1. Technical Field
The present invention relates to a printing material cartridge, a cartridge set and a printing apparatus in which the printing material cartridge is mountable.
2. Related Art
In recent years, a printing material cartridge is used, in which a storage device containing information (for example, ink remainder amount) regarding the printing material is loaded. Also, a technique that performs a mounting detection of the printing material cartridge is used. For example, in JP-A-2005-119228, a CPU of a printing apparatus communicates with a storage device of an ink cartridge so as to detect whether the ink cartridge is mounted or not.
However, in JP-A-2005-119228, if the mounting detection is performed during a user performing an ink cartridge exchange operation, the mounting and dismounting of the ink cartridge requires that the storage device of the cartridge be in a conductive state. In this case, a hot-plugging of the storage device is performed so that stress is applied to a semiconductor element inside the storage device by the hot-plugging and there is a possibility of inducing a bit error. Meanwhile, if the CPU does not access the storage device of the cartridge during the ink cartridge exchange operation in order to prevent the bit error, a display panel of the printing apparatus does not display which cartridge is not mounted and the user cannot be informed during the exchange operation thereof, thus there is a problem that user convenience is greatly impaired.
Also, a mounting detection technique of the ink cartridge is disclosed in JP-A-3-284953. In JP-A-3-284953, a mounting detection circuit of a printing apparatus detects a voltage that varies according to an ink resistance value inside the ink cartridge and then determines if the ink cartridge is mounted or not. However, in this technique, there is a problem that a mounting detection wiring is required to be individually arranged between each cartridge and a mounting detection circuit of the printing apparatus in order to detect the presence or absence of an individual cartridge in a plurality of ink cartridges.
JP-A-6-262771 discloses a technique in which conductive sections or resistance bodies are provided in a ink cartridge, the conductive sections or the resistance bodies are connected in series or in parallel when four ink cartridges for four colors are mounted in a printer and mounting states of the ink cartridges are detected from a voltage that is obtained in the circuits that are connected in series or in parallel. More specifically, in a first embodiment of JP-A-6-262771, the voltage is input through one signal line into a MPU according to the mounting states of the ink cartridge set in which four ink cartridges are one unit. The MPU determines, according to the voltage value, any one of (i) a usual ink cartridge set is mounted, (ii) an ink cartridge is set that is different from the usual ink cartridge set mounted and (iii) an ink cartridge is unmounted (non-mounted) or mis-mounted, and then performs a process according to the respective case. In the first embodiment, the type of the cartridge set in which four ink cartridges are one unit is detected, however the detection cannot be performed if the resistance value in even one of four cartridges is different. Thus, in a second embodiment of JP-A-6-262771, inventors design that each resistance body is provided with respect to each ink cartridge the voltages are input into the MPU respectively by four signal lines that are provided individually corresponding the resistance bodies, and the mounting state or type of an individual ink cartridge can be detected according to the voltage. As described above, in JP-A-6-262771, a technique where the mounting states or types of the ink cartridge set (in other words, four ink cartridges is one unit) are determined using one signal line that is in common in four ink cartridges and a technique where the mounting states or types of individual ink cartridge using four signal lines corresponding to four ink cartridges respectively is disclosed. However, even in the techniques of JP-A-6-262771, there is a problem in that wiring for the mounting detection is required to be individually arranged between each cartridge and the mounting detection circuit of the printing apparatus in order to detect the presence or absence of the mounting of an individual cartridge. In addition, in JP-A-6-262771, there is a problem that since arrangement positions of the conductive bodies or the resistances are different in the individual cartridges, printer side terminals are also required to be in different positions and the configuration of the apparatus becomes complicated.
In the mounting detections of JP-A-3-284953 and JP-A-6-262771, the voltage is detected and the mounting state is determined according to the mounting state of the ink cartridge. However, errors are present due to manufacturing errors or temperature dependence in the practical resistance value so that for example, in a case where the voltages according to design are approximate values to each other, there is a problem that two types of the mounting states es are necessarily not easy to determine.
Also, above-described problems are not limited to ink cartridges and are the same as that of a printing material cartridge in which another type of printing material (for example, toner) are contained.
An advantage of some aspects of the invention is that a technique is provided, in which a mounting detection of a printing material cartridge is capable of being performed by a device that is different from the related art.
