1. Technical Field
The present invention relates to a printing apparatus or the like which can contain at least one printing material container attached thereto.
2. Related Art
Some known printing apparatuses, which contain at least one printing material container (ink container or the like) attached thereto, have a detection circuit configured to detect attributes and states of the at least one printing material container, such as a kind thereof and the presence or absence of the attachment thereof, and another circuit (a printing-material amount detection circuit) configured to detect whether the amount of a printing material contained in the at least one printing material container is more than or equal to a predetermined amount, or not. With respect to such a printing apparatus which is configured in such a manner as described above, known examples of a technology which enables prevention or suppression of occurrence of failures in the at least one printing material container and the printing apparatus due to any short circuit between the detection circuit and the printing-material amount detection circuit, include a technology described in Japanese Patent No. 4539654.
Further, known examples of a short-circuit protection circuit for a charging-type secondary battery pack having a remaining-amount indication function include a short-circuit protection circuit described in JP-A-5-299123.
This short-circuit protection circuit described in JP-A-5-299123 employs a method in which the presence or absence of an output electric current which arises upon occurrence of any short circuit is determined by measuring voltage-level changes of an electric-current detection resistor provided at the output portion of the secondary battery pack. But, it is to be noted that, in order to suppress loss of energy, the electric-current detection resistor needs to be of relatively low resistance. In this regard, however, the relatively low resistance of the electric-current detection resistor lowers a detected voltage level resulting from a current-to-voltage conversion, and thus, a determination circuit for determining whether any short circuit exists, or not, needs to be of higher accuracy.
In order to realize such a determination circuit of higher accuracy, a method of realizing the determination circuit by means of an analog circuit, which is configured to operate between a first power supply voltage (having a voltage level of, for example, 0V) and a second power supply voltage (having a voltage level of around several volts, that is, for example, approximately 3V to 5V), is employed. In such a circuit configuration, a short circuit is detected by measuring voltages of both terminals (two terminals) of the electric-current detection resistor. But, the voltage levels of the respective two terminals fluctuate, and thus, obviously, the fluctuations thereof cause a further variation in accuracy of the measurement.
Moreover, in the case where a high voltage (having a voltage level of, for example, approximately several ten volts) needs to be handled, a level conversion circuit is additionally needed, and thus, obviously, the addition of the level conversion circuit makes the circuit configuration further complicated.
Furthermore, since a protection circuit operates after the occurrence of a short circuit has been determined, a short-circuit electric current due to the short circuit is likely to flow even during a short period of time.
An advantage of some aspects of the invention is to provide a printing apparatus which is capable of further highly accurately detecting normal conditions of contacts between terminals thereof, and any unintended short circuit occurring between terminals thereof which is likely to cause failures in the printing apparatus including at least one printing material container.
(1) According to an aspect of the invention, a printing apparatus includes at least one printing material container which includes two first terminals, two second terminals, an electric device connected to the two first terminals, and a wiring connecting the two second terminals to each other, and which is attachable and detachable to the printing apparatus; a first detection terminal and a second detection terminal which contact with the two first terminals, respectively, under the state where the at least one printing material container is attached to the printing apparatus; a third detection terminal and a fourth detection terminal which contact with the two second terminals, respectively, under the state where the at least one printing material container is attached to the printing apparatus; a first detection unit which is connected to the second detection terminal, and which detects contacts between the first and second detection terminals and the respective two first terminals by detecting a first detection signal, which is output from the first detection terminal, via a first attachment detection path including the electric device and the two first terminals; and a second detection unit which is connected to the fourth detection terminal, and which detects contacts between the third and fourth detection terminals and the respective two second terminals by detecting a second detection signal, which is output from the third detection terminal, via a second attachment detection path including the wiring and the two second terminals. Further, the first detection unit detects a short circuit occurring between the second detection terminal and the third detection terminal on the basis of the second detection signal, and the second detection unit detects a short circuit occurring between the first detection terminal and the fourth detection terminal on the basis of the first detection signal.
