JP5759116B2 - Inkjet printing device - Google Patents

Description

  The present invention relates to an inkjet printing apparatus that performs printing on printing paper by ejecting ink with an inkjet head.

  In general, an inkjet printing apparatus to which an inkjet method is applied prints images, characters, and the like by ejecting ink from a nozzle of an inkjet head toward printing paper based on print data such as image information and character information. In addition, since print data can be printed in color on printing paper using multi-color ink, it is widely used for home use and business use.

  The ink used in such an ink jet printing apparatus has a temperature characteristic in which the viscosity changes depending on temperature conditions such that the viscosity is high at a low temperature and the viscosity is low at a high temperature. In particular, when the viscosity of the ink increases, the size of the ink droplets and the ejection speed vary, and it may be impossible to obtain a high-definition printed matter. Furthermore, when the temperature of the ink becomes too high, the ink may be deteriorated.

  Therefore, the ink jet printing apparatus is provided with a heating unit that measures the temperature of the ink supplied to the ink jet head so that appropriate printing is possible, and heats the ink based on the measured temperature.

  Patent Document 1 proposes an ink jet printer including an induction heating unit that heats a nozzle plate by electromagnetic induction heating.

JP 2008-44128 A

  However, in a general ink jet printing apparatus, since there is a heat loss between heating by the heating unit and supplying to the ink jet head, the measured temperature of the ink and the temperature of the ink heated by the heating unit are different. There was a case that did not match. Therefore, if the ink is heated based on the measured temperature, it may be heated more than necessary. Furthermore, the ink may be overheated and deteriorated.

  In addition, there is a problem in burning out apparatus members at abnormal temperature rise due to system malfunction.

  The ink jet printer described in Patent Document 1 includes an induction heating unit that heats the nozzle plate, but it is very difficult to measure the temperature of the ink in contact with the nozzle plate.

  SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and is an ink jet printing apparatus that controls ink to an appropriate temperature without newly installing a thermometer and without fear of abnormal temperature rise even in a system malfunction. The purpose is to provide.

In order to achieve the above object, a first feature of an ink jet printing apparatus according to the present invention is an ink jet head that ejects ink onto a print medium, a first coil that generates a magnetic field when energized, and the ink jet head. Guarantees the quality of the ink, the first magnetic shunt alloy having a stable ejection temperature, which is a temperature at which ink can be ejected stably, and the second coil that generates a magnetic field when energized. A second magnetic shunt alloy having a quality assurance upper limit temperature, which is an upper limit temperature, having a Curie temperature, and the first magnetic shunt alloy generates heat by induction by the magnetic field generated by the first coil. And heating the ink by induction heat generation of the second magnetic shunt alloy by the magnetic field generated by the second coil .

  A second feature of the ink jet printing apparatus according to the present invention is that the first magnetism adjustment is based on a load detecting unit that detects a driving load of the first coil, and a driving load detected by the load detecting unit. Determining means for determining whether or not the alloy has exceeded the Curie temperature; and control for stopping energization of the first coil when the determining means determines that the first magnetic shunt alloy has exceeded the Curie temperature. Means.

A third feature of the ink jet printing apparatus according to the present invention is that a load detection unit that detects a drive load of the first coil, and the first magnetic shunt based on the drive load detected by the load detection unit. Determining means for determining whether or not the alloy has exceeded the Curie temperature; and control for stopping energization of the second coil when the determining means determines that the first magnetic shunt alloy has exceeded the Curie temperature. Means.

A fourth feature of the ink jet printing apparatus according to the present invention further comprises temperature detecting means for detecting the temperature of the ink, and the control means is configured such that the temperature detected by the temperature detecting means is equal to the stable ejection temperature. When the temperature is equal to or lower than the first temperature, which is lower than the first coil, only the first coil and the second coil are energized, and the temperature detected by the temperature detection means is lower than the stable discharge temperature, When the temperature exceeds the first temperature, the second coil is energized.

A fifth feature of the ink jet printing apparatus according to the present invention is that the temperature detected by the temperature detecting means is higher than a lower limit value of a temperature width at which the ink jet head can stably discharge the ink. The first coil is energized so that the first magnetic shunt alloy does not exceed the Curie temperature when the temperature is lower than the median value of the stable discharge temperature range.
A sixth feature of the ink jet printing apparatus according to the present invention is an ink jet head that discharges ink onto a print medium, a coil that generates a magnetic field when energized, and an upper limit temperature that guarantees the quality of the ink. A magnetic shunt alloy having a certain quality assurance upper limit temperature as a Curie temperature, and the magnetic shunt alloy heats by induction heat generated by the magnetic field generated by the coil.

According to the first feature of the ink jet printing apparatus of the present invention, the first magnetic shunt alloy heats by induction heat generated by the magnetic field generated by the first coil, and is generated by the second coil. Since the second magnetic shunt alloy heats the ink by induction heat generation by the generated magnetic field , the ink can be controlled to an appropriate temperature without installing a new thermometer, and abnormal temperature rise due to system malfunction It is possible to control to an appropriate temperature in a short time without worrying about the problem and without changing the quality of the ink.