The invention is to solve at least a portion of the above-described problems and is capable of being realized as the forms or applications described below.
Application 1 According to an aspect of the invention, there is provided a printing material cartridge detachably mountable inside a holder of a printing apparatus, the printing apparatus including a power supply and a mounting detection circuit having a mounting current value detection section that detects a detection current that flows when at least one printing material cartridge among a cartridge set configured of N (N is integer of 2 or more) printing material cartridges is mounted in the holder of a printing apparatus, the mounting detection circuit detecting a mounting state of the cartridge set in the holder according to the detection current,the printing material cartridge comprising:
a storage device storing information regarding the printing material cartridge;
an electric device for the mounting detection; and
a plurality of terminals including the storage device terminals and the electric device terminals;
wherein,
the electric device is,
(i) connected in parallel to each other to the electric device of another printing material cartridge among the cartridge set between the power supply and the mounting current value detection section, and (ii) configured such that the detection current is a predetermined threshold value current or more when N printing material cartridges are mounted inside the holder a printing material cartridge mounted inside a holder of a printing apparatus including: a mounting detection circuit having a power supply for mounting detection; and a mounting current value detection section that detects a detection current that flows when a cartridge set configured of N (N is integer of 2 or more) printing material cartridges is mounted in the holder of a printing apparatus, the mounting detection circuit detecting a mounting state of the printing material cartridge in the holder according to the detection current, wherein the printing material cartridge has a storage device storing information regarding contained printing material, an electric device for the mounting detection and a plurality of terminals including the storage device terminals and the electric device terminals,
the electric device is,
(i) connected in parallel to each other to the electric device of another printing material cartridge configured of the cartridge set between the power supply for mounting detection and the mounting current value detection section, and (ii) configured such that the detection current that is detected at the mounting current value detection section is a predetermined threshold value current or more when N printing material cartridges are mounted inside the holder.
According to the printing material cartridge, the detection current is determined according to the mounting state of the electric device for the mounting detection that is provided individually from the storage device and the detection current is predetermined threshold value current or more when N printing material cartridges are mounted inside the holder so that the printing material cartridge is capable of determining whether it is properly mounted or not inside the holder. In addition, when the mounting detection of the printing material cartridge is performed, there is no need for concern of a bit error due to the hot-plugging of the storage device.
It is preferable that the electric device is configured such that the detection current is a different current value according to 2N types of mounting states regarding N printing material cartridges.
According to the configuration, the detection current takes the current value that is identified at once according to 2N types of mounting states so that the mounting state of the printing material cartridge in the holder is capable of determining any one of 2N types of mounting states by the detection current.
It is preferable that the electric device is a resistance element.
According to the configuration, even if an error within allowable range is present at an individual resistance value, 2N types of mounting states are capable of being identified by the detection current.
According to another aspect of the invention, there is provided a cartridge set configured of N (N is integer of 2 or more) printing material cartridges and mountable inside a holder of the same printing apparatus,
wherein individual printing material cartridge configured of the cartridge set is the printing material cartridges according to any one of claims 1 to 2 and arrangement of contacting sections of the printing apparatus side terminals and the plurality of terminals on each printing material cartridge is common in the N printing material cartridges.
According to the configuration, the arrangement of the contacting section in the printing apparatus side terminals or the terminals of the printing material cartridge is capable of being in common at N printing material cartridges so that the configuration of the terminals or the contacting section is simplified.
It is preferable that the resistance element of an individual printing material cartridge have the same resistance value.
According to the configuration, the configuration of an individual printing material cartridge that is configured of cartridges is capable of being further simplified.
It is preferable that a voltage applied to both ends of the resistance element of an individual printing material cartridge be 42V or less and a resistance value of the resistance element of an individual printing material cartridge may be 20 kΩ or more.
According to the configuration, even if the highest voltage is applied at the resistance element, the current is capable of being suppressed at 2.1 mA or less, so that excessive current does not flow in the circuit and the circuit is capable of being protected.