In the aspect of the invention, two kinds of signals used for the attachment detection, i.e., the first and second detection signals, are also used for the short-circuit detection, and when any short circuit occurring between terminals exists, a short-circuit detection signal (i.e., one of the first and second detection signals) is detected in preference to a contact detection signal (i.e., the other one of the first and second detection signals) which is to be detected under the normal condition. Therefore, it is possible to surely detect the short-circuit detection signal under the condition where any short circuit exists without shutting off any one of the first and second detection signals by means of a method of making the output port of any one of generation units for generating the first and second detection signals be in a high-impedance state, or the like. In addition, the short circuit occurring between the second detection terminal and the third detection terminal includes any short circuit which results in an electric conduction between the third detection terminal, from which the second detection signal is output, and the second detection terminal, to which the first detection unit is connected, and also includes any short circuit occurring between terminals at the printing material container side (refer to
Further, in the aspect of the invention, since the two kinds of detection signals, i.e., the first and second detection signals, are detected by the first and second detection units, it is unnecessary to connect any electric-current detection resistor, and thus, driving capabilities of the first and second detection signals are not degraded.
Further, in the aspect of the invention, the presence or absence of any short circuit is detected with reference to a predetermined electric potential (for example, a grounding potential). In each of the first and second detection units, for example, the presence or absence of any short circuit is detected by fixing one of both terminals of a current-to-voltage conversion resistor to a grounding potential, and detecting the changes of electric potential of the other one of the both terminals thereof. In this case, the presence or absence of any short circuit can be detected by measuring the changes of electric potential of only one of the both terminals of the current-to-voltage conversion resistor with reference to a predetermined electric potential (a grounding potential in the foregoing example). Therefore, the accuracy of the short-circuit detection is upgraded to a greater degree, as compared with the method in which the voltage changes of the both terminals of the electric-current detection resistor are detected.
(2) In the aspect of the invention, in the case where a path, via which the second detection signal output from the third detection terminal transmits to the first detection unit, is defined as a first short-circuit path, and a path, via which the first detection signal output from the first detection terminal transmits to the second detection unit, is defined as a second short-circuit path, preferably, an impedance of the first attachment detection path is larger than an impedance of the first short-circuit path, and an impedance of the second attachment detection path is larger than an impedance of the second short-circuit path.
If the electric-current driving capabilities of generation sources of the first and second detection signals are substantially equal to each other, the detection of the foregoing short-circuit detection signal, which is one of the first and second detection signals prevailing against the other one thereof, is made possible dependent on the largeness of each of the impedances of the first attachment detection path and the first short-circuit path, the impedances being ones when seen from the first detection unit. That is, if the impedance of the first attachment detection path is larger than the impedance of the first short-circuit path, the second detection signal prevails against the first detection signal.
Similarly, whether one of the first and second detection signals prevails against the other one thereof, or not, depends on the largeness of each of the impedances of the second attachment detection path and the second short-circuit path, the impedances being ones when seen from the second detection unit. That is, if the impedance of the second attachment detection path is larger than the impedance of the second short-circuit path, the first detection signal prevails against the second detection signal.
(3) In the aspect of the invention, preferably, the printing apparatus further includes an electric-current limitation resistor for limiting an amount of electric-current of the second detection signal output from the third detection terminal.
In this way, the impedances of the first and second attachment detection paths, as well as the impedances of the first and second short-circuit paths, can be appropriately set by utilizing a relatively large resistance of the electric device under the state where a short circuit exists between the first and third detection terminals, and the electric-current limitation resistor under the state where a short circuit exists between the second and fourth detection terminals, so that the electric-current driving capabilities of the first and second detection signals can be made adjustable; whereby it is possible to perform the short-circuit detection by detecting one of the first and second detection signals, which prevails against the other one thereof, as the short-circuit detection signal.
(4) In the aspect of the invention, preferably, the printing apparatus further includes an overvoltage detection unit configured to, when a high voltage having a voltage level higher than that of a voltage of the second detection signal is applied to the first detection terminal, detect whether a voltage having a voltage level higher than or equal to a predetermined voltage level is applied to at least one of the third detection terminal and the fourth detection terminal, or not.
In the aspect of the invention, in the case where at least one of a short circuit via a short-circuit resistance RSN (
(5) In the aspect of the invention, preferably, the printing apparatus further includes at least one discharging element configured to discharge electric charges stored in a capacitive element in advance of outputs of the first detection signal and the second detection signal, wherein the capacitive element is used for the electric device of the at least one printing material container in the case where the electric device is a sensor for detecting whether a remaining amount of a printing material contained in the at least one printing material container is more than or equal to a predetermined amount.
