JP2006253511A - Mounting structure of noise filter device, recording device having the mounting structure and liquid injection equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide the mounting structure of a noise filter device capable of reducing noise generated in a signal passing through a signal cable by the rocking of the noise filter device, a recording device having the structure and liquid injection equipment. <P>SOLUTION: The mounting structure of a ferrite core 15 has a main control substrate 14 with a formed control circuit; and the signal cable 12 movably disposed between the main control substrate 14 and a carriage motor so that one end side is connected to the control circuit on the main control substrate 14 through a connector 13 and the other end side is connected to the carriage motor. The mounting structure of the ferrite core 15 further has the ferrite core 15 mounted on one end side of the signal cable 12. In the mounting structure of the ferrite core 15, a substrate opening 18 is formed at a place near the connector 13 for the main control substrate 14, and the ferrite core 15 is fixed by a fixing band 16 for inserted into the substrate opening 18. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

The present invention relates to a mounting structure that prevents a noise filter device from swinging and reduces noise generated by the swinging , and a recording apparatus and a liquid ejecting apparatus including the mounting structure.

  2. Description of the Related Art Conventionally, each device such as a circuit board constituting a recording apparatus such as a printer and a motor controlled by the circuit board is connected by a signal cable. In the signal cable, radiation noise is generated by electromagnetic waves radiated from other devices. In addition, noise generated in other devices is conducted through other circuit boards and cables and enters the signal cable. Therefore, in order to reduce radiation noise and conduction noise, a noise filter device is attached to the signal cable. The mounting structure varies depending on the type of noise filter device to be employed. Even if the same noise filter device is adopted, it differs depending on the use situation. Therefore, many mounting structures for the noise filter device have been proposed. For example, there is a simple structure in which the signal cable is inserted into a central hole of a ferrite core that is a noise filter device (see Patent Document 1).

  However, the simple structure in which the signal cable is inserted into the central hole of the ferrite core has a low inductance component of the signal cable, and the effect of reducing noise cannot be sufficiently expected. Therefore, as shown in FIG. 7, in order to improve the noise reduction effect, there is a structure in which the signal cable (ground wire 7) is inserted into the center hole of the ferrite core 5 and wound several times. Here, FIG. 7 is a front view showing a structure in which the conventional ferrite core 5 is wound around the ground wire 7 several times. In FIG. 7, an inlet 1 for an external cable for supplying commercial frequency power is mounted on a power supply board 9 of a recording apparatus such as a printer. The inlet 1 includes a ground terminal 2 and a lead terminal 3. A ground wire 7 is connected to the ground terminal 2, and a crimp terminal 8 is provided at the tip of the ground wire 7. The ground line 7 conducts an external cable and emits noise that enters the recording apparatus such as a printer to the ground. The ground wire 7 is also provided with a ferrite core 5 in order to reduce noise. The ground wire 7 is wound around the ferrite core 5 several times.

  Further, as shown in FIG. 8, a structure is adopted in which a ferrite core 5 is attached between the inlet 1 and the tip 2 a of the ground terminal 2 so as to cover the outer peripheral surface of the ground terminal 2. FIG. 8 is a front view showing a structure in which a conventional ferrite core 5 is attached between the inlet 1 and the tip 2 a of the ground terminal 2. The ground terminal 2 of the inlet 1 is inserted into the center hole of the ferrite core 5 and brought into contact with the inlet 1, and then the tip 2a of the ground terminal 2 is pressed to increase the shape. Therefore, the ferrite core 5 is in contact with the inlet 1 at the right end surface in the drawing, and is in contact with the tip 2a of the ground terminal 2 at the left end surface in the drawing. Thereby, the ferrite core 5 is supported by the front-end | tip part 2a of the ground terminal 2, and omission is prevented.