According to still another aspect of the invention, there is provided a printing apparatus including: a holder in which a cartridge set configured of N (N is integer of 2 or more) printing material cartridges that are independently mountable and different from each other is mounted; a power supply for mounting detection; and a mounting detection circuit including a mounting current value detection section that detects a detection current that flows when one or more printing material cartridges in the holder are mounted, the mounting detection circuit detecting a mounting state of N printing material cartridges according to the detection current,
wherein each of N printing material cartridges has a storage device storing information regarding the printing material cartridge, a electric device for the mounting detection and a plurality of terminals including the storage device terminals and the electric device terminals,
the electric device of N printing material cartridges is,
(i) connected in parallel between the power supply for mounting detection and the mounting current value detection section, and (ii) configured such that the detection current that is detected at the mounting current value detection section is a predetermined threshold value current or more when N printing material cartridges are mounted inside the holder.
According to the printing apparatus, the detection current is determined according to the mounting state of the electric device for the mounting detection that is provided individually from the storage device and the detection current is predetermined threshold value current or more when N printing material cartridges are all mounted inside the holder so that the printing material cartridge is capable of determining whether it is properly mounted or not inside the holder. In addition, when the mounting detection of the printing material cartridge is performed, there is no need for concern of a bit error due to the hot-plugging of the storage device.
It is preferable that the electric device of N printing material cartridges be configured such that the detection current is a different current value according to 2N types of mounting states regarding N printing material cartridges.
According to the configuration, the detection current takes the current value that is identified at once according to 2N types of mounting states so that the mounting state of the printing material cartridge in the holder is capable of determining any one of 2N types of mounting states by the detection current.
It is preferable that the printing apparatus further comprising a resistance element of apparatus side;
wherein the electric device of nth (n=1 to N) printing material cartridge in N printing material cartridges is a resistance element,
According to the configuration, even if an error within allowable range is present at an individual resistance value, 2N types of mounting states are capable of being identified by the detection current.
It is preferable that the mounting current value detection section include: a current-voltage converting section that generates the detection voltage by converting the detection current into the voltage; an A-D converting section that compares the mounting detection voltage with a plurality of threshold value voltages and converts it into a digital detection signal; and a voltage correction section that corrects the plurality of threshold value voltages according to variation of the voltage of the power source for the mounting detection, wherein the mounting detection circuit determines the mounting state of the printing material cartridge in the holder based on the digital detection signal.
According to the configuration, the threshold value voltage that is used when the detection current is converted into the digital detection signal is adjusted so as to follow the voltage of the power supply for the mounting detection so that the mounting state is capable of being exactly detected even though the voltage of the power supply for mounting detection is varied.
It is preferable that a voltage that is higher than the voltage that is applied to the storage device terminal is supplied from the power supply for the mounting detection to the electric device terminal,
wherein N printing material cartridges further have overvoltage detection terminals respectively, which are provided near the electric device terminals, and
wherein the supply of the voltage from the power supply for the mounting detection to the electric device is stopped when the overvoltage is detected through the overvoltage detection terminal.
According to the configuration, when unintentional short-circuiting occurs between the terminal for the electric device terminal and overvoltage detection terminal by foreign materials such as ink or dust, the overvoltage is detected immediately so that the possibility that the high voltage for the mounting detection is applied to other circuits and then damage the other circuits caused by unintentional short-circuiting can be decreased.
Also, the invention can be realized in various embodiments for example, a printing material cartridge, a printing material cartridge set that is configured of a plurality types of printing material cartridges, a cartridge adapter, a cartridge adapter set that is configured of a plurality types of cartridge adapters, a printing apparatus and a mounting detection method of the printing material cartridge.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
The carriage 3 includes a holder 4, the printing head 5 and a carriage circuit (described below). The holder 4 is detachably configured of a plurality of ink cartridges and arranged on the upper surface of the printing head 5. In the embodiment shown in
An arrow Z in
The terminals 210 to 240 that form the upper side row and the terminals 250 to 290 that form the lower side row are arranged as described below respectively.
Each of the terminals 210 to 290 includes a contacting section cp that contacts the corresponding terminal in a plurality of device side terminals. Each of the contacting sections cp of the terminals 210 to 240 that form the upper side row and each of the contacting sections cp of the terminals 250 to 290 that form the lower side row are arranged differently to each other and configures so called zigzag-shaped arrangement. Also, the terminals 210 to 240 that form the upper side row and the terminals 250 to 290 that form the lower side row are arranged differently to each other and configures so called zigzag-shaped arrangement so that terminal center each other is not in a line in the insertion direction Z.
