The present invention relates to a recording apparatus and a recording method.
There is provided a recording apparatus which records an image by using a recording head including a substrate on which a plurality of recording elements for generating heat energy for discharging ink is arranged. In the above-described recording apparatus, if the temperature the vicinity of a recording element is lowered, the amount of discharged ink may be reduced considerably, which may then lower the ink density of the recorded image.
In order to suppress the considerable reduction in the discharged amount caused due to the lowering of temperatures, Japanese Patent Application Laid-Open No. 3-005151 discusses a recording head including a substrate an which heating elements different from the recording elements are further arranged. According to Japanese Patent Application Laid-Open No. 3-005151, when the temperature is lowered, the above-described lowering of density can be suppressed by heating in the vicinity of the recording element by driving the heating element.
However, if a set of heating elements described in Japanese Patent Application Laid-Open No. 3-005151 is used, there is a risk that the above-described temperature control cannot be performed in a favorable manner because of the temperature distribution of the ink on the substrate.
For example, it is assumed that a temperature is comparatively low at a position A on the substrate and has not reached a target temperature of heating performed by the heating element, whereas a temperature is comparatively high at a position B and has reached the target temperature thereof. Although an amount of discharge caused by a recording element positioned at the position A is considerably low, an amount of discharge caused by a recording element positioned at another position is ideal. At this time, if heating is not performed by the heating elements, image quality will be lowered because the amount of discharge caused by the recording element positioned at the position A is extremely low. On the other hand, if heating is performed by the heating elements, the temperature is further increased at the position B, and the amount of discharge caused by the recording element positioned at the position B is increased excessively, so that density of the image will be high.
The above-described problem can be solved if a plurality of heating elements is arranged at different positions on the substrate, and heating is individually executed by the heating elements at respective positions. For example, in the above-described example, heating elements for heating the positions A and B are arranged separately, and the heating element corresponding to the position B does not perform heating, while the heating element corresponding to the position A performs heating. With this configuration, deviation from an ideal discharge amount can be suppressed at both of the positions, so that an image with small density variations (i.e., an image with substantially ideal density) can be recorded.
However, as a result of examinations conducted by inventors, it has been found that the following problem occurs if heating is individually performed by a plurality of heating elements. If a large number of heating elements are switched from a non-driving state to a driving state at the same timing, inrush current occurring when the non-driving state is switched to the driving state is superimposed, so that there is a risk in which a load with respect to an electric circuit is increased, or induction noise is generated to cause an error in data transmission between the recording head and the recording apparatus.
The present invention is directed to a method suppressing a negative effect caused by superimposition of inrush current in a case where a recording head having a plurality of heating elements arranged on a same substrate is to be used.
According to an aspect of the present invention, a recording apparatus includes a recording head having a plurality of recording elements configured to generate energy for discharging ink, a first heating element configured to heating ink in the vicinity of one of said recording elements positioned at a first position, insufficiently to discharge ink, and a second heating element configured to heat ink in the vicinity of a recording element positioned at a second position different from the first position, insufficiently to discharge ink, wherein the first and second positions are arranged on a same substrate, a heating control unit configured to control the heating operation of the ink by driving the first and the second heating elements by applying voltage to the first and the second heating elements, and a recording control unit configured to control the recording operation by driving the plurality of recording elements, wherein the heating control-unit is configured to control the heating operation to drive the first heating element and the second heating element at timings different from each other.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
The recording unit 101 for discharging ink is arranged on the recording apparatus. The recording unit 101 includes seven recording heads 102a to 102g for discharging ink of different colors, which are arranged in an X-direction (i.e., rotation direction or scanning direction). Specifically, the recording head 102a discharges cyan ink (C), the recording head 102b discharges magenta ink (M), the recording head 102c discharges yellow ink (Y), the recording head 102d discharges black ink (K), the recording head 102e discharges light-cyan ink (Lc), the recording head 102f discharges light-magenta ink (Lm), and the recording head 102g discharges gray ink (Gy). Although details will be described below, a plurality of recording element arrays including a plurality of recording elements that generates heat energy for discharging ink of each color arrayed in the Y-direction (i.e., array direction) is arranged on each of the recording heads 102a to 102g.