Furthermore, as shown in FIG. 9, a structure in which ferrite cores 5A and 5B are attached inside the inlet 1 is also employed. FIG. 9 is a cross-sectional view showing a structure in which a conventional ferrite core 5 is provided inside the inlet 1. In FIG. 9, ferrite cores 5A and 5B are attached to the ground terminal portion 2i and the lead terminal portion 3i inside the inlet 1, respectively. The ferrite cores 5A and 5B are attached so as to cover the outer peripheral surfaces of the terminal portions 2i and 3i, respectively. (See Patent Document 2.)
JP 09-190855 A Japanese Utility Model Publication No. 6-63335

  In the ferrite core mounting structure shown in Patent Document 1 described above, a signal cable that transmits a signal from a circuit board to each device such as a motor controlled by the circuit board is inserted through a hole in the center of the ferrite core, and To the connector on the circuit board and the terminals of each of the above devices. However, the control cable is not fixed except for the connector on the circuit board and the terminal of each device. Moreover, the ferrite core was not fixed to any. For this reason, the ferrite core and the signal cable sometimes oscillate due to vibration generated by movement of the carriage or rotation / stop of the motor. When the ferrite core and the signal cable are swung, there is a problem that noise is generated in a control signal passing through the signal cable by approaching or moving away from an IC or a motor that radiates electromagnetic waves. Originally, even if the ferrite core and the signal cable do not oscillate, if the electromagnetic waves radiated from the IC inside the recording device such as a printer or the motor fluctuate, noise is generated in the control signal passing through the signal cable. Was. However, noise is generated due to the rocking of the ferrite core and the signal cable, so that the noise and the noise generated by the fluctuation of the radiated electromagnetic wave are superimposed, and the magnitude of the noise generated in the control signal is reduced. There was also a problem that it was not stable. Further, according to the standard, a maximum allowable value is defined for the magnitude of electromagnetic waves radiated from the entire recording apparatus such as a printer. Therefore, the electromagnetic wave is measured and it is determined whether or not it is below the allowable value. However, if the magnitude of noise generated in the control signal is not stable, the magnitude of electromagnetic waves radiated from the entire recording device such as a printer is not stable, and it cannot be denied that the measured value may not be less than the maximum allowable value. There was a problem.

In addition, with the redundancy of signal cables, the problem that the ferrite core and signal cables swing significantly due to vibrations caused by carriage movement or motor rotation / stopping, etc., appears in other devices. There was a problem that the possibility of a collision could not be denied. There is also a problem that the possibility of damaging the ferrite core cannot be denied because it collides with another device. On the other hand, measures such as covering the ferrite core with an impact absorbing material have been adopted. However, even if this measure is adopted, the possibility that the ferrite core is damaged cannot be completely denied.
Further, in the attachment structure of the ferrite core 5 shown in FIG. 7, the ground wire 7 is wound around the ferrite core 5 several times, and the ground wire 7 is connected only to the inlet 1 and a casing (not shown). Moreover, the ferrite core 5 was not fixed to any. Therefore, there was a problem similar to the ferrite core mounting structure shown in Patent Document 1 described above.

Further, in the structure for attaching the ferrite core 5 shown in FIG. 8, the ferrite core 5 is attached so as to cover the outer peripheral portion of the ground wire 7 between the inlet 1 for the external cable and the tip 2a of the ground terminal 2. It was. The right end surface of the ferrite core 5 in the drawing is in contact with the inlet 1, and the left end surface in the drawing is in contact with the tip 2a of the ground terminal 2, so that the ferrite core 5 is supported by the tip 2a of the ground terminal 2, Dropping was prevented. However, even in this structure, there is room for the ferrite core 5 to swing back and forth or up and down in the drawing, and there is a problem similar to the ferrite core mounting structure shown in Patent Document 1 described above. Further, when the ferrite core 5 is attached to the inlet 1, there is a problem that workability is poor because the tip 2a of the ground terminal 2 needs to be pressed. Further, in FIG. 8, since the ground wire 2 is only inserted through the central hole of the ferrite core 5, the ferrite core 5 mounting structure shown in FIG. In comparison, there was a problem that the noise reduction effect deteriorated.