If there exist electric charges stored in the capacitive element functioning as the sensor when detecting contacts and any short circuit between the sensor and the printing-apparatus side terminals, an electric current caused by the electric charges results in occurrence of measurement errors. That is, it is difficult to detect the presence or absence of any short circuit with reference to a predetermined electric potential (for example, a grounding potential). Therefore, in the aspect of the invention, it is possible to suppress degradation of accuracy in the short-circuit detection by providing the at least one discharging element, through which the electric charges stored in the capacitive element are caused to discharge in advance of the contact/short-circuit detections performed by the first and second detection unit, and further, causing the electric charges stored in the capacitive element to discharge through the at least one discharging element.
(6) In the aspect of the invention, the first detection terminal and the third detection terminal may be located adjacent to each other, and the second detection terminal and the fourth detection terminal may be located adjacent to each other.
In the case where the first detection terminal and the third detection terminal are located adjacent to each other, the both terminals are highly likely to short-circuit via, for example, electrically conductive ink, or the like. Further, in the case where the second detection terminal and the fourth detection terminal are located adjacent to each other, the both terminals are highly likely to short-circuit via, for example, electrically conductive ink, or the like. Therefore, it is important to implement the protection operation by means of the short-circuit detection.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
Hereinafter, a preferred embodiment according to the invention will be described in detail. In addition, the embodiment described below does not unreasonably limit the content of the invention set forth in the appended claims, and all components described in this embodiment are not essential to solutions provided by the invention.
In an example shown in
The cartridge 100 has an anterior edge surface (a first surface) Sf, a posterior edge surface (a second surface) Sr, a ceiling surface (a third surface) St, a bottom surface (a fourth surface) Sb, and two side surfaces (fifth and sixth surfaces) Sc and Sd. An ink containing chamber 120 (which is also referred to as “an ink containing bag”) formed of a flexible material is provided inside the cartridge 100. The anterior edge surface Sf has two locating holes 131 and 132, and an ink feed opening 110 thereon. The ceiling surface St has a circuit substrate 200 thereon. On the circuit substrate 200, an involatile storage element for storing therein information related to ink is mounted. The first side surface Sc and the second side surface Sd are located opposite to each other, and further, each thereof is located orthogonal to the anterior edge surface Sf, the ceiling surface St, the posterior edge surface Sr and the bottom surface Sb. At a position where the second side surface Sd and the anterior edge surface Sf intersect with each other, a concavo-convex connection unit 134 is located.
An arrow SD of
Here, out of the two rows, a row located at the near side in the attachment direction SD (a row located at the upper side of
The terminals 210 to 240 forming the upper side row R1 and the terminals 250 to 290 forming the lower side row R2 have the following functions (applications).
1. Upper-side Row R1
The four attachment detection terminals 210, 240, 250 and 290 are used for detecting whether electric contacts with corresponding apparatus main-body side terminals 510, 540, 550 and 590 (which will be described below with reference to
Each of the plurality of terminals 210 to 290 has the contact portion cp at the central portion thereof, which is to be contacted with a corresponding terminal of the plurality of apparatus main-body side terminals. Each of the contact portions cp of the terminals 210 to 240 forming the upper-side row R1 and each of the contact portions cp of the terminals 250 to 290 forming the lower-side row R2 are alternatively disposed, and form a so-called staggered formation. Further, each of the terminals 210 to 240 forming the upper-side row R1 and each of the terminals 250 to 290 forming the lower-side row R2 are also alternatively disposed so as to cause central lines thereof not to align in the attachment direction SD, and form a staggered formation.
The contact portions cp of the two attachment detection terminals 210 and 240 of the upper-side row R1 are disposed at both end portions of the upper-side row R1, that is, at the most outer sides of the upper-side row R1, respectively. Further, the contact portions cp of the two attachment detection terminals 250 and 290 of the lower-side row R2 are disposed at both end portions of the lower-side row R2, that is, at the most outer sides of the lower-side row R2, respectively. The contact portions cp of the memory terminals 220, 230, 260, 270 and 280 are disposed so as to gather at a substantially central portion of an area inside which the entire plurality of terminals 210 to 290 are disposed. Further, the contact portions cp of the four attachment detection terminals 210, 240, 250 and 290 are located so as to correspond to respective four corners of an aggregate of the memory terminals 220, 230, 260, 270 and 280.