The transfer body 103 (first recording medium) is arranged on a discharge face side (lower side) of the recording unit 101 included in the recording apparatus. Ink of respective colors are discharged to the transfer body 103 from the recording heads 102a to 102g while the transfer body 103 is being rotated in the X-direction (rotation direction) through a rotation mechanism (not illustrated), so that an image is recorded on the transfer body 103.
A conveyance roller 106 is arranged to be in contact with the transfer body 103 and rotated in a direction (−X direction) opposite to the rotation direction of the transfer body 103 by a conveyance mechanism (not illustrated). At a contact portion between the transfer body 103 and the conveyance roller 106, an image formed on a surface of the transfer body 103 is transferred to a recording sheet (second recording medium) 105 conveyed by the conveyance mechanism (not illustrated), so that the image is recorded on the recording sheet 105.
A linear encoder 108 on which a slit is provided at predetermined intervals is attached to a shaft of the transfer body 103. Further, a linear encoder sensor (not illustrated) is arranged at a position at which the linear encoder 108 is detectable. The linear encoder 108 rotates along with rotation of the transfer body 103, and the linear encoder sensor detects respective slits provided on the linear encoder 108, so that a discharge timing of ink discharged from each of the recording heads 102a to 102g is adjusted based on the detection timing. Herein, although a configuration in which the linear encoder 108 is attached to the shaft of the transfer body 103 is described, the linear encoder 108 may be attached to a position away from the shaft of the transfer body 103. Further, a rotary encoder may be arranged on the shaft of the transfer body 103.
<Recording Head>
As illustrated in
Then, four discharge port arrays for discharging ink are arranged on each of the heater boards 111, 112, and 113. These four discharge port arrays are arranged in the X-direction (intersecting direction). For example, as illustrated in
Then, a recording element as an electrothermal conversion element is arranged at a position (an inner position in the vicinity of a discharge port) corresponding to each of the discharge ports. Accordingly, an array of recording elements (recording element array) is formed at a position corresponding to each of the discharge port arrays. When ink is to be discharged, a driving pulse (voltage) is applied to the recording elements via an electric wiring connected thereto. The recording elements are driven by the driving pulse to generate heat energy, so that discharge operation is executed through respective discharge ports by using the generated thermal energy.
Temperature sensors (detection elements) 123a to 123j and heating elements (sub-heaters) 124a to 124j are arranged on the heater board 111 in addition to the discharge port arrays 121a to 121d and the recording elements. Each of the temperature sensors 123a to 123j is a member for detecting a temperature in a vicinity area, and each of the sub-heaters 124a to 124j is a member for heating a vicinity area and retaining the temperature.
Herein, the heater board 111 is divided into ten heating areas 125a to 125j according to positions on the heater board 111. The heating areas 125a to 125e respectively include discharge port portions 122a to 122e consisting of portions of the discharge port arrays 121a and 121b divided in the Y-direction. Further, the heating areas 125f to 125j respectively include discharge port portions 122f to 122j consisting of portions of the discharge port arrays 121c and 121b divided in the Y-direction.
Then, the temperature sensor and the sub-heater are arranged in each heating area of the heater board of the present exemplary embodiment. For example, the temperature sensor 123a for detecting a temperature of ink in a vicinity of the discharge port portion 122a and the sub-heater 124a for heating ink in a vicinity of the discharge port portion 122a are arranged in the heating area 125a on the heater board 111. In
As illustrated in
<Recording Control System>
As illustrated in
Then, a recording data generation unit 305, a central processing unit (CPU) 306, a discharge timing generation unit 307, a temperature value storage memory 308, a sub-heater driving table storage memory (table storage memory) 313, and data transfer units 310 to 312 are arranged on the controller 304.
The CPU 306 reads and executes a program stored in the ROM 303 to control operation of the entire recording apparatus such as driving operation of a driver such as a motor. Further, fixed data necessary for various kinds of operation of the recording apparatus is stored in the ROM 303 in addition to various control programs executed by the CPU 306. For example, a program for executing recording control of the recording apparatus is stored.
The DRAM 302 is necessary for the CPU 306 to execute a program. The DRAM 302 is used as a work area of the CPU 306 or a temporary storage area of various received data, and various setting data may be stored. Further, although only one DRAM 302 is illustrated in
The recording data generation unit 305 receives image data from a host (personal computer (PC)) outside the recording apparatus. Then, the recording data generation unit 305 executes color conversion processing or quantization processing on the image data, generates recording data used for discharging ink from the recording head 102a, and stores the generated recording data in the DRAM 302.