  Further, in the structure for attaching the ferrite core 5 shown in FIG. 9, the ferrite core 5A is attached to the ground terminal portion 2i inside the inlet 1 so as to cover the outer peripheral portion of the ground terminal portion 2i. Therefore, there is a problem that the structure of the inlet 1 is complicated. Further, since the ground wire 7 is only inserted through the central hole of the ferrite core 5A, the noise is compared with the mounting structure of the ferrite core 5 shown in FIG. 7 in which the ground wire 7 is wound around the ferrite core 5 several times. There has been a problem that the effect of reducing the reduction of the quality is deteriorated.

Therefore, the present invention has been made in view of the various problems as described above, and its purpose is to make the connector for connecting the signal cable a complicated structure without deteriorating the noise reduction effect. In addition, the noise filter device and the signal cable wound around the noise filter device are prevented from oscillating without deteriorating the workability of the work of attaching the noise filter device, and the signal cable is passed by the above oscillating . To reduce the noise generated in the control signal, stabilize the magnitude of the noise generated in the control signal, and reliably reduce the magnitude of the electromagnetic wave radiated from the entire recording apparatus to an allowable value or less. The object is to provide a mounting structure of a possible noise filter device.

  Another object of the present invention is to reduce noise without deteriorating the noise reduction effect, without complicating the connector for connecting the signal cable, and without deteriorating the workability of attaching the noise filter device. An object of the present invention is to provide a noise filter device mounting structure that prevents the filter device and the signal cable from swinging and prevents the noise filter device from colliding with other devices.

  In order to achieve the above object, in the noise filter device mounting structure of the present invention, one end side is connected to the substrate on which the first signal processing circuit is formed and the first signal processing circuit on the substrate via the connector. A signal cable movably disposed between the substrate and the second signal processing circuit so that the other end side is connected to the second signal processing circuit, and attached to the one end side of the signal cable. In a noise filter device mounting structure including a noise filter device, a hole is provided in the vicinity of the connector of the substrate, and the noise filter device is fixed by a bundling member through which the hole is inserted.

Accordingly, the noise filter device attached to the signal cable is fixed in the vicinity of the substrate, so that the noise reduction effect is not deteriorated, the connector for connecting the signal cable is not complicated, and the noise filter device. It is possible to prevent the noise filter device and the signal cable from swinging without deteriorating the workability of the work of attaching the cable. That is, the noise generated in the signal passing through the signal cable can be reduced by the above swinging . From this, it becomes possible to stabilize the magnitude of noise generated in the signal passing through the signal cable. Further, since the magnitude of the noise is stabilized, the magnitude of the electromagnetic wave radiated from the entire recording apparatus is also stabilized. Therefore, the magnitude of the electromagnetic wave can be surely set to the maximum allowable value or less. Furthermore, it is possible to completely prevent the noise filter device from colliding with other devices. Therefore, it is not necessary to cover the noise filter device with the shock absorbing material, and the shock absorbing material can be eliminated.

  The noise filter device mounting structure of the present invention is characterized in that the noise filter device is constituted by a ring-shaped ferrite core. Thereby, the ring-shaped ferrite core which is a noise filter apparatus can be easily fixed with the binding member inserted in the hole formed in the board | substrate.

  In addition, the recording apparatus of the present invention is characterized by including the above-described noise filter device mounting structure. Thereby, the recording apparatus provided with the attachment structure of said noise filter apparatus can be provided.

  The liquid ejecting apparatus of the present invention is characterized by including the above-described noise filter device mounting structure. Thereby, the liquid ejecting apparatus provided with the mounting structure of the noise filter device can be provided.

  One embodiment of the present invention will be described with reference to the drawings. The embodiments described below do not limit the invention according to the claims, and all the combinations of features described in the embodiments are not necessarily essential to the solution means of the invention. Absent.

  FIG. 1 is a perspective view showing the overall appearance of an ink jet type multifunction peripheral 100 which is one of recording apparatuses according to an embodiment of the present invention. The ink jet type multifunction peripheral 100 has a printer function capable of recording on, for example, a JIS standard L size, A6 size to A4 size cut sheet or postcard, a JIS standard size A4 size original, Equipped with a scanner function that can read originals up to US standard letter size, and a copy function that can copy to JIS standard L size, 2L size, B5 size, A4 size, six cuts, postcard size paper ing.