  According to the second feature of the inkjet printing apparatus according to the present invention, when it is determined that the first magnetic shunt alloy has exceeded the Curie temperature, the energization to the first coil is stopped. Power consumption can be reduced.

According to the third feature of the ink jet printing apparatus according to the present invention, when it is determined that the first magnetic shunt alloy has exceeded the Curie temperature, the energization to the second coil is stopped. Power consumption can be reduced.

According to the fourth feature of the ink jet printing apparatus according to the present invention, when the temperature detected by the temperature detecting means is equal to or lower than the first temperature that is lower than the stable discharge temperature, the first coil and the first coil Since the second coil is energized, the second coil can be heated rapidly, and when the temperature detected by the temperature detecting means is lower than the stable discharge temperature and exceeds the first temperature, Since power is supplied, power consumption can be optimized. In addition, since the magnetic shunt alloy heats the ink by generating dielectric heat, there is no fear of abnormal temperature rise due to system malfunction.

According to the fifth feature of the ink jet printing apparatus according to the present invention, the temperature detected by the temperature detecting means is higher than the lower limit value of the temperature width at which the ink jet head can stably eject ink and lower than the median value. In addition, since the first coil is energized so that the first magnetic shunt alloy does not exceed the Curie temperature, the temperature of the ink can be efficiently maintained. In addition, since the magnetic shunt alloy heats the ink by generating dielectric heat, there is no fear of abnormal temperature rise due to system malfunction.
Furthermore, according to the sixth feature of the ink jet printing apparatus according to the present invention, an ink jet head that ejects ink onto a print medium, a coil that generates a magnetic field when energized, and an upper limit temperature that guarantees the quality of the ink With the magnetic shunt alloy whose quality assurance upper limit temperature is the Curie temperature, and because the magnetic shunt alloy heats by induction heat generation by the magnetic field generated by the coil, without installing a new thermometer, Without changing the quality of the ink, it can be controlled to an appropriate temperature in a short time, and there is no fear of abnormal temperature rise due to system malfunction.

It is a figure which shows the outline | summary of the inkjet printing apparatus which concerns on Example 1 of this invention. FIG. 3 is a diagram illustrating a functional configuration of an ink circulation path-related mechanism and a control unit of the ink jet printing apparatus according to the first embodiment of the present invention. (A) is a perspective view of the heater provided in the inkjet printing apparatus which concerns on Example 1 of this invention, (b) is a cross section of the heater provided in the inkjet printing apparatus which concerns on Example 1 of this invention. FIG. It is a circuit block diagram of the heater with which the inkjet printing apparatus which concerns on Example 1 of this invention was equipped. It is the figure which showed the magnetic permeability of the magnetic shunt alloy with which the inkjet printing apparatus which concerns on Example 1 of this invention was equipped, and the circuit load. It is the flowchart which showed the process sequence in the inkjet printing apparatus which concerns on Example 1 of this invention. It is the figure explaining the relationship between the temperature of the ink and control of a coil in the inkjet printing apparatus which concerns on Example 1 of this invention. It is a perspective view of the heater with which the inkjet printing apparatus which concerns on Example 2 of this invention was equipped. It is a perspective view of the heater with which the inkjet printing apparatus which concerns on Example 3 of this invention was equipped. It is a perspective view of the heater with which the inkjet printing apparatus which concerns on Example 4 of this invention was equipped.

  Embodiments of the present invention will be described with reference to the drawings.

<Configuration of inkjet printing apparatus>
In the first embodiment of the present invention, a plurality of inkjet heads having a large number of nozzles are provided, and printing is performed on printing paper by ejecting black or color ink from each inkjet head. A circulation type ink jet printing apparatus that circulates the part to the ink jet head will be described as an example.

  FIG. 1 is a diagram illustrating an overview of an inkjet printing apparatus 100 according to a first embodiment of the present invention.

  As shown in FIG. 1, for example, a menu is displayed or an operation for requesting various operations such as printing is started based on a control unit 10 including a controller board on which a CPU or the like is arranged and a user operation. And an operation panel 50 for supplying signals to the control unit 10.

  In addition, the inkjet printing apparatus 100 serves as a paper feed mechanism that supplies printing paper, and includes a side paper feed tray 320 exposed outside the side surface of the housing and a plurality of paper feed trays (330a, 330b) provided inside the housing. , 330c, 330d).

  Then, the printing paper fed one by one from one of the side paper feed tray 320 and the paper feed tray 330 is fed by a feed mechanism such as a roller in a paper feed system conveyance path (black in the figure). (Bold line) and guided to the resist portion Rg. Here, the registration unit Rg is provided to perform alignment and skew correction of the leading edge of the printing paper, and includes a pair of registration rollers 350. The fed printing paper is temporarily stopped at the registration unit Rg and conveyed toward the printing mechanism at a predetermined timing.

  A plurality of inkjet heads 130 are provided further on the conveyance direction side of the resist portion Rg, and C (cyan), M (magenta), Y (yellow), and K (black) are arranged in order from the resist portion Rg. Arranged in order. The printing paper is printed line by line with ink ejected from each inkjet head 130 while being conveyed at a speed determined by printing conditions by an annular conveyance belt 360 provided on the opposite surface of the inkjet head 130.

