Flicker is an electrical effect that can occur in power distribution networks such as commercial power distribution utility networks. Flicker occurs when relatively large electronic loads are connected and disconnected to a power distribution network (e.g., an alternating current (AC) power distribution network) within a range of frequencies that are perceptible to humans. Devices such as light bulbs are sensitive to drops in voltage and/or current and have noticeable changes in performance in response to flicker. Such changes, when occurring within a range of frequencies and intensities, can be annoying to people within view of the light bulb. Thus, some governmental agencies have issued or adopted regulations for equipment that is connected to public power distribution networks and draws power greater than a defined threshold.
Several examples are described throughout this specification. The figures are not necessarily to scale and certain features and certain views of the figures may be shown exaggerated in scale or in schematic for clarity and/or conciseness. Although the following discloses example methods, apparatus, and articles of manufacture, it should be noted that such methods, apparatus, and articles of manufacture are merely illustrative and should not be considered as limiting the scope of this disclosure.
Some types of printer ink, such as latex-based inks, have improved finish quality when dried by heating the ink after applying the ink to a print substrate (e.g., printer paper). The example ink drying apparatus and methods to control ink drying apparatus described herein may be used to heat and dry inks applied to a print substrate in a printer while complying with regulations on electrical equipment that are or may be implemented by government agencies in certain locations and/or countries. Some example regulations of note include a flicker requirement (e.g., International Electrotechnical Commission (IEC) 61000-3-3), a harmonics requirement (e.g., the IEC 61000-3-2 or IEC 61000-3-4), and/or an electromagnetic interference (EMI) requirement (e.g., IEC 61000-3-6 or IEC 61000-3-7). Some example heating apparatus described herein comply with each of the example flicker requirement, the harmonics requirement, and the EMI requirement. Some example heating apparatus described below include two or more heating elements positioned adjacent a heating area and a controller to control the heating elements according to a temperature of the heating area. In some examples, the controller selectively causes electrical power to be applied to a first one of the heating elements using a burst mode and to a second one of the heating elements using an on/off mode.
As noted, in some examples the controller controls the application of electrical power to one or more of the heating elements by causing power electronics to apply alternating current (AC current) to the heating element(s) in a burst mode. In burst mode, the controller applies the AC current to a heating element for a portion of a heating period (e.g., a duty cycle) that includes a substantially whole multiple of an AC current period (e.g., 1/50 Hertz (Hz) or 20 milliseconds (ms), 1/60 Hz or 16.67 ms). In some examples, the portion of the heating period ranges from 0% to 100% in whole and/or half AC-period increments. In some examples, the controller couples and/or decouples the heating element(s) to an AC current source when the AC current is substantially at a neutral (e.g., ground, zero) voltage, thereby reducing harmonics in the AC current source. The heating period may be set and/or adjusted based on a desired ink drying temperature, the upper power output of the heating element (e.g., a duty cycle of 100%), and a number and/or power output of other heating elements that are powered.
As noted, in some examples the controller controls the application of electrical power to one or more of the heating elements by applying AC current to the heating element(s) in an on/off mode. In contrast to heating elements controlled in burst mode, heating element(s) that are controlled in on/off mode remain in an on state or an off state for either substantially zero or substantially 100% of a heating period that is longer than the AC current period. In some examples, a heating element is maintained in either an on mode or an off mode when the desired ink drying temperature is substantially constant.
Turning to the figures,
The print substrates 108 and 110 are directed from the print substrate source(s) to the printhead(s) 104, which apply one or more layer(s) of ink to the print substrate 108. After having ink applied, the print substrate 110 moves to an ink drying area 112 adjacent the ink drying apparatus 102. The example ink drying apparatus 102 applies heat to the ink on the print substrate 110 (for example, at a substantially constant temperature) to dry the ink. After the ink dries, the print substrate 110 is directed out of the ink drying area 112 and the print substrate 108 may be directed into the ink drying area 112.
The heating elements 202 and 204 are positioned adjacent the ink drying area 112 of
When the controller 206 applies AC power to the example heating elements 202 and 204, the powered heating elements 202 and 204 generate heat in the form of infrared radiation. The example heating elements 202 and 204 of
The example ink drying apparatus 102 illustrated in
An alternative implementation of the example ink drying apparatus 102 of
Additional heating elements may be added to the example protective cases 306, 402, or 404 in
The example ink drying apparatus 102 of
The example power electronics 210 includes an AC input 502, a radio frequency interference (RFI) and/or electromagnetic interference (EMI) filter 504, a fuse 506, a relay switch 508, a current sensor 510, a triac 512, a control switch 514, and a thermal switch 516. The AC input 502 is connected to the AC power source 208. The RFI/EMI filter 504 filters the AC current received at the AC input to remove interference from the AC current and/or to prevent the power electronics and/or other circuitry within the ink drying apparatus 102 from transmitting interference back to the AC source 208.
The fuse 506 protects the ink drying apparatus 102 from potential damage as a result of current in excess of a current limit. The relay switch 508 may be used as a safety device, similar to the fuse 506, to disconnect the AC input 502 from the remainder of the ink drying apparatus 102.