  The ink jet type multifunction peripheral 100 is entirely covered with a substantially rectangular parallelepiped housing 101, and has a configuration in which a printer 110 is disposed in a lower stage and a scanner 120 is disposed in an upper stage. A user can open the inside of the printer 110 by lifting the heavy scanner 120, and when a problem such as a paper jam occurs inside the printer, a structure that can easily solve the problem as in the past. It has become. A paper feeding unit 130 is disposed on the back side of the printer 110 of the inkjet multifunction peripheral 100, and a paper feeding / discharging unit 140 is disposed on the front side. As a paper setting direction before recording, one or both of the rear-side paper feeding unit 130 and the front-side paper feeding / discharging unit 140 can be selected. Furthermore, since the paper after recording is always discharged from the paper supply / discharge section 140 on the front side, the user can easily take out the paper.

  A rectangular flat plate-like scanner cover 102 is disposed on the upper surface of the housing 101. The scanner cover 102 has a handle 103 at the front, and is attached so as to be rotatable in the direction of the arrow a in the figure around a rotation axis at the rear. When using the scanner 120, the user inserts a finger into the handle 103, opens and closes the scanner cover 102, places the document on a scanner table (not shown), and scans the document.

  In front of the scanner cover 102 on the upper surface of the housing 101, an operation unit 106 for instructing each operation of the printer 110, the scanner 120, and the copy is disposed. The operation unit 106 includes buttons and the like without reference numerals, a liquid crystal panel 107, and the like. The buttons and the like are buttons such as a power system for turning on / off the power, an operation system for operating a cueing of a paper sheet or operating ink flushing, a processing system for performing image processing, and the like. In addition, the liquid crystal panel 107 and the like are arranged to display the state of the inkjet multifunction peripheral 100. The user can operate buttons and the like while looking at the liquid crystal panel 107 for confirmation.

  FIG. 2 is a perspective view showing the internal structure of the printer 110 of the inkjet type multifunction peripheral 100 shown in FIG. On both sides of the front surface of the printer 110, cartridge storage portions 104 into which a plurality of ink cartridges 10 are inserted and removed are formed. Each ink cartridge 10 stores ink of each color for recording. Further, inside the printer 110, a paper feed unit 130, a paper feed / discharge unit 140, a recording unit 150, and the like are arranged.

  The recording unit 150 includes a roller (not shown) that feeds paper in the sub-scanning direction in synchronization with the recording operation, a driven roller (not shown), a carriage 153 that moves in the main scanning direction in synchronization with the recording operation, and a recording operation. A recording head (not shown) that ejects ink, a platen (not shown) that holds the paper during recording flat, and the like are configured. The carriage 153 is connected to the carriage belt 158 above a platen (not shown). The carriage belt 158 is operated by the rotation of the carriage motor 159. Therefore, when the carriage belt 158 is operated by the rotation of the carriage motor 159, the carriage 153 is reciprocated along with the movement of the carriage belt 158.

  Here, the carriage motor 159 of the present embodiment is disposed in the vicinity of the paper feeding unit 130 on the back side of the printer 110 of the inkjet multifunction peripheral 100. The carriage motor 159 is a pulse motor, and executes rotation / stop in response to a signal transmitted from the main control board 14 (see FIG. 4). As will be described later, the carriage motor 159 and the main control board 14 are connected by a signal cable 12 (see FIG. 4). A noise filter device (not shown) is attached near the carriage motor 159 of the signal cable 12 of this embodiment. Also, a ferrite core 15 (see FIG. 4), which is a kind of noise filter device, is attached to the vicinity of the main control board 14 of the signal cable 12.