The first mounting detection terminal 250 is adjacent to two terminals (the power supply terminal 260 and the first overvoltage detection terminal 210) and the first overvoltage detection terminal 210 of these terminals is near the first mounting detection terminal 250, and especially, is arranged nearest to the first mounting detection terminal 250. Similarly, the second mounting detection terminal 290 is adjacent to two terminals (the second overvoltage detection terminal 240 and the data terminal 280) and the second overvoltage detection terminal 240 of these terminals is near the second mounting detection terminal 290, and especially, is arranged nearest to the second mounting detection terminal 290.
Regarding the relation between the contacting sections cp, the contacting section cp of the first mounting detection terminal 250 is adjacent to each of the contacting sections cp of two terminals (the power supply terminal 260 and the first overvoltage detection terminal 210). Similarly, the contacting section cp of the second mounting detection terminal 290 is adjacent to each of the contacting sections cp of two terminals (the second overvoltage detection terminal 240 and the data terminal 280).
As is understandable from
Also, the contacting sections cp of the first and the second mounting detection terminals 250 and 290 are positioned at both ends of the lower side row that are formed by the contacting section cp of each of terminals, in other words, at the outermost side of the lower side row respectively. Also, the contacting sections cp of the first and the second mounting detection terminals 250 and 290 are positioned at the outermost side of the contacting sections cp of the mounting detection terminals 210 to 290 that include the upper side row and the lower side row in a substantially vertical direction to the insertion direction Z.
The first and the second overvoltage detection terminals 210 and 240 are arranged at both ends of the upper side row, in other words, at the outermost side of the upper side row. As a result, similar to the above description, the contacting sections cp of the first and the second overvoltage detection terminals 210 and 240 are arranged at both ends of the upper side row that are formed by the contacting section cp of each of terminals, in other words, at the outermost side thereof. Accordingly, the terminals 220, 230, 260, 270, and 280 for the storage device 203 are arranged so as to be pinched from both sides between a pair of the first overvoltage detection terminal 210 and the first mounting detection terminal 250 and a pair of the second overvoltage detection terminal 240 and the second mounting detection terminal 290.
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 that are provided at the substrate 200 (
The first and the second overvoltage detection terminals 210 and 240 are connected to each other through wiring inside the substrate 200 (
Wiring names RST, SCK, VDD, SDA, VSS, OV1, OV2, DT1 and DT2 are applied to wirings that connect the carriage circuit 500 and the ink cartridge 100 by the device side terminals 510 to 590 and the terminals 210 to 290 of the substrate 200. From among these wiring names, the wiring names for the storage device use the same names as the signal names.
The memory control circuit 501 is a circuit to control the storage device 203 of the cartridge 100 so as to perform reading and writing of the data. The memory control circuit 501 and the storage device 203 of the cartridge are low voltage circuits that are operated at a relatively low voltage (in the embodiment, regular 3.3V).
The mounting detection circuit 600 is a circuit in order to perform the mounting detection of the cartridge in the holder 4. The mounting detection circuit 600 and the resistance element 204 of the cartridge are high voltage circuits that are operated at a high voltage (in the embodiment, regular 42V) compared to the storage device 203.
When one or more cartridges are unmounted or non-mounted, according to that, the composition resistance value Rc is increased and the detection current IDET is decreased.
If four cartridges IC1 to IC4 are all mounting states, the detection current IDET is the maximum value I max. Meanwhile, in a state where only the cartridge IC4 that correspond to the resistance 704 having the largest resistance value is unmounted, the detection current IDET is 0.93 times the maximum value Imax. Accordingly, if investigation is performed whether the detection current IDET is the threshold value current Ithmax or more, or not which is predetermined value between two current values, it can detect whether four cartridges IC1 to IC4 are all mounted or not. In addition, in order to perform individual mounting detection, the reason for using a voltage VHV that is higher than the power supply voltage (about 3.3V) of the usual logic circuit is to increase the detection precision by widening the dynamic range of the detection current IDET so that the detection precision is increased.
The graph of the detection current IDET shown in
The individual mounting current value detection section 630 converts the detection current IDET to a digital detection signal SIDET and then transmits the digital detection signal SIDET to the determination section 660. The determination section 660 can determine any one of the sixteen types of mounting states by the value of the digital detection signal SIDET. When the determination is that one or more cartridges are unmounted, the determination section 660 displays the information (letter or image) illustrating the unmounting state at the display panel 30 and informs the information to the user.