The first power supply voltage VDD is a general power supply voltage (rated 3.3 V) used for logic circuits. The second power supply voltage VHV is a high voltage (for example, rated 42 V) for driving a print head to eject inks. These voltages VDD and VHV are supplied to the sub-control circuit 500, and are also supplied to other circuits in accordance with necessity. The main control circuit 400 includes a CPU 410 and a memory 420. The sub-control circuit 500 includes a memory control circuit 501 for executing accesses to the storage device 203 of the cartridge, and an attachment detection circuit 600. In addition, a circuit including the main control circuit 400 and the sub-control circuit 500 can be also referred to as “a control circuit (a control unit)”.
The apparatus main body 1010 of the printing apparatus 1000 is provided with a plurality of terminals 510 to 590 connected to the sub-control circuit 500. These apparatus main-body side terminals 510 to 590 are contacted with the plurality of terminals 210 to 290 of the printing material container (the ink cartridge) 100, respectively. Here, the terminals denoted by symbols 550 and 590 are referred to as a first detection terminal 550 and a second detection terminal 590, which are contacted with the cartridge side two first terminals 250 and 290, respectively. Further, the terminals denoted by the symbols 510 and 540 are referred to as a third detection terminal 510 and a fourth detection terminal 540, which are contacted with the cartridge side two second terminals 210 and 240, respectively.
The reset terminal 220, the clock terminal 230, the power supply terminal 260, the ground terminal 270 and the data terminal 280 of the nine terminals provided on the substrate 200 (
Here, in order to allow the sensor 208 to detect the remaining amount of ink, a liquid amount inspection signal is supplied to one of electrodes of a piezoelectric element forming the sensor 208 via the sensor terminal 290. The liquid amount inspection signal is an analog signal which is generated by a high-voltage generation unit 661 (refer to
The printing apparatus 1000 includes at least one printing material container (at least one ink cartridge or the like), which contains a printing material (an ink or the like), and is attachable to the printing apparatus 1000. The printing apparatus 1000 shown in
In this printing apparatus 1000, a sensor processing unit 660 includes two attachment/short-circuit detection units 662 and 665. The two attachment/short-circuit detection units 662 and 665 are used for detecting whether the printing material containers (the ink cartridges) IC1 and IC2 are normally attached to the printing apparatus 1000, or not, and whether at least one of two kinds of unintended abnormal short circuits exists, or not, a first one being a short circuit occurring between the first detection terminal 550 and the fourth detection terminal 540, which are originally not to be connected to each other, a second one being a short circuit occurring between the second detection terminal 590 and the third detection terminal 510, which are also originally not to be connected to each other.
In addition, short circuits to be detected here are ones which occur when the sensor processing unit (a sensor driving circuit) 660 applies the high voltage to the sensor 208, and which include all short circuits resulting in an electric conduction between the third detection terminal 510, from which a second attachment detection signal (a second detection signal) DPins shown in
In addition, in the sensor processing unit 660 shown in
(1) Attachment Detection (Contact Detection)
The attachment/short-circuit detection unit 662 includes a first detection signal generation unit 640 and the first detection unit 667, and further, the attachment/short-circuit detection circuit 665 includes a second detection signal generation unit 650 and the second detection unit 670.
The first detection signal generation unit 640 generates the first detection signal SPins. The first detection signal SPins, which is generated by the first detection signal generation unit 640, flows through a path, which will be described below in detail, and is detected by the first detection unit 667 if the first and second detection terminals 550 and 590 are contacted with the two first terminals 250 and 290 of the ink cartridge IC1, respectively. That is, the first detection signal SPins, which is generated by the first detection signal generation unit 640, flows through a path (i.e., a first attachment detection path), and is detected as a first detection response signal SPres by the first detection unit 667, the first attachment detection path including elements shown in
Here, in the case where the sensor 208, which is an example of the electric device, is a capacitive element, a voltage having been applied to one of the both terminals of the sensor 208 causes a voltage to occur at the other one of the both terminals of the sensor 208 because of a capacitive coupling. As described above, since the voltage of the first detection signal SPins transmits via the sensor 208, the first detection response signal SPres based on the first detection signal Spins can be detected by the first detection unit 667.