  A suction fan 370 is provided inside the conveyor belt 360. A large number of air holes are formed on the surface of the conveyance belt 360, and the printing paper is adsorbed to the conveyance belt 360 and conveyed by the suction force generated by the rotation of the suction fan 370.

  The printed printing paper is further conveyed in the housing by a driving mechanism such as a roller. In the case of single-sided printing in which printing is performed only on one side of the printing paper, the paper is guided to the paper discharge port 340 and discharged as it is, and the print surface is lowered to a paper discharge tray 345 provided as a receiving tray for the paper discharge port 340. To be loaded. The paper discharge table 345 has a tray shape protruding from the casing, and has a certain thickness. The discharge tray 345 is inclined, and the printing paper that is discharged from the discharge outlet 340 and slides down along the inclination by the wall formed at a lower position of the inclination is naturally arranged and overlapped. ing.

  In the case of double-sided printing in which printing is performed on both sides of printing paper, the front side (the first printed side is “front side” and the next printed side is “back side”) is not guided to the paper discharge outlet 340 at the end of printing. In addition, it is transported in the housing. For this reason, the inkjet printing apparatus 100 includes a switching mechanism 380 for switching the conveyance path for backside printing. The printing paper that has not been led to the paper discharge port 340 by the switching mechanism 380 is drawn into the switchback path SR, and is switched back, so that the front and back are reversed with respect to the transport path. Then, it is guided again to the registration portion Rg by a driving mechanism such as a roller and temporarily stops. Thereafter, the sheet is conveyed in the direction of the printing mechanism at a predetermined timing, and the back side is printed by the same procedure as that for the front side. The printing paper on which the back side is printed and images are formed on both sides is guided to the paper discharge port 340 and discharged, and is stacked on a paper discharge table 345 provided as a receiving base for the paper discharge port 340. .

  Further, the ink jet printing apparatus 100 according to the first embodiment of the present invention employs a circulation system that circulates ink ejected from the ink jet head 130.

  FIG. 2 is a diagram illustrating the functional configuration of the ink circulation path-related mechanism and the control unit 10 of the inkjet printing apparatus 100 according to the first embodiment of the present invention.

  As shown in FIG. 2, the inkjet printing apparatus 100 includes inkjet heads 130C, 13M, 130Y, and 130K corresponding to C (cyan), M (magenta), Y (yellow), and K (black) inks. The printing paper is conveyed at a speed determined by printing conditions by an annular conveyance belt (not shown) provided on the opposite surface of the inkjet heads 130C, 13M, 130Y, and 130K, and the inkjet heads 130C, 13M, 130Y, and 130K. Is printed line by line with ink ejected from the printer.

  Each ink is supplied from a removable ink bottle. An ink bottle 110C that supplies cyan ink, an ink bottle 110M that supplies magenta ink, an ink bottle 110Y that supplies yellow ink, and a black ink bottle. An ink bottle 110K that supplies ink is provided. In the following description, the ink bottle 110 will be used as a representative when the ink color is not particular. The same applies to other functional units.

  The ink supplied from the ink bottle 110 passes through an ink circulation path formed by a pipe made of resin, metal, or the like, and is temporarily stored in a downstream tank provided on the downstream side of the inkjet head 130. Therefore, the inkjet printing apparatus 100 includes a downstream tank 122C that stores cyan ink, a downstream tank 122M that stores magenta ink, a downstream tank 122Y that stores yellow ink, and a downstream tank 122K that stores black ink. .

  The ink stored in the downstream tank 122 is sent to an upstream tank provided on the upstream side of the inkjet head 130 by a pump. For this reason, the inkjet printing apparatus 100 includes a pump 170C, a pump 170M, a pump 170Y, a pump 170K, an upstream tank 120C, an upstream tank 120M, an upstream tank 120Y, and an upstream tank 120K. The ink sent to the upstream tank 120 is sent to the ink jet head 130 provided with a number of nozzles for discharging ink.

  The ink that has not been ejected by the inkjet head 130 is returned to the downstream tank 122. Ink feedback from the upstream tank 120 to the downstream tank 122 via the inkjet head 130 uses the water head difference between the upstream tank 120 and the downstream tank 122.

  The temperature range in which the print quality is guaranteed is determined for the ink, and it is necessary to heat the ink when the environmental temperature is low and the ink temperature is below the lower limit temperature at which printing is possible. For this reason, a heater 140 is provided in the ink circulation path. On the other hand, the driver and the piezo element provided in the ink jet head 130 generate heat when operated. A cooler 160 that cools the ink when the ink temperature exceeds the upper limit temperature is provided in order to suppress the influence of an increase in the ink temperature at a high temperature due to the Joule heat of the heat generation and the ink vibration.

  In addition, for each inkjet head 130, the temperature of each ink flowing into each inkjet head 130 from each ink upstream tank 120 is measured, and the measured temperature of the ink is supplied to the control unit 10 at predetermined time intervals. A thermometer 134 (134C, 134M, 134Y, 134K) is provided.

  Further, for each ink jet head 130, the temperature of the ink flowing out from each ink jet head 130 to each downstream tank 122 is measured, and the measured ink temperature is supplied to the control unit 10 at a predetermined time interval. A thermometer 135 (135C, 135M, 135Y, 135K) is provided.