In the first embodiment, the unmounting state of each of cartridges is displayed on the display panel 30 during the exchange of cartridges so that the user sees the display and then may perform the exchange of the cartridges. Especially, when cartridges are exchanged, the display panel 30 displays that the cartridge is changed from the unmounting to the mounting so that even though a user is inexperienced with cartridge exchange operation, the user is capable of processing next operation with an easy mind. In addition, in the first embodiment, mounting and removing, and mounting detection of the cartridge is capable of being performed in a state where the storage device 203 of the cartridge is in a non-conductive. Accordingly, a bit error that is generated by the so-called hot-plugging of the storage device is preventable.
As described in
First of all, a case where the number N of cartridges is four is considered. When the allowable error of the resistance value is c, the resistance value of each resistance element 204 (
Here, Rc1max is the composition resistance value in a case where all cartridges are mounted, and
Rc2min is the composition resistance value in a case where only 4th cartridge is not mounted.
Rc1max and Rc2min in the formula 3 are given in below formula respectively.
When the formulas (4) and (5) substitute to formula (3), formula (6) is established and if it is modified, it will be formula (7).
In the formula 7, the error ε is sufficiently small compared to 1, so that if (1−ε)=1, following formula is established, and the allowable error ε of the resistance value is 3.6%.
ε<0.036=3.6% (8)
When the above-described consideration is generalized, if the number of cartridges is N, the allowable error ε is given according to following formula.
In other words, if the allowable error ε satisfies the formula (9), the composition resistance value Rc is always determined at once according to the mounting states of N cartridges and then the detection current IDET is capable of assuring the determination at once. However, it is desirable that the allowable error of the resistance value in practical design be set to a value that is smaller than the right side of the formula (9). In addition, the allowable error of the resistance values of the resistances 701 to 704 may be set to a sufficiently small value (for example, predetermined value that is 1% or less) without performing the above-described consideration.
The cartridge detection circuit 502 is a circuit that cooperates with the main control circuit 40 and performs the mounting detection of the cartridge on the holder 4. In addition, in the second embodiment, the cartridge detection circuit 502 cooperates with the main control circuit 40 so that the mounting detection process is performed similar to the mounting detection circuit 600 (
Inside of the cartridge detection circuit 502, the high voltage power supply VHV for mounting detection is provided. The high voltage power supply VHV is connected in parallel to four device side terminals 550 that are provided at the mounting position of each of the cartridges IC1 to IC4 through a transistor 612. The voltage value of the high voltage power supply VHV is referred to as “the high voltage VHV”. on/off of the transistor 612 is controlled by the detection voltage control section 610. Each of the device side terminals 550 is connected to the first mounting detection terminal 250 of the corresponding cartridge. The resistance elements 204 are provided between the first and the second mounting detection terminal 250 and 290 inside each cartridge. The resistance values of the resistance elements 204 of four cartridges IC1 to IC4 is set to the same value R. Resistance elements 631 to 634 that are connected respectively in series to the resistance element 204 of each of cartridges inside the cartridge detection circuit 502 are provided. Resistance values of the resistance elements 631 to 634 are set in different values from each other. Especially, the resistance value of the resistance element 63n that corresponds to the nth (n=1 to 4) cartridge ICn of the resistance elements 631 to 634 is set to (2n−1)R (R is a constant value). As a result, the resistance connected in series having 2nR of resistance value is formed according to the serial connection between the resistance element 204 inside nth cartridge and the resistance element 63n inside the cartridge detection circuit 502. In addition, these resistances connected in series are the same as that shown in
The first and the second overvoltage detection terminals 210 and 240 are connected with a wiring inside each cartridge. The first overvoltage detection terminal 210 of the first cartridge IC1 is connected to a wiring 651 inside the cartridge detection circuit 502 through corresponding device side terminal 510 and the wiring 651 is connected to a low voltage power supply VDD through the resistance 652. In addition, the wiring 651 is connected to the non-mounting state detection section 430 (