If the first and second detection terminals 550 and 590 are not contacted with the two first terminals 250 and 290 of the ink cartridge IC1, respectively, the first attachment detection path does not come to existence. In this case, the first detection response signal SPres based on the first detection signal SPins is never detected by the first detection unit 667. In this way, the first detection unit 667 can highly accurately detect the contacts or non-contacts of the first and second detection terminals 550 and 590 with the respective two first terminals 250 and 290 by determining whether the first detection response signal SPres based on the first detection signal SPins has been successfully detected, or not.
Moreover, an inspection with respect to another ink cartridge IC2 can be performed merely by using a switch SW1′ (a contact point a1′) and a switch SW2′ (a contact point b1′) in place of the switches SW1 and SW2 described above. In this way, it is possible to perform inspections with respect to the plurality of ink cartridges IC1 and IC2 on a time division basis.
The second detection signal generation unit 650 generates the second detection signal DPins. The second detection signal DPins, which is generated by the second detection signal generation unit 650, flows through a path, which will be described below in detail, and is detected by the second detection unit 670 if the third and fourth detection terminals 510 and 540, which are provided for each of the ink cartridges IC, are contacted with the respective two first terminals 210 and 240 of each of the ink cartridges IC. That is, the second detection signal DPins, which is generated by the second detection signal generation unit 650, flows through a path (i.e., a second attachment detection path), and is detected as a second detection response signal DPres by the second detection unit 670, the second attachment detection path including an output buffer A3; a resistor Rr; the third detection terminal 510, an ink cartridge detection path (i.e., the second terminal 210, the wiring 206 and the second terminal 240) and the fourth detection terminal 540 for each of the ink cartridges IC; and an input buffer A4.
If the third and fourth detection terminals 510 and 540 are not normally contacted with the two first terminals 210 and 240, respectively, for any of the ink cartridges IC, the second attachment detection path described above does not come to existence. In this case, the second detection response signal DPres based on the second detection signal DPins is never detected by the second detection unit 670. In this way, the second detection unit 670 can highly accurately detect the contacts or non-contacts of the third and fourth detection terminals 510 and 540 with the respective two second terminals 210 and 240 for each of the cartridges IC by determining whether the second detection response signal DPres based on the second detection signal DPins has been successfully detected, or not.
(2) Short-Circuit Detection
In this embodiment, the presence or absence of any short circuit occurring between terminals, which is likely to cause at least one of the foregoing storage device and the control circuits to be supplied with a voltage having a voltage level exceeding an absolute maximum rating therefor, is also detected by using the foregoing first and second detection signal generation units 640 and 650, as well as the foregoing first and second detection units 667 and 670. That is, the contact detection and the short-circuit detection are simultaneously carried out. The outline of this short-circuit detection will be described with reference to
In this case, the first detection unit 667 receives a signal resulting from synthesizing the first detection signal SPins flowing through the first attachment detection path described above, and the second detection signal DPins flowing through a first short-circuit path Ir2 which particularly includes a first short-circuit portion (a short-circuit resistance RSN) between the second detection terminal 590 and the fourth detection terminal 540 (the third detection terminal 510), and which includes the resistor Rr, the third detection terminal 510, the cartridge side elements (i.e., the second terminal 210, the wiring 206 and the second terminal 240), the short-circuit resistance RSN and the second detection terminal 590. Further, the first detection unit 667 detects the short circuit between the second detection terminal 590 and the third detection terminal 510 on the basis of the received signal.
In this case, the second detection unit 670 receives a signal resulting from synthesizing the second detection signal DPins flowing through the second attachment detection path described above, and the first detection signal SPins flowing through a second short-circuit path In which particularly includes a second short-circuit portion (a short-circuit resistance RSP) between the first detection terminal 550 and the third detection terminal 510 (the fourth detection terminal 540), and which includes a resistance Rc, the first detection terminal 550, the short-circuit resistance RSP, the cartridge side elements (i.e., the second terminal 210, the wiring 206 and the second terminal 240) and the fourth detection terminal 540. Further, the second detection unit 670 detects the short circuit between the first detection terminal 550 and the third detection terminal 510 on the basis of the received signal.