The discharge timing generation unit 307 receives position information indicating relative positions of the recording head 102a and the recording medium 103 detected by the encoder sensor 301. Then, based on the position information, the discharge timing generation unit 307 generates discharge timing information indicating a timing of discharging ink from the recording head 102a.
Three data transfer units 310, 311, and 312 read recording data stored in the DRAM 302 according to the discharge timing generated by the discharge timing generation unit 307. Further, sub-heater driving information generated as described below is also read from a heating control unit 309. Then, each of the data transfer units 310, 311, and 312 transfers the recording data and the sub-heater driving information to each of the heater board 111, 112, and 113 via a wiring substrate.
Each of the heater boards 111, 112, and 113 uses the transferred recording data to drive the recording elements to discharge ink, and outputs the output values of temperature sensors within the heater board to the AD conversion device 314. Further, in order to reduce the number of signals simultaneously input to the AD conversion device 314, output values of temperature sensors are sequentially input to the AD conversion device 314 one by one from all of the temperature sensors arranged on the heater boards 111, 112, and 113. The AD conversion device 314 converts the output values of the temperature sensors into digital values (temperature values), and outputs those temperature values to the heating control unit 309.
At this time, in the present exemplary embodiment, it will take 50 μs to detect a temperature from one temperature senor. As described above, the three heater boards 111, 112, and 113 are arranged on the recording head 102a, and ten temperature sensors are arranged on each of the heater boards 111, 112, and 113. Therefore, it will take 1500 μs (50×3×10) for the heating control unit 309 to update temperature values of all of the temperature sensors. In consideration of the above situation, in the present exemplary embodiment, the temperature value of one temperature sensor is updated every 1500 μs.
The heating control unit 309 stores the temperature values received from the AD conversion device 314 in the temperature value storage memory 308. Then, the heating control unit 309 reads out the latest temperature value stored in the temperature value storage memory 308 according to an input of the discharge timing information, and generates the sub-heater generation information at each heater board based on the heating control table of the heater board previously stored in the sub-heater driving table storage memory 313. As described above, the generated sub-heater driving information is output to the data transfer units 310, 311, and 312.
<Sub-Heater Heating Control>
When recording is started, sub-heater heating operation is also started. In step S1, the heating control unit 309 determines whether a predetermined period has passed after previous sub-heater heating operation is executed. The processing in step S1 may be omitted if recording operation and sub-heater heating operation have just been started. Herein, although a different time period can be appropriately set as the predetermined period, a period the same as the update interval of the temperature value, i.e., 1500 μs, is set thereto.
In step S2, the heating control unit 309 reads out the latest stored temperature value from the temperature value storage memory 308. Because reading is executed at each of the temperature sensors, temperature values of ten pieces each of temperature sensors respectively arranged on three heater boards, i.e., temperature values of thirty temperature sensors in total, will be acquired.
In step S3, based on the sub-heater driving table stored in the sub-heater driving table storage memory 313 and the temperature values acquired in step S2, a sub-heater driving pattern for driving the sub-heater is determined as the sub-heater driving information. The sub-heater driving table of the present exemplary embodiment directly specifies a correspondence between a temperature and a sub-heater driving pattern indicating a driving timing of the sub-heater. In step S3, the heating control unit 309 refers to the sub-heater driving table and determines the sub-heater driving pattern corresponding to the temperature detected by each of the temperature sensors. A determination method of the sub-heater driving pattern will be described below.
In step S4, the heating control unit 309 drives the sub-heater according to the determined sub-heater driving pattern and retains a temperature of ink in the vicinity of a recording element group belonging to the corresponding heating area.