  The control unit 10 is a functional unit that controls a central process such as a printing process in the inkjet printing apparatus 100. Moreover, the control part 10 is provided with the determination part 11 and the apparatus control part 12 on the function. These configurations will be described later.

  FIG. 3A is a perspective view of the heater 140 provided in the inkjet printing apparatus 100 according to the first embodiment of the present invention, and FIG. 3B is an inkjet printing apparatus 100 according to the first embodiment of the present invention. It is sectional drawing of the heater 140 with which it was equipped.

  As shown in FIGS. 3A and 3B, the heater 140 includes a heat transfer section 145 having a hollow section through which each of C (cyan), M (magenta), Y (yellow), and K (black) ink flows. It has. The magnetic shunt alloy 141 is provided in contact with the heat transfer section 145 upstream of the ink flow, and the magnetic shunt alloy 143 is provided in contact with the heat transfer section 145 downstream of the ink flow. Yes. In addition, a heat insulating material 149 is provided between the magnetic shunt alloy 141 and the magnetic shunt alloy 143 in order to block heat transfer between the magnetic shunt alloy 141 and the magnetic shunt alloy 143.

  The magnetic shunt alloy 141 has a metal composition in which the quality assurance upper limit temperature is the Curie temperature (the temperature at which magnetism is lost). The upper limit temperature for quality assurance is an upper limit temperature at which the ink is not deteriorated, that is, the quality of the ink is guaranteed, and is 60 (° C.) here although it varies depending on the type of ink.

  A coil 142 is provided on the surface of the magnetic shunt alloy 141 facing the heat transfer section 145. When the coil 142 is energized, the coil 142 generates a magnetic field, and the magnetic shunt alloy 141 generates induction heat by the generated magnetic field. Then, the heat generated by the induction heat is transferred to the heat transfer unit 145, whereby the ink flowing in the heat transfer unit 145 is heated.

  The magnetic shunt alloy 143 has a metal composition such that the stable ejection temperature, which is the temperature at which the inkjet head can eject ink stably, becomes the Curie temperature. This stable discharge temperature is a temperature within a stable discharge temperature range (here, 25 (° C.) to 45 (° C.)) at which the ink has an appropriate viscosity, and varies depending on the type of ink, the shape of the nozzle, and the like. However, here, it is set to 35 (° C.) which is the median value of the stable discharge temperature region.

  Similar to the coil 142, a coil 144 is provided on the surface of the magnetic shunt alloy 143 that faces the heat transfer portion 145. When the coil 144 is energized, the coil 144 generates a magnetic field, and the magnetic shunt alloy 143 generates induction heat by the generated magnetic field. Then, the heat generated by the induction heat is transferred to the heat transfer unit 145, whereby the ink flowing in the heat transfer unit 145 is heated.

  FIG. 4 is a circuit configuration diagram of the heater 140 provided in the inkjet printing apparatus 100 according to the first embodiment of the present invention.

  As shown in FIG. 4, the heater 140 includes coils 142 and 144 and a drive unit 161 that applies voltages to the coils 142 and 144, respectively.

  The driving unit 161 is supplied with driving power from the power source 163, and the current value of the driving power supplied to the driving unit 161 is measured by an ammeter 162 arranged on the driving power supply path. Based on the current value measured by the ammeter 162, the circuit load, that is, the circuit impedance, is calculated and supplied to the determination unit 11 of the control unit 10 described later. The circuit impedance may be calculated directly by the ammeter 162 or may be calculated by the determination unit 11 described later.

  The control unit 10 includes a determination unit 11 and a device control unit 12.

  The determination unit 11 determines whether or not the magnetic shunt alloy 143 has exceeded the Curie temperature based on the driving load detected by the ammeter 162.

  When the determination unit 11 determines that the magnetic shunt alloy 143 has exceeded the Curie temperature, the device control unit 12 stops energization of the coil 142 and the coil 144.

  In addition, when the temperature detected by the thermometer 134 is equal to or lower than the first temperature that is lower than the stable discharge lower limit temperature, the device control unit 12 energizes the coil 144 and the coil 142, and the thermometer 134 When the detected temperature is lower than the stable discharge temperature and exceeds the first temperature, the coil 142 is energized.

  Furthermore, when the temperature detected by the thermometer 134 is higher than the lower limit value of the temperature range at which the inkjet head can stably eject ink and lower than the median value, the device control unit 12 determines that the magnetic shunt alloy 143 is curie. The ink is kept warm by energizing the coil 144 so as not to exceed the temperature.

  FIG. 5 is a diagram showing the magnetic permeability and circuit load of the magnetic shunt alloys 141 and 143 provided in the inkjet printing apparatus 100 according to the first embodiment of the present invention.

  As shown in FIG. 5, since the Curie temperature of the magnetic shunt alloy 141 is 60 (° C.), the magnetic permeability 201 of the magnetic shunt alloy 141 decreases to near 0 (H · m) near 60 (° C.). To do. Further, since the Curie temperature of the magnetic shunt alloy 143 is 35 (° C.), the magnetic permeability 202 of the magnetic shunt alloy 143 decreases to near 0 (H · m) in the vicinity of 35 (° C.).

