JP2017226200A - Inkjet head and inkjet recording device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inkjet head that can excellently radiate heat which is generated from a piezoelectric element for discharging ink from a pressure chamber and a wiring substrate for supplying electricity to the piezoelectric element, and an inkjet recording device.SOLUTION: The inkjet head comprises: an ink storage chamber 41; at least one pressure chamber 23 which is communicated with the ink storage chamber 41 through an injection hole 31a and is applied with voltages to cause variation of volumes; a discharge nozzle 22, communicated with the pressure chamber 23, which discharges ink in the pressure chamber 23 to the outside; pseudo pressure chambers 25, positioned adjacently across the pressure chamber 23, which cause vibration of volumes due to the variation of volumes of the pressure chamber 23; and supply passages 28, communicated with the pseudo pressure chambers 25, which supply fluid (heat media) into the pseudo pressure chambers 25.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an ink jet head and an ink jet recording apparatus, and more specifically, a piezoelectric element that discharges ink from a pressure chamber, and an ink jet head that can well dissipate heat generated from a wiring board that supplies power to the piezoelectric element. The present invention relates to an ink jet recording apparatus.

  Various inkjet heads such as a shear mode (edge (end) shooter, side shooter) type and a bend mode type have been proposed as an inkjet head used in a general printer (inkjet recording apparatus).

  In these various inkjet heads, an inkjet head having an ink circulation mechanism for returning ink injected into a pressure chamber (ink channel) to an ink storage chamber (common ink chamber) has been proposed. The purpose of providing the ink circulation mechanism is to remove bubbles in the pressure chamber, prevent ink settling, reduce the amount of ink discarded during initial introduction, prevent decap, and the like.

  Patent Documents 1 to 3 describe an inkjet head provided with pseudo pressure chambers (dummy channels) 225 and 225 on both sides of the pressure chamber 223 as shown in FIG. In this ink jet head, two piezoelectric elements (drive walls) 224 and 224 are provided for each pressure chamber 223, and the piezoelectric elements 224 and 224 form both wall portions of each pressure chamber 223. . There is a gap between the piezoelectric element 224 constituting one pressure chamber 223 and the piezoelectric element 224 constituting the adjacent pressure chamber 223, and this gap is a pseudo pressure chamber 225. Therefore, each pressure chamber 223 can be driven (expanded or contracted) independently.

JP, 2015-171801, A JP, 2015-171803, A JP2015-171805A

  By the way, in the above-described ink jet head, in particular, a shear mode type ink jet head, as shown in FIG. 15, the piezoelectric element 224 that discharges ink from the pressure chamber 223 and the wiring substrate 203 that supplies power to the piezoelectric element 224 are used. The heat generation becomes a problem. If the heat generated by the piezoelectric element 224 or the wiring board 203 is stored without being dissipated, the temperature of the piezoelectric element 224 or the wiring board 203 rises, and the normal operation of the piezoelectric element 224 may be hindered. . Further, since the piezoelectric element 224 and the discharge nozzle 222 are close to each other, the viscosity of the ink in the discharge nozzle 222 is lowered by the heat generated by the piezoelectric element 224, and normal discharge operation may be hindered. .

  In any of the various ink jet heads described above, the heat generated by the piezoelectric elements and the wiring board cannot be sufficiently dissipated even if the ink is circulated. Further, in the ink jet head described in the above-described patent document, the pseudo pressure chamber (dummy channel) 225 does not contribute to the heat dissipation of the heat generated by the piezoelectric element 224 or the wiring substrate 203.

  Therefore, the present invention provides a piezoelectric element that discharges ink from a pressure chamber, and an inkjet head and an inkjet recording apparatus that can efficiently dissipate heat generated from a wiring board for supplying power to the piezoelectric element. Let it be an issue.

  Other problems of the present invention will become apparent from the following description.

  The above problems are solved by the following inventions.

An inkjet head reflecting one aspect of the present invention is:
An ink storage chamber;
At least one pressure chamber communicating with the ink storage chamber via an injection hole and causing a volume variation by application of a voltage;
A discharge nozzle that communicates with the pressure chamber and discharges the ink in the pressure chamber to the outside;
A pseudo pressure chamber that is formed at a position including both adjacent positions sandwiching the pressure chamber, and capable of changing the volume by an external pressure;
And a supply passage that communicates with the pseudo pressure chamber and supplies fluid to the pseudo pressure chamber.

Further, an inkjet recording apparatus reflecting one aspect of the present invention,
The inkjet head;
An ink tank for storing ink transferred to the inkjet head;
And an ink transfer section for transferring the ink in the ink tank to the inkjet head.

  According to the present invention, it is possible to provide an ink jet head and an ink jet recording apparatus capable of satisfactorily dissipating heat generated from a piezoelectric element that discharges ink from a pressure chamber and a wiring board that supplies power to the piezoelectric element. it can.