Thereafter, the processing proceeds to step S5. In step S5, the heating control unit 309 determines whether the sub-heater heating operation has been ended. In the present exemplary embodiment, sub-heater heating operation is ended when recording is ended. If it is determined that sub-heater heating operation has not been ended (i.e., recording has not been ended) (NO in step S5), the processing returns to step S1, and the heating control unit 309 drives the sub-heater according to the sub-heater driving pattern determined in previous step S3 until the predetermined period has passed. Then, when the predetermined period has passed, the processing proceeds to step S2 again, so that the temperature value is updated and similar control processing is continued. If the heating control unit 309 determines that sub-heater heating operation has been ended (YES in step S5), the processing flow illustrated in
Of the two rows one above the other in
For example, if reading of the sub-heater driving pattern is started from the left end, the driving signals are output in the order of 1, 1, 1, 1, 1, 0, 0, 0, 0, and 0 if the temperature is less than 50° C. Accordingly, the sub-heater is driven for the first 50 μs (corresponding to the first five driving signals represented by “1”) and is not driven for the subsequent 50 μs (corresponding to the first five driving signals represented by “0”). Thereafter, the reading position returns to the left end of the sub-heater driving pattern, so that the sub-heater is driven for the next 50 μs, and is not driven for the following 50 μs. As described above, because the sub-heater is driven to a certain extent if the temperature is less than 50° C., the temperature of vicinity ink can be prevented from being lowered.
Further, if the temperature is 50° C. or more, “0” which represents the driving signal indicating non-driving of the sub-heater is specified at every position. This is because the temperature is higher than the target temperature, and thus driving of the sub-heater is not executed in order to prevent excessive rise in the temperature.
Herein, if the left end of the sub-heater driving pattern in
For example, if a temperature lower than 50° C. is detected at all of the ten temperature sensors 123a to 123j, the driving signals are output in the order of 1, 1, 1, 1, 1, 0, 0, 0, 0, and 0 with respect to all of the sub-heaters 124a to 124j. Therefore, all of the sub-heaters 124a to 124j in a non-driving state are switched to a driving state at the same timing immediately after the sub-heater heating control is started. If electric current is to be applied to a circuit to which the electric current has not been applied, electric current (inrush current) higher than the electric current applied in its steady state may flow into the circuit. If a reading start position of the sub-heater driving table is the same at each of the sub-heaters 124a to 124j, the above-described high current is superimposed at all of the sub-heaters 124a to 124j at the same timing, so that the above-described increase in the load of the electric circuit or the data transmission error will occur.
In consideration of the above problem, in the present exemplary embodiment, although the same sub-heater driving pattern illustrated in
If the temperature detected at all of the temperature sensors 123a to 123j is lower than 50° C., the sub-heater driving table is read from the left end with respect to the sub-heater 124a, so that driving signals are output in the order of 1, 1, 1, 1, 1, 0, 0, 0, 0, and 0. On the other hand, because the sub-heater driving table is read from the right end with respect to the sub-heater 124b, the driving signals are output in the order of 0, 1, 1, 1, 1, 1, 0, 0, 0, and 0. Further, for example, with respect to the sub-heater 124f, because the sub-heater driving table is read from the fifth position from the right end, the driving signals are output in the order of 0, 0, 0, 0, 0, 1, 1, 1, 1, and 1.
If the reading start positions of the sub-heater driving table are set differently as described in the present exemplary embodiment, the output orders of the driving signals (i.e., driving/non-driving orders of the sub-heater) are offset with each other. Accordingly, a timing at which the sub-heater is switched from a non-driving state to a driving state, i.e., a timing at which inrush current occurs, can be set differently at each of the sub-heaters. With this configuration, a load of the electric circuit can be reduced, or a data transmission error can be reduced by suppressing occurrence of induction noise.
An actual driving timing of the sub-heater will be described below.
As described above, with respect to the sub-heater 124a, because reading is started from the left end, the driving signals are input in the order of 1, 1, 1, 1, 1, 0, 0, 0, 0, and 0. Accordingly, the sub-heater 124a is driven at the first to the fifth input timings of the driving signals. Then, the sub-heater 124a is not driven at the sixth to the tenth input timings of the driving signals. Then, the sub-heater 124a is driven again at the eleventh input timing of the driving signal. Accordingly, the sub-heater 124a is switched from a non-driving state to a driving state at the input timings of the first and the eleventh driving signals, which are the timings at which inrush current occurs.