  Therefore, when the temperature of the magnetic shunt alloys 141 and 143, that is, the temperature of the ink flowing through the heat transfer section 145 is less than 35 (° C.), the circuit load 203 becomes a predetermined value, but is 35 (° C.) or more. When the temperature is less than 60 (° C.), the magnetic permeability 202 of the magnetic shunt alloy 143 is lowered to near 0 (H · m), so that the circuit load 203 is also lowered accordingly.

  Further, when the temperature of the ink flowing through the heat transfer section 145 is 60 (° C.) or higher, the magnetic permeability 201 and 202 of the magnetic shunt alloys 141 and 143 are both lowered to near 0 (H · m). The circuit load 203 is also lowered to near 0 (Ω) accordingly.

  As described above, the magnetic shunt alloys 141 and 143 decrease in permeability to near 0 (H · m) at the respective Curie temperatures. Therefore, by measuring the circuit load 203, the temperature of the ink flowing through the heat transfer section 145 is measured. Is less than 35 (° C.), 35 (° C.) or more, less than 60 (° C.), or 60 (° C.) or more.

<Operation of Inkjet Printing Apparatus 100>
Next, the operation of the inkjet printing apparatus 100 according to the first embodiment of the present invention will be described.

  Details of the processing procedure in the inkjet printing apparatus 100 according to the first embodiment of the present invention will be described.

  FIG. 6 is a flowchart showing a processing procedure in the inkjet printing apparatus 100 according to the first embodiment of the present invention. The processing procedure shown in this flowchart is executed every predetermined time.

  As illustrated in FIG. 6, the determination unit 11 of the control unit 10 acquires the head temperature T (step S101). Specifically, the determination unit 11 uses any one of the temperatures measured by the thermometer 134 (134C, 134M, 134Y, 134K) or the thermometer 135 (135C, 135M, 135Y, 135K) as a head. Take as temperature T. However, the present invention is not limited to this, and an average value of each temperature measured by the thermometer 134 and the thermometer 135 may be calculated, and the calculated value may be collected as the head temperature T.

Next, the determination unit 11 determines whether or not the collected head temperature T has exceeded the stable discharge lower limit temperature _TL (step S103). Here, the stable discharge lower limit temperature _TL is a lower limit value in a range of a stable discharge temperature region (25 (° C.) to 45 (° C.)) in which the ink has an appropriate viscosity, and is 25 (° C.) here. .

When it is determined in step S103 that the head temperature T is equal to or lower than the stable discharge lower limit temperature _TL (in the case of NO), the determination unit 11 determines whether the head temperature T has _exceeded the first temperature _TLL. Determination is made (step S105). Here, the first temperature T _LL is a temperature that is sufficiently lower than the stable discharge lower limit temperature T _L , and is a temperature that needs to be warmed up rapidly in order to start printing as quickly as possible. (° C).

If it is determined in step S105 that the head temperature T is equal to or lower than the first temperature T _LL (in the case of NO), the device control unit 12 of the control unit 10 energizes the coils 142 and 144 (step S107). As a result, the coil 142 generates a magnetic field, and the magnetic shunt alloy 141 generates induction heat by the generated magnetic field, and the coil 144 generates a magnetic field. The magnetic shunt alloy 143 generates induction heat by the generated magnetic field. Then, the heat induced by the magnetic shunt alloy 141 and the magnetic shunt alloy 143 is transferred to the heat transfer section 145, and the ink flowing in the heat transfer section 145 is heated. Thus, when the head temperature T is equal to or lower than the first temperature T _LL , the ink temperature flowing through the heat transfer unit 145 is likely to be equal to or lower than the first temperature T _LL , so that the coils 142 and 144 are energized, By inductively generating heat in the magnetic shunt alloy 141 and the magnetic shunt alloy 143, the ink flowing through the heat transfer section 145 is rapidly heated.

In step S105, when it is determined that the head temperature T exceeds the first temperature _TLL (in the case of YES), the device control unit 12 of the control unit 10 energizes the coil 142 (step S109). As a result, the coil 142 generates a magnetic field, and the magnetic shunt alloy 141 generates induction heat by the generated magnetic field. Then, the heat induced by the magnetic shunt alloy 141 is transferred to the heat transfer unit 145, and the ink flowing in the heat transfer unit 145 is heated.

And the determination part 11 measures the temperature of the magnetic shunt alloy 143 (step S111). Specifically, the determination unit 11 energizes the coil 144 (that is, energizes both the coils 142 and 144) at a predetermined cycle (for example, every second), and measures by the ammeter 162 when energized. based on the current value, to calculate the circuit load Z _1. The determining unit 11 includes a circuit load Z ₁ that this calculation, when not allowed to energize the coil 144 (i.e., when is energized only in the coil 142) based on the current value measured by the ammeter 162 to calculate by comparing been a circuit load Z _2, measures the temperature of the magnetic shunt alloy 143.

Next, the determination unit 11 determines whether or not the temperature of the magnetic shunt alloy 143 has exceeded the Curie temperature 35 (° C.) (step S113). Specifically, the determination unit 11, when the difference between the circuit load _{Z 1} and circuit load _{Z 2} calculated in step S111 is close to 0, the magnetic permeability of the magnetic shunt alloy 143, 0 (H · m) near Therefore, it is determined that the temperature of the magnetic shunt alloy 143 has exceeded the Curie temperature 35 (° C.).