  FIG. 3 is a perspective view showing the positional relationship between the operation unit 106 and the main control board unit 17 shown in FIG. A main control board unit 17 is disposed below the operation unit 106 as shown in FIG. An operation board (not shown) is disposed on the back side of the operation unit 106, and the operation board (not shown) is electrically connected to the main control board unit 17 through the ground member 20. That is, the main control board unit 17 of the present embodiment is disposed obliquely below the operation unit 106 on the front side of the inkjet multifunction peripheral 100. As shown in FIGS. 2 and 3, the carriage motor 159 and the main control board unit 17 are arranged at positions far away from each other. Along with this, the signal cable 12 (see FIG. 4) connecting the main control board 14 (see FIG. 4) forming the main control board unit 17 and the carriage motor 159 becomes longer. Therefore, as the signal cable 12 becomes redundant, the ferrite core 15 (see FIG. 4) and the signal cable 12 are swung due to vibration generated by the movement of the carriage 153 or the rotation / stop of the carriage motor 159. Appears prominently. Therefore, the ferrite coil 15 and the signal cable 12 are prevented from swinging by adopting a mounting structure of the ferrite coil 15 which is a characteristic part of the present invention described later.

  FIG. 4 is a perspective view of the main control board unit 17 shown in FIG. 3 as viewed from above in a state where the mounting structure of the ferrite core 15 which is a characteristic part of the present invention is applied. The main control board unit 17 is composed of a main control board 14, a shield plate 11, and a bottom frame without reference numerals. The shield plate 11 does not radiate electromagnetic waves generated from the electronic components mounted on the main control board 14 to other devices, or prevents the main control board 14 from being affected by the electromagnetic waves radiated from other devices. Further, the main control board 14 is covered. The shield plate 11 is electrically connected to a grounding terminal (not shown) of the ink jet type multifunction peripheral 100, and the electromagnetic wave generated from the electronic component mounted on the main control board 14 and the electromagnetic wave radiated from another device are The ink is discharged from the grounding terminal to the outside of the inkjet multifunction peripheral 100 through a grounding wire.

  On the main control board 14, electronic components such as an IC (not shown), a coil (not shown), and a capacitor (not shown) are mounted. A control circuit 19 for controlling the ink jet type multifunction peripheral 100 is formed by the electronic components described above. A control circuit 19 on the main control board 14 transmits a signal to each device such as a motor. In this embodiment, a signal is transmitted from the control circuit 19 to the carriage motor 159. The control circuit 19 is connected to the carriage motor 159 via the connector 13 via the signal cable 12. The shield plate 11 is formed in a shape that does not cover the periphery of the connector 13 of the main control board 14 so as not to interfere with the signal cable 12 connected to the connector 13.

  Here, electromagnetic waves radiated from other devices generate noise in signals passing through the signal cable 12 connected to the connector 13. This noise enters the main control board 14 from the signal cable 12 through the connector 13. Therefore, the signal cable 12 is wound and connected to a ferrite core 15 that is a noise filter device provided around the connector 13 of the main control board 14. By winding the ferrite core 15 around the signal cable 12 several times, the inductance component of the signal cable 12 is increased. Since the carriage motor 159 to which the signal cable 12 is connected is a pulse motor as described above, the signal transmitted to the carriage motor 159 through the signal cable 12 forms a pulse-like waveform. The inductance component passes through the pulse waveform signal without being attenuated. On the other hand, the inductance component attenuates the high frequency component of the signal, that is, noise. Thereby, the noise which generate | occur | produces in the signal which passes the signal cable 12 can be reduced. Further, the ferrite core 15 is fixed at a position other than the connector 13 and the carriage motor 159 on the main control board 14.

  FIG. 5 is a detailed plan view of the main control board 14 before mounting electronic components constituting the main control board unit 17 shown in FIG. A four-layer board is used for the main control board 14 shown in FIG. In each layer of the main control board 14, a wiring pattern, a ground pattern, and a power supply pattern are formed depending on each application. After the various patterns are formed, the main control board 14 is insulated by applying a resist 26 except for necessary portions. Here, the necessary portions of the various patterns indicate portions to which electronic components are attached and soldered.