With respect to the sub-heater 124b, because reading is started from the right end, the driving signals are input in the order of 0, 1, 1, 1, 1, 1, 0, 0, 0, and 0. Accordingly, the sub-heater 124b is not driven at the input timing of the first driving signal, and driven at the input timings of the second to the sixth driving signals. Then, the sub-heater 124b is switched to the non-driving state at the input timing of the seventh driving signal, and switched to the driving state at the input timing of the twelfth driving signal. As described above, with respect to the sub-heater 124b, there is a risk in which inrush current occurs at the input timings of the second and the twelfth driving signals.
Further, with respect to the sub-heater 124f, because reading is started from the fifth position from the right end, the driving signals are input in the order of 0, 0, 0, 0, 0, 1, 1, 1, 1, and 1. Accordingly, the sub-heater 124f is not driven at the input timings of the first to the fifth driving signals and switched to the driving state at the input timing of the sixth driving signal, and further switched to the non-driving state at the input timing of the eleventh driving signal. Accordingly, with respect to the sub-heater 124f, there is a risk in which inrush current occurs at the input timing of the sixth driving signal.
As illustrated in
In the above-described first exemplary embodiment, if a temperature detected by the temperature sensor is lower than the target temperature, sub-heater heating control is constantly executed at the same intensity.
On the other hand, in a second exemplary embodiment, sub-heater heating control is executed at different intensity according to a difference between a temperature detected by the temperature sensor and the target temperature.
Further, description of the configuration similar to that of the first exemplary embodiment will be omitted.
In the first exemplary embodiment, the sub-heater is driven if the temperature detected by the temperature sensor is lower than the target temperature, and the sub-heater is not driven if the detected temperature is higher the target temperature. However, in practice, even in a state where the detected temperature is lower than the target temperature, favorable driving intensity of the sub-heater, i.e., the favorable heating amount, is different depending on a difference between the detected temperature and the target temperature. For example, when the target temperature is 50° C., heating does not have to be executed so intensively if the detected temperature is 45° C. However, if the detected temperature is 20° C., it is preferable that the target temperature be achieved as quickly as possible by executing heating at a certain degree of intensity.
In consideration of the above situation, in the present exemplary embodiment, when the detected temperature is lower than the target temperature, sub-heater heating operation is executed at different sub-heater driving intensity based an the difference between the detected temperature and the target temperature. Therefore, the sub-heater driving table storage memory 313 of the present exemplary embodiment stores the sub-heater driving tables of two types, i.e., a first sub-heater driving table in which a correspondence between a temperature difference and a sub-heater driving intensity is specified, and a second sub-heater driving table in which a correspondence between the sub-heater driving intensity and the sub-heater driving pattern is specified. The sub-heater heating control using two types of sub-heater driving tables will be described below in detail.
The processing in steps S11 and S12 in
In step S13, a difference (temperature difference) between a predetermined target temperature and a temperature (detected temperature) detected at each of the temperature sensors 123a to 123j acquired in step S12 is calculated. This difference is calculated by subtracting the detected temperature from the target temperature. Accordingly, the detected temperature is higher than the target temperature if a negative value is acquired as a difference, and the detected temperature is lower than the target temperature if a positive value is acquired as a difference.
Next, in step S14, sub-heater driving intensity is determined based on the first sub-heater driving table stored in the sub-heater driving table storage memory 313 and the temperature difference at each temperature sensor calculated in step S13. As described above, the correspondence between the temperature difference and the sub-heater driving intensity is specified in the first sub-heater driving table. The sub-heater driving intensity corresponding to the temperature difference calculated in step S13 is determined with reference to the first sub-heater driving table.
As illustrated in
In step S15, the sub-heater driving pattern is determined based on the second sub-heater driving table stored in the sub-heater driving table storage memory 313 and the sub-heater driving intensity determined in step S14. As described above, a correspondence between the sub-heater driving intensity and the sub-heater driving pattern is specified in the second sub-heater driving table. The sub-heater driving pattern corresponding to the sub-heater driving intensity determined in step S14 is determined with reference to the second sub-heater driving table.
As illustrated in
For example, when the sub-heater driving intensity is 90%, respective driving signals of 1, 1, 1, 1, 1, 1, 1, 1, 1, and 0 are specified from the left end of the second sub-heater driving table. Accordingly, nine driving signals indicate driving of the sub-heater.