According to this configuration, both of the two kinds of attachment detection signals SPins and DPins are also used for the short-circuit detection, and any short circuit occurring between terminals can be detected by causing the first detection unit 667 to detect a signal based on the attachment detection signal DPins, and causing the second detection unit 670 to detect a signal based on the attachment detection signal SPins. These signals can be detected on a digital processing basis. Further, the two kinds of short-circuit detection signals SPins and DPins can be realized as, for example, pulse signals. Therefore, any analog circuit of high accuracy is not needed.
The contact detection and the short-circuit detection are usually carried out prior to detection of remaining amounts of inks during a process the printing apparatus 1000 performs upon turning on of the power supply thereof, or upon replacement of any of the ink cartridges thereof. Therefore, if any short circuit is detected with respect to a certain one of the cartridges 100 during the contact detection for detecting whether the individual cartridges 100 are correctly attached to the holder 1100, or not, it is preferable to cause the printing apparatus 1000 not to perform the detection of remaining amounts of inks, but to output a message for recommending users to replace the corresponding cartridges 100, or advising users to remove stains of the corresponding cartridges 100.
(3) Overvoltage Detection
Next, an outline of detection of an overvoltage situation due to the short circuit described above will be described. This overvoltage detection is processing for preventing occurrence of a situation in which, during the detection of remaining amounts of inks, the high voltage for driving sensors is applied to the main control circuit 400, the sub-control circuit 500 and/or the storage device 203, because of, for example, any short circuit which has not been detected during the attachment detection, but arises during the detection of remaining amounts of inks. As shown in
The high-voltage generation unit 661 can generate a high voltage having a voltage level (for example, 36V to 42V) higher than the voltage level (for example, 3.3V) of each of the voltages of the first and second detection signals SPins and DPins. The high-voltage generation unit 661 (including a high-voltage unit 663 and an output buffer A5) applies a high voltage having a voltage level (for example, 42V) to the sensor 208 via the switch TS2, and the liquid amount detection unit 664 shown in
In the case where at least one of a short circuit via the short-circuit resistance RSN (
When any short circuit occurs between at least one of the sensor terminals 250, 290, 550 and 590, and at least one of the terminals 210, 240, 510 and 540 other than the sensor terminals, and further, a voltage having a voltage level higher than a predetermined voltage level is applied to the at least one of the terminals 210, 240, 510 and 540 other than the sensor terminals, this occurrence of the overvoltage situation is detected by the overvoltage detection unit 620. In this case, for example, a protection operation, in which, upon reception of the detection result, the main control circuit (the control unit) 400 lowers or shuts off the high voltage, can be promptly carried out. Consequently, a preferable overvoltage protection operation can be carried out independently of the short-circuit detection between terminals.
(4) Detailed Description of Short-Circuit Detection
It has already been described that, in the case where a short circuit shown in
Here, regarding the impedance of the first attachment detection path, the impedance Rc of the output buffer A1 and the switch TS1, as well as the impedance of the sensor 208 (referred to as Rz), is dominant. Particularly, in the case where the sensor 208 is a capacitive element, the impedance Rz of the sensor 208 is infinitive. Therefore, the condition, in which the impedance of the first attachment detection path is to be larger than the impedance of the first short-circuit path, is satisfied. Accordingly, the first detection unit 667 can detect the second detection signal DPins flowing through the first short-circuit path Ir2, shown in
In the case where a short circuit shown in
In order to satisfy this condition, preferably, the printing apparatus 1000 shown in
The electric-current limitation resistor Rr can be set to a resistance value which satisfies the relation: Rr>Rc+RSP.