  If it is determined in step S113 that the temperature of the magnetic shunt alloy 143 has exceeded the Curie temperature 35 (° C.) (in the case of YES), the device control unit 12 of the control unit 10 stops energization of the coil 142 (step S115). ).

Thus, when the head temperature T exceeds the first temperature T _LL , there is a high possibility that the ink temperature flowing through the heat transfer unit 145 also exceeds the first temperature T _LL . By temporarily energizing the coil 144, the temperature of the magnetic shunt alloy 143 (that is, the temperature of the ink flowing through the heat transfer section 145) is measured, and until the temperature of the magnetic shunt alloy 143 reaches the Curie temperature 35 (° C.), By causing the magnetic shunt alloy 141 to generate heat by induction, the ink flowing through the heat transfer section 145 can be heated.

On the other hand, in step S103, (the case of YES) head temperature T is, when it is determined that exceeds the stable discharge lower limit temperature T _L, the determination unit 11, whether or not the head temperature T is beyond the stable discharge center temperature T _M Is determined (step S121). Here, the stable discharge center temperature T _M, a median of a range of stable discharge temperature region where the ink is proper viscosity (25 (℃) ~45 (℃ )), for example, is 35 (° C.).

In step S121, the head temperature T is, when it is determined that exceeds the stable discharge center temperature _{T M} (the case of YES), the device control unit 12 of the control unit 10 stops the energization of the coil 142, 144 (step S123 ).

Thus, the head temperature T is, if it exceeds the stable discharge center temperature T _M, there is a high possibility that the ink temperature flowing through the heat transfer portion 145 also exceeds the stable discharge center temperature T _M, the coils 142, 144 Stop energizing.

On the other hand, in step S121, the head temperature T is, when it is determined that less stable discharge center temperature _{T M} (the case of NO), the determination unit 11 measures the temperature of the magnetic shunt alloy 143 (step S125). Specifically, as in the processing in step S111, the determination unit 11 temporarily energizes the coil 144 (that is, energizes only the coil 144), and measures by the ammeter 162 when energized. based on the current value, to calculate the circuit load Z _3. The determining unit 11 includes a circuit load Z ₃ that this calculation, when not allowed to energize the coil 144 (i.e., if not also is energized in any coil 142, 144) the measured current value by the ammeter 162 comparing the circuit load Z ₄ calculated on the basis of the result, to measure the temperature of the magnetic shunt alloy 143.

Next, the determination unit 11 determines whether or not the temperature of the magnetic shunt alloy 143 exceeds the Curie temperature 35 (° C.) (step S127). Specifically, the determination unit 11, when the difference between the circuit load _{Z 1} and circuit load _{Z 2} calculated in step S125 is close to 0, the magnetic permeability of the magnetic shunt alloy 143, 0 (H · m) near Therefore, it is determined that the temperature of the magnetic shunt alloy 143 has exceeded the Curie temperature 35 (° C.).

  In step S127, when it is determined that the temperature of the magnetic shunt alloy 143 exceeds the Curie temperature 35 (° C.) (in the case of YES), the device control unit 12 of the control unit 10 energizes the coil 144 (step S129).

Thus, the head temperature T is, if less than stable discharge center temperature T _M, there is a high possibility that the ink temperature flowing through the heat transfer section 145 is also less than stable discharge center temperature T _M, temporarily energizing the coil 144 By measuring the temperature, the temperature of the magnetic shunt alloy 143 (that is, the temperature of the ink flowing through the heat transfer section 145) is measured, and the magnetic shunt alloy 143 is induced so that the temperature of the magnetic shunt alloy 143 becomes the Curie temperature 35 (° C.). By generating heat, the ink flowing through the heat transfer unit 145 can be kept warm.

  FIG. 7 is a diagram illustrating the relationship between the ink temperature and the coil control in the inkjet printing apparatus 100 according to the first embodiment of the present invention.

As shown in the area A in FIG. 7, when the head temperature T is equal to or lower than the first temperature T _LL , the device control unit 12 of the control unit 10 energizes the coils 142 and 144.

As shown in region B of FIG. 7, when the head temperature T exceeds the first temperature T _LL and is equal to or lower than the stable discharge lower limit temperature _TL , the coil 142 is energized and the coil 144 is energized temporarily. By measuring the temperature of the magnetic shunt alloy 143 (that is, the temperature of the ink flowing through the heat transfer section 145), the magnetic shunt alloy 141 is inductively heated until the temperature of the magnetic shunt alloy 143 reaches the Curie temperature 35 (° C.). The ink flowing through the heat transfer unit 145 is heated.

As shown in the area C of FIG. 7, the head temperature T is beyond the stable discharge lower limit temperature T _L, if it is stable discharge center temperature T _M or less, by temporarily energizing the coil 144, the magnetic shunt alloy 143 The temperature (that is, the temperature of the ink flowing through the heat transfer unit 145) is measured, and the magnetic shunt alloy 143 is inductively heated so that the temperature of the magnetic shunt alloy 143 becomes the Curie temperature 35 (° C.), thereby the heat transfer unit 145. Keep the ink flowing through.