Further, when the sub-heater driving intensity is 50%, respective driving signals of 1, 1, 1, 1, 1, 0, 0, 0, 0, and 0 are specified from the left end of the second sub-heater driving table. Accordingly, five driving signals indicate driving of the sub-heater.
Further, when the sub-heater driving intensity is 0%, respective driving signals of 0, 0, 0, 0, 0, 0, 0, 0, 0, and 0 are specified from the left end of the second sub-heater driving table. Accordingly, none of the driving signals indicates driving of the sub-heater.
As described above, by using the second sub-heater driving table, the number of driving, times of the sub-heater can be increased if the sub-heater driving intensity is higher.
Similar to the first exemplary embodiment, in the present exemplary embodiment, a reading start position of the sub-heater driving table is set differently with respect to the ten sub-heaters 124a to 124j arranged on the heater board 111. Details of the reading start positions for the sub-heaters 124a to 124j are illustrated in
For example, with respect to the sub-heater 124a, reading is executed from the left end of the sub-heater driving table. Therefore, the driving signals are output in the order of 1, 1, 1, 1, 1, 1, 1, 1, 1, and 0 if the sub-heater driving intensity is 90%. Further, if the sub-heater driving intensity is 50%, the driving signals are output in the order of 1, 1, 1, 1, 1, 0, 0, 0, 0, and 0.
On the other hand, with respect to the sub-heater 124b, reading is executed from the right end of the sub-heater driving table. Therefore, the driving signals are output in the order of 0, 1, 1, 1, 1, 1, 1, 1, 1, and 1 if the sub-heater driving intensity is 90%. Further, if the sub-heater driving intensity is 50%, the driving signals are output in the order of 0, 1, 1, 1, 1, 1, 0, 0, 0, and 0.
As described above, in the present exemplary embodiment, when the output orders at the same sub-heater driving intensity are compared to each other, the output orders of the driving signals (i.e., driving/non-driving orders of sub-heaters) are also offset with each other. Accordingly, a timing at which the sub-heater is switched from a non-driving state to a driving state, i.e., a timing at which inrush current occurs, can be set differently at each of the sub-heaters. As described above, in the present exemplary embodiment, a load of the electric circuit can be reduced, or a data transmission error can be reduced by suppressing occurrence of induction noise.
An actual driving timing of the sub-heater will be described below.
First, a driving timing will be described with respect to the case where each of the temperature sensors 123a to 123j detects the temperature of 37° C. In this case, in step S13, the temperature difference is calculated as 13° C. at each of the temperature sensors 123a to 123j. In step S14, with reference to the first sub-heater driving table, the sub-heater driving intensity is determined as 50% because the temperature difference falls within a range of 10° C. or more and less than 15° C. at each of the temperature sensors 123a to 123j. Accordingly, in step S15, with reference to the second sub-heater driving table, the sub-heater driving pattern corresponding to the sub-heater driving intensity of 50% is read out. For example, with respect to the sub-heater 124a, because reading is started from the left end of the second sub-heater driving table, the driving signals are output in the order of 1, 1, 1, 1, 1, 0, 0, 0, 0, and 0. Further, with respect to the sub-heater 124b, because reading is started from the right end of the second sub-heater driving table, the driving signals are output in the order of 0, 1, 1, 1, 1, 1, 0, 0, 0, and 0. Similarly, with respect to the sub-heaters 124c to 124j, the driving signals are output in respective orders with reference to the second sub-heater driving table. Accordingly, actual driving timings of the respective sub-heaters are similar to those illustrated in
As described above, according to the present exemplary embodiment, an effect of reducing a load of the electric circuit or an effect of suppressing induction noise can be acquired while heating is expedited by increasing the driving intensity when the temperature difference between the detected temperature and the target temperature is greater.
In the above-described exemplary embodiment, sub-heater driving tables of two types, the first sub-heater driving table in which a correspondence between the temperature difference and the sub-heater driving intensity is specified and the second sub-heater driving table in which a correspondence between the sub-heater driving intensity and the sub-heater driving pattern is specified are used. In other words, a correspondence between the temperature difference and the sub-heater driving pattern is not specified directly but specified indirectly by the first and the second sub-heater driving tables. However, the present invention is not limited to the above. For example, an effect similar to the effect of the present exemplary embodiment can be acquired by using only one type of sub-heater driving pattern in which a correspondence between the temperature difference and the sub-heater driving pattern is directly specified as illustrated in
In the first and the second exemplary embodiments, a reading start position of the sub-heater driving table (i.e., second sub-heater driving table) is set differently at each of the sub-heaters arranged an one heater board.