As described above, by utilizing the relatively large resistor Rz of the sensor 208 in the case where a short circuit shown in
Moreover, when any short circuit has occurred between at least one of the apparatus main-body side terminals 510 and 540, and at least one of the apparatus main-body side sensor terminals 550 and 590 and the cartridge side sensor terminals 250 and 290, a resistance value of the short circuit, which causes the short circuit to be detected by means of the overvoltage detection/the short-circuit detection so that any failures do not occur inside the main control circuit 400, the sub-control unit 500 and/or the storage device 203, will be described below. Regarding the printing apparatus 1000 shown in
That is, the following relation is preferably to be satisfied: RSN<Vmax/Ilim, RSP<Vmax/Ilim (provided that Vmax>>Vlim). This term “Vmax/Ilim” is a condition which causes each of devices targeted for protection (i.e., the control circuits and the storage device) not to suffer from any damage due to an overvoltage exceeding an absolute maximum rating therefor. Further, the term “Vmax/Ilim” is a boundary condition, below which the short-circuit detection/the overvoltage detection needs to operate effectively.
Moreover, in the printing apparatus 1000 shown in
As described above, the printing apparatus 1000 provides two kinds of detection signals, i.e., the first and second detection signals, and upon occurrence of any short circuit between terminals, the printing apparatus 1000 detects mutual interferences of the two kinds of detection signals on a digital processing basis, and then, detects the presence or absence of the short circuit with reference to a predetermined electric potential (for example, a grounding potential).
Here, when detecting the short circuit, if electric charges are stored in the capacitive element functioning as the sensor 208, an electric current arising due to the electric charges causes measurement errors. That is, the electric charges stored in the sensor (the capacitive element) 208 make it difficult to detect the presence or absence of the short circuit with reference to a predetermined electric potential (for example, a grounding potential). Therefore, it is possible to provide discharging paths which enable the electric charges stored in the sensor (the capacitive element) 208 to be discharged therethrough in advance of performing the short-circuit detection. In this embodiment, by providing discharging paths which are formed while discharging elements (MOS transistors) M1 and M4 shown in
Further, in the printing apparatus 1000 shown in
In the case where the first and third detection terminals 550 and 510 are located adjacent to each other, this situation increases the possibility that, because of, for example, electrically conductive inks, or the like, the both terminals short-circuit, thereby causing an overvoltage situation. Further, in the case where the second and fourth detection terminals 590 and 540 are located adjacent to each other, this situation increases the possibility that, because of, for example, electrically conductive inks or the like, the both terminals short-circuit, thereby causing an overvoltage situation. Therefore, it is important to implement the protection operation by means of the short-circuit detection. In the case where the first detection terminal 550 and the fourth detection terminal 540 are located adjacent to each other, and/or the second detection terminal 590 and the third detection terminal 510 are located adjacent to each other, similarly, this situation increases the possibility of causing an overvoltage state, and thus, in this case, it is also necessary to implement an overvoltage protection operation just like that described above.
The main control circuit (the control unit) 400 included in the printing apparatus 1000 shown in
According to such a control method employed by the printing apparatus 1000, it is possible to increase safety margin with respect to the high-voltage driving operation performed by the printing apparatus 1000. In addition, in
Next, an example of individual waveforms regarding the attachment detection and the short-circuit detection will be described with reference to
In the case where any short circuits do not exist, as shown in
In the case of
Meanwhile, in the case of
Furthermore, according to this embodiment, as described above, the contact detection and the short-circuit detection can be simultaneously performed. For example, the first detection unit 667 can simultaneously detect both of a contact state and a short-circuit state by determining detected levels (L, L), (L, H) and (H, L), each representing a combination of levels having been detected at the two timings (t1, t2) shown in
Hereinbefore, some examples of this embodiment have been described, and it can be understood easily by those skilled in the art that lots of modifications not substantially departing from new matters and effects of the invention can be made. Therefore, it is to be noted that all examples having such modifications are included within the scope of the invention. For example, any term described at least once together with a broader or synonymous different term in the specification or the drawings may be replaced by the different term at any place in the specification or the drawings.
The entire disclosure of Japanese Patent Application No. 2011-125991, filed on Jun. 6, 2011 is expressly incorporated herein by reference.
Number | Date | Country | Kind |
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2011-125991 | Jun 2011 | JP | national |
Number | Name | Date | Kind |
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4401999 | Brown, Jr. | Aug 1983 | A |
7364252 | Asauchi | Apr 2008 | B2 |
20070126770 | Asauchi | Jun 2007 | A1 |
Number | Date | Country |
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05-299123 | Nov 1993 | JP |
4539654 | Jul 2010 | JP |
Number | Date | Country | |
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20120306959 A1 | Dec 2012 | US |