  In FIG. 5, various wiring patterns formed for mounting a plurality of types of electronic components are shown on the surface layer of the four-layer structure of the main control board 14. For example, a BGA package wiring pattern 21, a connector wiring pattern 22, a capacitor wiring pattern 23, a coil wiring pattern 24, and a QFP package wiring pattern 25 are formed. Therefore, a BGA package (not shown) is mounted on the BGA package wiring pattern 21, and the connector 13 is mounted on the connector wiring pattern 22. A capacitor (not shown) is mounted on the capacitor wiring pattern 23, a coil (not shown) is mounted on the coil wiring pattern 24, and a QFP package (not shown) is mounted on the QFP package wiring pattern 25.

  Here, the BGA package and the QFP package (not shown) are ICs, and constitute a control circuit 19 that controls the operation of the inkjet multifunction peripheral 100. A coil and a capacitor (not shown) constitute a part of a power supply circuit that supplies a predetermined voltage in the inkjet multifunction peripheral 100. The connector 13 on the main control board 14 is connected to the signal cable 12. The signal cable 12 is also connected to the terminal of the carriage motor 159 described above. Accordingly, the control circuit 19 transmits a signal to the carriage motor 159 through the signal cable 12 to control the operation of the carriage motor 159.

  As described above, the electromagnetic waves radiated from other devices of the inkjet type multifunction peripheral 100 generate noise in the signal passing through the signal cable 12. This noise enters the main control board 14 from the signal cable 12 through the connector 13. It cannot be denied that noise that has entered the main control board 14 may adversely affect electronic components on the main control board 14. Therefore, the main control board 14 of the present embodiment is covered with the shield plate 11. The shield plate 11 shields electromagnetic waves radiated from other devices and emits them through the grounding wire (not shown) to the outside of the inkjet multifunction peripheral 100. Thereby, the main control board unit 17 is formed with a structure in which electromagnetic waves radiated from other devices do not easily enter the main control board 14.

  However, the shield plate 11 protects noise generated in a signal passing through the signal cable 12 due to electromagnetic waves radiated from other devices from entering the main control board 14 from the signal cable 12 via the connector 13. It is not possible. Therefore, a ferrite core 15 that is a noise filter device is attached to the signal cable 12. Specifically, the signal cable 12 is wound around the ferrite core 15 several times and connected to the connector 13 on the main control board 14. By winding the signal cable 12 around the ferrite core 15 several times, the inductance component of the signal cable 12 is increased as described above. The inductance component attenuates the high-frequency component of the signal, that is, noise while allowing the pulse waveform signal to pass through without being attenuated. Thereby, the noise which generate | occur | produces in the signal which passes the signal cable 12 can be reduced.

  Further, FIG. 5 shows a substrate opening 18 which is a characteristic part of the present invention. The substrate opening 18 is formed to allow the fixing binding band 16 to be inserted into the main control substrate 14 when the ferrite core 15 is fixed by the fixing binding band 16 (see FIG. 6). Naturally, no pattern is formed in the substrate opening 18 so as not to interfere with the various patterns described above. In addition, the substrate opening 18 of the present embodiment is a through hole and penetrates to the back surface of the main control substrate 14. Thereby, the operation | work which inserts the binding band 16 for fixation can be performed easily.

  FIG. 6 is an enlarged view of the periphery of the ferrite core 15 shown in FIG. In FIG. 6, the signal cable 12 is wound around the ferrite core 15 several times, and the signal cable 12 is connected to the connector 13 on the main control board 14. Thus, by winding the signal cable 12 around the ferrite core 15 several times, the inductance component of the signal cable 12 can be increased and noise can be further reduced as compared with the mounting structure shown in FIG. . Furthermore, the workability of the attaching work of the ferrite core 15 is also improved. Further, unlike the attachment structure shown in FIG. 9, noise can be reduced without requiring a connector having a complicated structure.