On the contrary, in a third exemplary embodiment, the same reading start position of the sub-heater driving table is specified with respect to a part of the sub-heaters.
Description of a configuration similar to that the first or the second exemplary embodiment will be omitted.
In the present exemplary embodiment, sub-heater heating control is executed according to the flowchart illustrated in
Of the rows one above the other in
As illustrated in
Specifically, if the temperature is lower 50° C., the driving signals are output in the order of 1, 1, 1, 1, and 0 with respect to the sub-heaters 124a and 124f. Further, the driving signals are output in the order of 0, 1, 1, 1, and 1 with respect to the sub-heaters 124b and 124g.
An actual driving timing of the sub-heater will be described below.
As illustrated in
However, with respect to the sub-heaters belonging to different pairs, different reading start positions of the sub-heater driving pattern are specified thereto. Thus, it is possible to make the timings at which the sub-heaters are switched from a non-driving state to a driving state be different from each other. Therefore, in comparison to the case where all of the sub-heaters are switched from a non-driving state to a driving state at the same timing, it is possible to further acquire the effect of reducing the load of the electric circuit or the effect of suppressing induction noise.
In addition, in the above-described exemplary embodiments, although temperature information detected by the temperature sensor is updated every 1500 μs, this period may be changed as appropriate. Further, in the above-described exemplary embodiments, although only a temperature detected at a certain timing is used for the heating control, a temperature detected prior to that timing may be also used. For example, if one temperature is detected from a temperature sensor at one timing, a moving average between the one temperature and a temperature detected at a timing just before the one timing (e.g., 1500 μs before) may be calculated to be used for the heating control. If the above-described average temperature is used, there is a risk that the temperature may be deviated from the precise temperature detected at each timing. However, in a case where deviations occur in measurement of the detected temperature due to an influence of noise, deviations caused by the influence of noise can be reduced to some extent.
Further, in the above-described exemplary embodiments, the same sub-heater driving table is used for the respective sub-heaters, and superimposition of inrush current is suppressed by changing the reading start position of the sub-heater driving table. However, the present invention is not limited thereto. For example, different sub-heater driving tables may be used for the respective sub-heaters. In this case, the effect similar to the effect acquired from the other exemplary embodiments can be acquired if the respective sub-heater driving tables are specified to make the timings at which the sub-heaters are switched from a non-driving state to a driving state be different from each other.
Further, in the above-described exemplary embodiments, although a reading start position of the sub-heater driving pattern is always set differently at each of the sub-heaters, the present invention is not limited thereto. For example, it may be determined whether timings at which inrush current is increased (i.e., timings at which the sub-heaters are switched from a non-driving state to a driving state) are superimposed with each other, and the reading start position may be switched to the reading start position described in the above-described exemplary embodiment only when it is determined that the timings are superimposed with each other.
Further, in the above-described exemplary embodiments, signals indicating driving of the sub-heater and signals indicating non-driving thereof are output respectively in a consecutive manner. For example, in the upper row in
Further, in the above-described exemplary embodiments, after ink is applied to the transfer body (first recording medium) from the recording head, recording is performed on a recording sheet (second recording medium) by transferring an image formed on the transfer body to the recording sheet. However, the present invention is not limited thereto. For example, ink may be directly applied to a recording sheet from the recording head.
Further, in the above-described exemplary embodiments, although a recording head having a length longer than a width of a recording medium is used, the present invention is not limited thereto. For example, recording operation of making the recording head discharge ink while scanning in a direction intersecting with an array direction of discharge ports and conveyance operation of conveying a recording medium in the array direction between the scans may be executed repeatedly, so that recording with respect to the recording medium may be completed by a plurality of times of scanning (moving) operation.
According to the recording apparatus of the present invention, a negative effect caused by superimposition of inrush current can be suppressed in a case where a recording head having a plurality of heating elements arranged on a same substrate is to be used.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.
This application claims the benefit of Japanese Patent Application No. 2017-074679, filed Apr. 4, 2017, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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