Furthermore, the first overvoltage detection terminals 210 of four cartridges IC1 to IC4 are connected to anode terminals of the diodes 641 to 644 through corresponding device side terminal 510. Also, the second overvoltage detection terminals 240 of four cartridges IC1 to IC4 are connected to anode terminals of the diodes 642 to 645 through corresponding device side terminal 540. The anode terminal of the second diode 642 is commonly connected to the second overvoltage detection terminal 240 of the first cartridges IC1 and the first overvoltage detection terminal 210 of the second cartridges IC2. Similarly, the diodes 643 and 644 are commonly connected to the second overvoltage detection terminal 240 of one cartridge and the first overvoltage detection terminal 210 of the adjacent cartridge. Cathode terminals of the diodes 641 to 645 are connected in parallel to the overvoltage detection section 620. The diodes 641 to 645 are used to monitor whether an abnormal high voltage (specifically, a voltage that exceeds the voltage value of the low voltage power supply VDD) is applied or not to the overvoltage detection terminals 210 and 240. Such an abnormal voltage value (referred to as “overvoltage”) is generated when unintentional short-circuiting is generated between any one of the overvoltage detection terminals 210 and 240 of each cartridge, and any one of the mounting detection terminals 250 to 290 of each cartridge. For example, when ink droplets or dust become attached to the surface of the substrate 200 (
As described above, in the second embodiment, the overvoltage detection terminals 210 and 240 are used in two processes, wherein two processes are that the detection process whether all cartridges are mounted in the holder 4 or not (the mounting detection of all cartridges) and the detection process that the unintentional short-circuiting is present or not between the overvoltage detection terminals 210 and 240, and the mounting detection terminals 250 and 290. However, one or both of two detection processes may be omitted. If two detection processes that use the overvoltage detection terminals 210 and 240 are not performed at both, circuit elements such as the overvoltage detection terminals 210, 240, 510 and 540, the diodes 641 to 645, and the overvoltage detection section 620 may be omitted.
When the carriage 3 stops at the cartridge exchange position, the non-mounting state detection section 430 (
IDET is the first threshold value or less, all cartridges are non-mounted and then the process in
When the individual mounting detection process finishes, it returns to step S130 in
As described above, in the second embodiment, the non-mounting state of each cartridge can inform to the user during the exchange of cartridges so that the user sees the display while performs the exchange of the cartridges. Especially, when cartridge is exchanged and new cartridge is mounted on the holder 4, the intent that the cartridge is mounted is displayed on the display panel 30 so that even though a user is inexperienced with the cartridge exchange operation, the user is capable of processing next operation with an easy mind. In addition, in the second embodiment, mounting and removing, and mounting detection of the cartridge is capable of being performed in a state where the storage device 203 of the cartridge is in a non-conductive state. Accordingly, bit error that is generated by so-called hot-plugging of the storage device is preventable.
Also, in the second embodiment, if overvoltage is generated at the overvoltage detection terminals 210 and 240, applying of the high voltage VHV for mounting detection is canceled instantly so that damage in the electric circuit of the printing apparatus or cartridge due to the overvoltage is preventable.
In addition, in an electric device that is connected to the mounting detection terminals 250 and 290 (
Various modified examples or modified examples regarding the first and the second embodiments may be applied to other embodiments described below.
Entire configuration of the circuit of the third embodiment is the same as the configuration of the second embodiment shown in
The current-voltage converting section 710 is an inverting amplifier circuit that is configured of an operational amplifier 712 and a return resistance R11. The output voltage VDET of the operational amplifier 712 is given in below formula.
Here VHO is an output voltage of the transistor 512 (
In addition, the voltage VDET that is given in formula 10 illustrates a value that is inversed voltage IDET·R11 by the detection current IDET. Thus, the inverting amplifier is added to the current-voltage converting section 710 and the voltage that inverses the voltage VDET at the added inverting amplifier may be output as the output voltage of the current-voltage converting section 710. It is desirable that the absolute value of the amplifying rate of the added inverting amplifier be 1.