The main control board 14 is formed with two board openings 18. The fixing tie band 16 is inserted through the substrate opening 18. Further, the fixing binding band 16 is inserted into the center hole of the ring-shaped ferrite core 15 to fix the ferrite core 15 to the main control board 14. Thus, unlike the mounting structure shown in FIG. 7, the ferrite core 15 and the signal cable 12 are prevented from swinging due to vibration generated by movement of the carriage 153 or rotation / stop of the carriage motor 159 or the like. can do. Therefore, the generated noise can be reduced when the ferrite core 15 and the signal cable 12 are swung . Furthermore, since the noise generated by the swing of the ferrite core 15 and the signal cable 12 can be reduced, the magnitude of the noise generated in the signal passing through the signal cable 12 can be stabilized. Furthermore, since the magnitude of the noise is stabilized, the magnitude of electromagnetic waves radiated from the entire inkjet multifunction peripheral 100 is also stabilized. Therefore, the magnitude of the electromagnetic wave can be surely set to the maximum allowable value or less.

  Furthermore, it is possible to completely prevent the ferrite core 15 from colliding with other devices. Therefore, it is not necessary to cover the ferrite core 15 with the shock absorber, and the shock absorber can be eliminated.

  As described above, according to the mounting structure of the noise filter device of the present embodiment, the main control board 14 on which the control circuit 19 that is the first signal processing circuit is formed, and the control circuit 19 on the main control board 14 A signal cable movably disposed between the main control board 14 and the carriage motor 159 so that one end is connected via the connector 13 and the other end is connected to the carriage motor 159 as the second signal processing circuit. 12 and a ferrite core 15 that is a noise filter device attached to one end of the signal cable 12. Further, a substrate opening 18 that is a hole is provided in the vicinity of the connector 13 of the main control substrate 14, and the ferrite core 15 is fixed by a fixing binding band 16 that is a binding member through which the substrate opening 18 is inserted.

As a result, by fixing the ferrite core 15 attached to the signal cable 12 in the vicinity of the main control board 14, the connector 13 for connecting the signal cable 12 has a complicated structure without deteriorating the noise reduction effect. And the ferrite core 15 and the signal cable 12 are not affected by the vibration generated by the movement of the carriage 153 or the rotation / stop of the carriage motor 159 or the like without deteriorating the workability of attaching the ferrite core 15. Oscillation can be prevented. That is, the noise generated in the signal passing through the signal cable 12 can be reduced by the above swinging . From this, it becomes possible to stabilize the magnitude of noise generated in the signal passing through the signal cable 12. Furthermore, since the magnitude of the noise is stabilized, the magnitude of electromagnetic waves radiated from the entire inkjet multifunction peripheral 100 is also stabilized. Therefore, the magnitude of the electromagnetic wave can be surely set to the maximum allowable value or less. Furthermore, it is possible to completely prevent the ferrite core 15 from colliding with other devices. Therefore, it is not necessary to cover the ferrite core 15 with the shock absorber, and the shock absorber can be eliminated.

  Further, according to the mounting structure of the noise filter device of the present embodiment, since the noise filter device is constituted by the ring-shaped ferrite core 15, the fixing device inserted through the substrate opening 18 formed in the main control substrate 14. The ferrite core 15 can be easily fixed by the binding band 16.

Note that the scope of the present invention is not limited to the above-described embodiments, and can be applied to various other embodiments as long as they do not contradict the description of the claims. For example, in this embodiment, the ferrite core 15 attached to the signal cable 12 that connects the main control board 14 and the carriage motor 159 is fixed to the main control board 14, but the present invention is not particularly limited thereto. You may fix the ferrite core 15 to another apparatus or a housing | casing. However, by fixing the ferrite core 15 to the main control board 14, noise entering the main control board 14 can be reduced more efficiently. Further, if the cable is provided with the ferrite core 15, for example, it can be applied to a cable connecting a power supply board and a paper feed motor. Furthermore, other devices may be connected. Further, even if it is not a cable, any medium that generates noise due to the rocking of the ferrite core 15 can be applied.

  In the present embodiment, the present invention is applied to the ring-shaped ferrite core 15. However, the present invention is not particularly limited thereto, and can be applied to other noise filter devices.