As shown in the D region of FIG. 7, when the head temperature T has exceeded the stable discharge center temperature T _M, to stop the energization of the coil 142, 144.

  As described above, according to the ink jet printing apparatus 100 according to the first embodiment of the present invention, the coil 144 that generates a magnetic field when energized and the magnetic shunt alloy 143 having a stable ejection temperature as a Curie temperature are provided. Since the magnetic shunt alloy 143 is inductively heated by the magnetic field generated by the coil 144 to heat the ink, a new thermometer is installed, and the ink jet head can be directly measured without directly measuring the temperature of the heated portion. The temperature can be controlled to an appropriate value so that the ink can be ejected from 130 and the ink is not deteriorated.

  In Example 1 of the present invention, the surface of the magnetic shunt alloy 141 facing the heat transfer portion 145 is provided with the coil 142, and the surface of the magnetic shunt alloy 143 facing the heat transfer portion 145 is provided with the coil 144. However, the present invention is not limited to this, and the heat transfer section 145 itself may be formed of a magnetic shunt alloy.

  For example, the upstream heat transfer portion 145 and the magnetic shunt alloy 141 are integrally formed, the downstream heat transfer portion 145 and the magnetic shunt alloy 143 are integrally formed, and the coils 142 and 144 are provided respectively. Also good.

  In the first embodiment of the present invention, the ink supplied from the ink bottle 110 to the inkjet head 130 is ejected toward the printing paper to print images, characters, and the like, and the ejected ink is applied to the ink bottle 110. The circulation type inkjet printing apparatus 100 that circulates has been described as an example. However, the present invention is not limited to the circulation type inkjet printing apparatus 100 but can be applied to all inkjet printing apparatuses.

  In the first embodiment of the present invention, the inkjet is provided with the coil 142 on the surface facing the heat transfer portion 145 of the magnetic shunt alloy 141 and the coil 144 on the surface facing the heat transfer portion 145 of the magnetic shunt alloy 143. The printing apparatus 100 has been described as an example.

  In the second embodiment of the present invention, an ink jet printing apparatus 100A provided with a coil arranged so as to wind around the magnetic shunt alloys 141 and 143 and the heat transfer section 145 will be described as an example.

  FIG. 8 is a perspective view of a heater 140A provided in the ink jet printing apparatus 100A according to the second embodiment of the present invention.

  As shown in FIG. 8, similarly to the heater 140, the heater 140 </ b> A provided in the ink jet printing apparatus 100 </ b> A is a hollow through which inks of C (cyan), M (magenta), Y (yellow), and K (black) flow. The heat transfer part 145 which has a part is provided. Further, a magnetic shunt alloy 141 having a Curie temperature of 60 (° C.) is provided on the upstream side of the ink flow so as to come into contact with the heat transfer unit 145, and the heat transfer unit 145 is contacted on the downstream side of the ink flow. A magnetic shunt alloy 143 having a Curie temperature of 35 (° C.) is provided.

  Further, a coil 146 is arranged so as to wind around the magnetic shunt alloys 141 and 143 and the heat transfer section 145.

The ink jet printing apparatus 100A, the head temperature T is beyond the stable discharge lower limit temperature T _L, is equal to or less than stable discharge center temperature T _M, if energizing the coil 146, beyond the stable discharge center temperature T _M, the coil The energization to 146 is stopped.

Thus, when there is a difference between the ink temperature flowing through the head temperature T and the heat transfer section 145 also when the ink temperature flowing through the heat transfer unit 145 exceeds a stable discharge center temperature T _M, the magnetic shunt alloy 143 The heating by can be stopped.

  In the first embodiment of the present invention, the inkjet is provided with the coil 142 on the surface facing the heat transfer portion 145 of the magnetic shunt alloy 141 and the coil 144 on the surface facing the heat transfer portion 145 of the magnetic shunt alloy 143. The printing apparatus 100 has been described as an example.

  In the third embodiment of the present invention, an ink jet printing apparatus 100B provided with a magnetic shunt alloy and a coil for each ink color will be described as an example.

  FIG. 9 is a perspective view of the heater 140B provided in the inkjet printing apparatus 100B according to the third embodiment of the present invention.

  As shown in FIG. 9, the heater 140B provided in the ink jet printing apparatus 100B has a hollow cylindrical shape in which ink flows for each of C (cyan), M (magenta), Y (yellow), and K (black). A magnetic shunt alloy 147 having a Curie temperature of 60 (° C.) and a magnetic shunt alloy 148 having a Curie temperature of 35 (° C.) are provided.

  The coils 149 and 151 are arranged to wrap around the magnetic shunt alloys 147 and 148 for each of C (cyan), M (magenta), Y (yellow), and K (black).

  And the inkjet printing apparatus 100B performs the process shown in FIG. 6 similarly to the inkjet printing apparatus 100 which concerns on Example 1 of this invention for every color.

  As described above, according to the ink jet printing apparatus 100B according to the third embodiment of the present invention, the temperature of the ink flowing through the heat transfer section can be controlled for each color, so that it can be controlled to an appropriate temperature with higher accuracy.