The voltage comparison section 720 has a threshold value voltage generating section 722, a comparator 724 (the operational amplifier) and a changeover control section 726. The threshold value voltage generating section 722 selects one of a plurality of threshold value voltages Vth(j) that is obtained by dividing a reference voltage Vref into a plurality of resistances R1 to Rm as a changeover switch 723 and outputs it. The plurality of threshold value voltages Vth(j) correspond to the threshold values that identify the values of the detection current IDET in sixteen types of the mounting states shown in
The comparison result storage section 730 changes over the comparison result of two values that are output from the voltage comparison section 720 in the changeover switch 732 and accommodate it in an appropriate bit position inside the bit resistor 734. The changeover timing of the changeover switch 732 is designated from the changeover control section 726. The bit resister 734 has N (here, N=4) cartridge detection bits that shows the presence or absence of the mounting of an individual cartridge that can be mounted on the printing apparatus and an abnormal flag bit that shows an abnormal current value being detected (the current value is predetermined abnormal determination value or more). The abnormal flag bit becomes H level if a significantly large current flows compared to the current value Imax (
Both the voltage comparison section 720 and the comparison result storage section 730 configures so-called an A-D converting section. As the A-D converting section, known various other configurations may be employed instead of the voltage comparison section 720 and the comparison result storage section 730 shown in
A voltage correcting section 740 is a circuit to correct the plurality of the threshold value voltages Vth(j) that are generated in the threshold value voltage generating section 722 following the change of the high voltage VHV (
The voltage AGND is used as the reference voltage AGND of the low voltage side of the threshold value voltage generating section 722. For example, if Vref=2.4V, VHO=42V, R21=20 kΩ and R22=400 kΩ, AGND=0.42V is established. It may be understandable when above-described formula 10 and formula 11 are compared, the reference voltage AGND of the low voltage side of the threshold value voltage generating section 722 changes according to the value of the output voltage VHO (in other words, the high voltage power supply VHV for mounting detection) of the transistor 612, similar to the detection voltage value VDET. The difference between two voltages AGND and VDET is generated by the difference between resistance ratio between R21/R22 and R11/Rc. As described above, when the voltage correcting section 740 is used, the plurality of the threshold value voltages Vth(j) that are generated at the threshold value voltage generating section 722 changes following the change of the power supply voltage VHV even though the power supply voltage VHV for mounting detection is changed by any cause. As a result, both the detection voltage value VDET and the plurality of the threshold value voltages Vth(j) change following the change of the power supply voltage VHV so that the result of comparison that shows a precision mounting state is obtainable in the voltage comparison section 720. Specifically, when the values of the resistance ratio R21/R22 and the resistance ratio R11/Rc1 (Rc1 is the composition resistance value when all cartridges are mounted) are set in the same value, the detection voltage value VDET and the plurality of the threshold value voltages Vth(j) may precisely follow the change of the power supply voltage VHV so as to change with substantially the same change width. However, the voltage comparison section 720 may be omitted.
As described above, even in the third embodiment, advantages the same as the second embodiment may be present. In other words, the unmounting state of an individual cartridge is displayed on the display panel 30 during the exchange of cartridge so that the user performs the exchange of the cartridge while seeing the display. Also, mounting and removing, and the mounting detection of the cartridge are capable of being performed in a state where the storage device 203 of the cartridge is in a non-conductive state. Accordingly, bit error that is generated by so-called hot-plugging of the storage device is preventable. Furthermore, if overvoltage is generated at the overvoltage detection terminals 250 and 290, applying of the high voltage VHV for mounting detection is canceled instantly so that damage in the electric circuit of the printing apparatus or cartridge due to the overvoltage is preventable. Furthermore, in the third embodiment, the individual bit value of the digital detection signal SIDET that is generated at the individual mounting current value detection section 630a shows the presence or absence of the mounting of an individual cartridge so that the presence or absence of the mounting of an individual cartridge is determined at once by the bit value of the digital detection signal SIDET.
If such input changeover switch 750 is provided, the mounting detection of each cartridge may be performed the same as above description even in a printing apparatus where the plurality of cartridges are mounted.
In
In
(1) The resistance value of each resistance element is 20 kΩ or more.
Then, the current that flows to the resistance element is capable of being limited to 2.1 mA or less as the calculation described below even though it is supposed that the highest voltage VHV that is used at the mounting detection circuit is applied to 20 kΩ of resistance element.
(44.1V−2.4V)/20 kΩ=2.085 mA<2.1 mA
Here, 44.1V is maximum value (absolute maximum voltage=42V+5%) of the voltage VHV when the regular value of the voltage VHV is 42V and allowable range is ±5%. Also, 2.4V is a value of the reference voltage Vref that is used at the current-voltage converting section 710. (44.1V−2.4V)=41.7V corresponds to the maximum value of the voltage that is applied to both end of the resistance element. As described above, when the resistance value of each resistance element is 20 Ω or more, the current is capable of being limited to 2.1 mA or less so that the ASIC that realizes the mounting detection circuit is capable of being protected.