  In this embodiment, the ferrite core 15 is fixed to the main control board 14 with the binding band 16 for fixing. However, the present invention is not limited to this, and it may be fixed by other methods. Not too long.

  In the present embodiment, in order to fix the ferrite core 15 to the main control board 14, the board opening 18 which is a through hole is formed in the main control board 14. However, the present invention is not limited to this. The substrate opening 18 may not be a through hole. However, by forming the substrate opening 18 with a through hole, it is possible to easily execute the operation of inserting the binding band 16 for fixation.

  For example, a printer, a facsimile machine, a copying machine or the like can be applied as long as it is a recording device provided with a noise filter device in a signal cable. Further, not limited to a recording device and a reading device, the meaning of a liquid ejecting apparatus that ejects a liquid corresponding to the application from a liquid ejecting head to an ejected medium instead of ink and attaches the liquid to the ejected medium, for example, Color material ejecting head used for manufacturing color filters such as liquid crystal displays, electrode material (conductive paste) ejecting head used for forming electrodes such as organic EL displays and surface emitting displays (FEDs), and bio-organic matter ejecting head used for biochip manufacturing The present invention can also be applied to an apparatus equipped with a sample ejection head as a precision pipette.

1 is a perspective view showing an overall appearance configuration of an ink jet type multifunction peripheral that is one of recording apparatuses according to an embodiment of the present invention. It is a perspective view which shows the internal structure of the printer of the inkjet type multi-function machine shown in FIG. It is a perspective view which shows the positional relationship of the operation part shown in FIG. 1, and a main control board unit. It is the perspective view which looked at the state which applied the attachment structure of the ferrite core which is the characteristic part of this invention to the main control board unit shown in FIG. 3 from the plane. It is a detailed top view of the main control board before mounting the electronic component which comprises the main control board unit shown in FIG. FIG. 5 is an enlarged view around the ferrite core shown in FIG. 4. It is a front view which shows the structure which wound the conventional ferrite core around the ground wire several times. It is a front view which shows the structure which attached the conventional ferrite core between the front-end | tip part of an inlet and a grounding terminal. It is sectional drawing which shows the structure which provided the conventional ferrite core inside the inlet.

Explanation of symbols

1, inlet, 2 ground terminal, 2a tip, 2i ground terminal part, 3 lead terminal, 3i lead terminal part, 5, 5A, 5B ferrite core, 7 ground wire, 8 crimp terminal, 9 power supply board,
10 ink cartridge, 11 shield plate,
12 signal cable, 13 connector, 14 main control board, 15 ferrite core,
16 Binding band, 17 Main control board unit, 18 Board opening,
19 control circuit, 20 grounding member,
21 BGA package wiring pattern, 22 Connector wiring pattern,
23 capacitor wiring pattern, 24 coil wiring pattern,
25 QFP package wiring pattern, 26 resist,
100 Inkjet MFP, 101 housing, 102 scanner cover,
103 Handle, 104 Cartridge storage section, 106 Operation section, 107 Liquid crystal panel, 110 Printer, 120 Scanner, 130 Paper feed section, 140 Feed / discharge section,
150 recording unit, 153 carriage, 158 carriage belt,
159 Carriage motor

Claims (4)

The substrate on which the first signal processing circuit is formed, the first signal processing circuit on the substrate and the one end side being connected via the connector, and the other end side being connected to the second signal processing circuit. In the mounting structure of the noise filter device comprising: a signal cable movably disposed between the first signal processing circuit and the second signal processing circuit; and a noise filter device mounted on the one end side of the signal cable. A mounting structure for a noise filter device, wherein a hole is provided in the vicinity of the connector, and the noise filter device is fixed by a bundling member through which the hole is inserted. 2. The noise filter device mounting structure according to claim 1, wherein the noise filter device comprises a ring-shaped ferrite core. A recording apparatus for recording on a recording medium, comprising the noise filter device mounting structure according to claim 1 or 2. A liquid ejecting apparatus that ejects liquid onto a medium to be ejected, comprising the noise filter device mounting structure according to claim 1.

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