  In addition, although it was set as the structure provided with the hollow cylindrical shape magnetic shunt alloy 147,148 of the heater 140B with which the inkjet printing apparatus 100B which concerns on Example 3 of this invention was provided, not only a hollow cylindrical shape but a bellows shape or a spiral shape The magnetic shunt alloy may be provided. As described above, when the shape of the magnetic shunt alloy is molded so as to have a surface area larger than that of the hollow cylindrical shape, heat transfer becomes easier.

  In the third embodiment of the present invention, the ink jet printing apparatus 100B including the hollow cylindrical magnetic shunt alloy and the coil wound around the perforated ink for each ink color has been described as an example.

  In the fourth embodiment of the present invention, a description will be given by taking as an example an ink jet printing apparatus 100C in which a coil is arranged on a surface facing a heat transfer portion of a flat magnetic shunt alloy and a magnetic shunt alloy for each ink color.

  FIG. 10 is a perspective view of a heater 140C provided in the ink jet printing apparatus 100C according to the fourth embodiment of the present invention.

  As shown in FIG. 10, the heater 140C provided in the inkjet printing apparatus 100B is a flat plate type transmission in which ink flows for each of C (cyan), M (magenta), Y (yellow), and K (black). A magnetic shunt alloy 155 having a Curie temperature of 60 (° C.) in contact with the heat transfer unit 153 is provided on the upstream side of the ink flow and the heat transfer unit 153 on the downstream side of the ink flow. A magnetic shunt alloy 156 having a Curie temperature of 35 (° C.) is provided.

  In addition, a heat insulating material 149 is provided between the magnetic shunt alloy 155 and the magnetic shunt alloy 156 in order to block heat transfer between the magnetic shunt alloy 155 and the magnetic shunt alloy 156.

  A coil 157 is provided on the surface of the magnetic shunt alloy 155 facing the heat transfer portion 153, and a coil 159 is provided on the surface of the magnetic shunt alloy 156 facing the heat transfer portion 153.

  As described above, according to the ink jet printing apparatus 100C according to the fourth embodiment of the present invention, the temperature of the ink flowing through the heat transfer section can be controlled for each color, so that it can be controlled to an appropriate temperature with higher accuracy.

DESCRIPTION OF SYMBOLS 10 ... Control part 11 ... Determination part 12 ... Equipment control part 50 ... Operation panel 100,100A, 100B, 100C ... Inkjet printing apparatus 110 ... Ink bottle 120 ... Upstream tank 122 ... Downstream tank 130 ... Inkjet head 134 ... Thermometer 135 ... Thermometers 140, 140A, 140B, 140C ... heaters 143, 148, 156, 141, 147, 155 ... magnetic shunt alloys 144, 146, 151, 159 ... coils (first coil)
142, 149, 157 ... Coil (second coil)
145, 153 ... Heat transfer part 149 ... Heat insulation material 160 ... Cooler 161 ... Drive part 162 ... Ammeter 163 ... Power supply

Claims (5)

An inkjet head that ejects ink onto a print medium;
A first coil that generates a magnetic field when energized;
A first magnetic shunt alloy having a Curie temperature as a stable ejection temperature at which the inkjet head can stably eject ink;
A second coil that generates a magnetic field when energized;
A second magnetic shunt alloy having a Curie temperature as a quality assurance upper limit temperature, which is an upper limit temperature at which ink quality is guaranteed,
The first magnetic shunt alloy heats by induction heat generated by the magnetic field generated by the first coil, and the second magnetic shunt alloy is induced by the magnetic field generated by the second coil. An ink jet printing apparatus that heats ink by generating heat. Load detecting means for detecting a driving load of the first coil;
Determining means for determining whether or not the first magnetic shunt alloy exceeds the Curie temperature based on the driving load detected by the load detecting means;
Control means for stopping energization of the first coil when the determination means determines that the first magnetic shunt alloy has exceeded the Curie temperature;
The inkjet printing apparatus according to claim 1, further comprising: Load detecting means for detecting a driving load of the first coil;
Determining means for determining whether or not the first magnetic shunt alloy exceeds the Curie temperature based on the driving load detected by the load detecting means;
Control means for stopping energization of the second coil when the determination means determines that the first magnetic shunt alloy has exceeded the Curie temperature;
The inkjet printing apparatus according to claim 1, further comprising: Temperature detecting means for detecting the temperature of the ink, and
The control means includes
When the temperature detected by the temperature detection means is equal to or lower than the first temperature that is lower than the stable discharge temperature, the first coil and the second coil are energized, and the temperature detection means 4. The ink jet printing apparatus according to claim 2, wherein when the detected temperature is lower than the stable discharge temperature and exceeds the first temperature, only the second coil is energized. 5. . Temperature detecting means for detecting the temperature of the ink, and
The control means includes
When the temperature detected by the temperature detection means is higher than the lower limit value of the temperature range at which the inkjet head can stably discharge the ink and lower than the median value of the temperature range in which stable discharge is possible, the first The inkjet printing apparatus according to claim 2 or 3, wherein the first coil is energized so that the magnetic shunt alloy does not exceed the Curie temperature.

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