(2) The resistance value of the resistance element 204 that is loaded on the ink cartridge is larger than the minimum resistance value of the resistance elements 631 to 633 inside the mounting detection circuit.
Then, by any possibility, even though the resistance element 204 that is loaded on the ink cartridge is short-circuited for any reason, the abnormal state is easily detected. In addition, the resistance element 204 is traditionally attached at rear surface side of the substrate 200 (
(3) The minimum value of the detection current IDET is 100 μA or more.
Then, even though if influence of disturbance (noise) is present, the detection current IDET easily and correctly determines the mounting state of the cartridge. In addition, in the circuit configuration shown in
Also, these conditions (1) to (3) are desirable conditions, however these conditions are not essentially satisfied and other conditions may be set.
In addition, in
In the fourth embodiment shown in
The ink container 100B includes a case 101B that contains ink and the ink supply opening 110. An ink chamber 120B that contains ink is formed inside the case 101B. The ink supply opening 110 is formed at the bottom wall of the case 101B. The ink supply opening 110 communicates with the ink chamber 120B.
The adapter 100A includes a main body 101A and the substrate 200. A space 101AS that receives the ink container 100B is formed inside the main body 101A. An opening that communicates with the space 101AS is provided on the upper portion of the main body 101A. In a state where the ink container 100B is received within the space 101AS, the ink supply opening 110 is projected to outside of the adapter 100A through an opening 101AH. In addition, a portion of sidewall of the adapter 100A may be omitted.
As described above, the ink cartridge is capable of being separated into the ink container 100B (also referred to as “printing material containing body”) and the adapter 100A. In this case, it is desirable that the circuit substrate 200 be provided at the adapter 100A side.
Also, the invention is not limited to the above-described embodiments or examples, various forms may be performed without departing from the gist thereof and for example, and modifications may be performed as below.
In above-described each of the embodiments, the storage device 203 and the resistance element 204 are loaded on the ink cartridge, however a plurality of electrical devices that are loaded on the ink cartridge are not limited to them and one or more arbitrary types of electrical devices may be loaded on the ink cartridge. For example, as a sensor for the ink amount detection, an electrical device (for example, a piezoelectric element or a resistance element) may be provided in the ink cartridge instead of the optical sensor. In addition, in the above-described embodiments, both the storage device 203 and the resistance element 204 are provided at the substrate 200, however the electrical device of the cartridge may be arranged on any arbitrary member. For example, the storage device 203 may be arranged on a structure body other than the casing of the cartridge, the adapter or cartridge.
In above-described each of the embodiments, four resistances for mounting detection 701 to 704 are formed with the resistance element 204 inside nth cartridge and corresponding resistance element 63n (n=1 to 4) inside the cartridge detection circuit 502, however the resistance value of the resistance for mounting detection may be realized by only one resistance element. Also, it may be realized by three or more resistance elements. For example, the resistance 701 for mounting detection that is configured of two resistance elements 204 and 631 may be substituted with single resistance element. Other resistances for mounting detection are also the same as the above description. In a case where one resistance for mounting detection is configured of a plurality of resistance elements, the resistance values of the resistance elements may be distributed arbitrarily. Also, a single resistance element or the plurality of resistance elements may be provided on only one side of the cartridge and the main body of the printing apparatus. For example, if all the resistances for mounting detection are mounted on the cartridge, the resistance elements that configure resistances for mounting detection are not required at the main body of the printing apparatus.
Constitutional elements in the various constitutions that are described in the above-described embodiments, which do not relate to a specific object•effect•advantage may be omitted. For example, the storage device 203 inside the cartridge may be omitted in a case where the individual mounting detection of the cartridge is a main object since it is not used in the individual mounting detection of the cartridge.
In above-described each of the embodiments, the invention is applied to an ink cartridge, however the invention is not limited to the ink cartridge and may be applied similarly to even other printing materials for example, a printing material containing body that contains toner.
The entire disclosure of Japanese Patent Applications Nos. 2010-197314, filed Sep. 3rd, 2010 and 2011-151692, filed Jul. 8th, 2011 are expressly incorporated by reference herein.
Number | Date | Country | Kind |
---|---|---|---|
2010-197314 | Sep 2010 | JP | national |
2011-151692 | Jul 2011 | JP | national |