An output of the relay switch 508 is input to the current sensor 510 and with the triac 512. The output of the example current sensor 510 is used as an input to the controller 206 to determine whether a burst mode and/or an on/off mode should be used for the heating element 202 to reach a desired temperature. For example, if the current sensed by the current sensor 510 is relatively low, the controller 206 may apply a higher burst mode duty cycle to the heating element 202 than if the current is higher.
The controller 206 controls the power electronics 210 by selectively closing the control switch 514 to operate the heating element 202 in a burst mode and/or an on/off mode. The triac 512 controls the conduction of current through the heating element 202. However, the example triac 512 is controlled via the thermal switch 516, which turns off conduction through the triac 512 and, thus, through the heating element 202 (regardless of the position of the control switch 514) if, for example, the temperature in the ink drying area 112 increases above a threshold as measured by the temperature sensor 214. In some examples, the thermal switch 516 may be integrated into the temperature sensor 214 of
Returning to
Table 1 illustrates an example list of burst modes and on/off modes that may be used by the controller 206 and the heating elements 202 and 204 to produce a desired temperature within the ink drying area 112. The percentages in Table 1 are with respect to the power dissipation or output of one of the heating elements 202 or 204. In the illustrated example, the heating elements 202 and 204 have equal maximum power dissipation. However, the heating elements 202 and 204 may have different maximum power dissipations to obtain different temperature ranges.
The example burst control levels illustrated in Table 1 may be achieved by applying AC power to the heating element 202 for the specified percentage of a predefined heating period (e.g., between 10 and −25 seconds). The burst control levels are determined by the AC frequency of the AC source 208 (e.g., about 60 Hertz (Hz) in United States systems, about 50 Hz in European Union systems, etc.) and the length of the heating period. In particular, the burst control levels are selected to provide bursts comprising full and/or half AC cycles where power may be connected and disconnected from the heating element 202 approximately when the AC current is at a zero crossing (e.g., the AC voltage is at neutral, the AC current is zero). By applying and disconnecting the burst at the AC current zero crossings, the example ink drying apparatus 102 reduces or substantially avoids causing frequency harmonics (which are also regulated in some countries) at the AC source 208.
The example burst control levels of Table 1 are illustrated in
The example controller 206 alters the burst mode level of the heating element 202 when the controller 206 determines, via the temperature sensor 214, that a single burst mode level does not provide the desired temperature in the ink drying area 112. For example, the controller 206 may apply a 25% burst level to the heating element 202 for two cycles and then apply a 50% burst level to the heating element 202 for one cycle to achieve a net power level of 33% of the upper power dissipation of the heating element 202.
The controller 206 controls the second heating element 204 in an on/off mode. In contrast to the burst mode used to control the first heating element 202, the on/off mode either applies AC power to the heating element 204 for the entire heating period or cycle 604 (i.e., the on mode) or removes AC power from the heating element 204 for the entire heating period or cycle 604 (i.e., the off mode). While the controller 206 may switch the heating element 204 between the on mode and the off mode (e.g., to change the temperature of the ink drying area 112), in some examples the heating element 204 remains in either the on mode or the off mode when the temperature of the ink drying area 112 is to remain substantially constant.
Table 2 illustrates example power levels that may be applied to the heating elements 202, 204, and 702 of
An example flicker requirement is the IEC 61000-3-3:2008 standard, edition 2.0, which is based on what can cause irritation to people experiencing fluctuations in power supply due to the flicker (e.g., due to variations in light output from a light bulb). For example, at 0.1 changes per minute (e.g., 0.00167 Hz, 1 change per 10 minutes), the IEC 61000-3-3:2008 standard allows a relatively high change in voltage because people are less likely to notice minor power supply changes at that frequency. However, as the frequency increases to 1000 changes per minute (e.g., 16.67 Hz), people are generally more sensitive to power supply changes and therefore the IEC 61000-3-3:2008 standard permits a smaller change in voltage. As the frequency increases above 1000 changes per minute, a person's perception diminishes and the IEC 61000-3-3:2008 standard thus allows more of a voltage change. A copy of the IEC 61000-3-3:2008 standard is available from the International Electrotechnical Commission.
Assuming an equal power output between two heating elements and three heating elements, including three heating elements allows a greater distribution of power between the heating elements and, thus, causes less of a voltage change at the AC current distribution system when switched on and/or off. However, additional cost is generally required for each additional heating element that is included in the ink drying apparatus 102.
The example heating apparatus described herein also have improved EMI performance. In particular, the example ink drying apparatus 102 of
While the example methods and apparatus described herein refer to heating elements in a printer, the example methods and apparatus may be modified and/or adapted for other ink drying application(s). For example, other ink drying devices having high power consumption may be controlled using a combination of burst mode(s) and on/off mode(s) to comply with, for example, a flicker requirement, a requirement to avoid inducing harmonics in a power supply, and/or an EMI requirement.
Although certain methods, apparatus, and articles of manufacture have been described herein, the scope of coverage of this patent is not limited thereto. To the contrary, this patent covers all methods, apparatus, and articles of manufacture falling within the scope of the appended claims.