1 is a schematic configuration diagram of a main part showing an example of an inkjet recording apparatus according to the present invention. FIG. 3 is a flow chart showing ink flow paths in the inkjet head according to the present invention. The perspective view of the actuator member of the inkjet head shown in FIG. 1 is an exploded perspective view of an actuator member of the inkjet head shown in FIG. FIG. 1 is an enlarged sectional view of an actuator member of the ink jet head shown in FIG. FIG. 1 is an enlarged cross-sectional view showing another example of the introduction path of the inkjet head shown in FIG. FIG. 1 is an enlarged cross-sectional view showing still another example of the introduction path of the inkjet head shown in FIG. FIG. 1 is an enlarged cross-sectional view showing still another example of the introduction path of the inkjet head shown in FIG. FIG. 1 is an enlarged cross-sectional view showing still another example of the introduction path of the inkjet head shown in FIG. FIG. 1 is an enlarged sectional view showing another example of the individual communication path of the ink jet head shown in FIG. FIG. 3 is an enlarged sectional view showing still another example of the individual communication path of the ink jet head shown in FIG. The expanded sectional view which shows the other example of the actuator member of the inkjet head shown in FIG. FIG. 2 is an enlarged cross-sectional view showing still another example of the actuator member of the ink jet head shown in FIG. The perspective view which shows an example of the flow volume adjustment member which shows the state which notched the ink collection pipe partially Enlarged cross-sectional view of a conventional inkjet head actuator member

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

[Inkjet recording device]
FIG. 1 is a schematic configuration diagram of a main part showing an example of an ink jet recording apparatus according to the present invention, and shows a partial cross section of an ink jet head.

  The ink jet recording apparatus 100 records an image by ejecting ink, which is a fluid, from the ink jet head 1 onto a recording medium transported in a certain direction (sub-scanning direction) by a transport unit (not shown). In a so-called one-pass ink jet recording apparatus, the ink jet head 1 is fixedly disposed, and ink is ejected from the ejection nozzle toward the recording medium in the process of transporting the recording medium. In a so-called scanning ink jet recording apparatus, the ink jet head 1 is mounted on a carriage (not shown), and the carriage moves from the discharge nozzle to the recording medium in the process of moving along the main scanning direction orthogonal to the sub scanning direction. Ink is ejected toward. In the ink jet recording apparatus 100 shown in the present embodiment, the ink jet head 1 is installed such that scanning is performed in the horizontal direction and the ink ejection direction from the ejection nozzles is downward in the vertical direction.

  In FIG. 1, only one ink jet head 1 is shown, but in general, an ink jet recording apparatus 100 is provided for each color ink such as yellow (Y), magenta (M), cyan (C), and K (black). A plurality of inkjet heads 1 are mounted. In the ink jet recording apparatus 100 shown in the present embodiment, an ink tank 101 that stores ink and an ink storage chamber 41 of the ink jet head 1 are communicated with each other by an ink transfer pipe 102 and an ink return pipe 103.

  A transfer pump 105 that is driven and controlled by the control unit 104 of the inkjet recording apparatus 100 is provided in the middle of the ink transfer tube 102. When the transfer pump 105 is driven, the ink in the ink tank 101 is transferred to the inkjet head 1 via the ink transfer pipe 102. Further, when the transfer pump 105 is driven, ink in the inkjet head 1 is returned to the ink tank 101 via the ink return pipe 103. In the inkjet recording apparatus 100, the ink transfer tube 102, the control unit 104, and the transfer pump 105 constitute an ink transfer unit that transfers the ink in the ink tank 101 to the inkjet head 1.

  The ink tank 101 is not particularly limited, but is preferably partitioned into an ink transfer chamber 101b and an ink return chamber 101c by a partition plate 101a that does not reach the bottom of the tank. In this case, one end of the ink transfer tube 102 is arranged in the ink transfer chamber 101b, and one end of the ink return tube 103 is arranged in the ink return chamber 101c. The partition plate 101a is provided to sufficiently deaerate ink so that bubbles contained in the ink returned to the ink return chamber 101c do not flow into the ink transfer pipe 102 again. Since the bubbles themselves have high buoyancy, the bubbles are restricted from flowing under the partition plate 101a and flowing into the ink transfer chamber 101b. Such an embodiment is a preferred embodiment when the ink is circulated.

[Inkjet head]
Next, a specific configuration of the inkjet head 1 according to the present invention shown in FIG. 1 will be described.

  The present invention can be applied to various ink jet heads such as a shear mode (edge (end) shooter, side shooter) type, bend mode type, so-called MEMS type, that is, the ink jet head according to the present invention can be applied to these various types. The inkjet head can be configured.

  The ink jet head 1 shown in the present embodiment is configured as a shear mode head. The ink jet head 1 is installed and used such that the ink discharge surface 1S faces downward in the vertical direction. In the present specification, “upper” and “lower” mean “upper side in the vertical direction” and “lower side in the vertical direction”, and correspond to the upper side and the lower side in the side view of the use state shown in FIG.

  As shown in FIG. 1, the inkjet head 1 includes an ink manifold 4 constituting an ink storage chamber 41, a wiring board 3 bonded to the ink manifold 4, and an opposite side of the ink manifold 4 across the wiring board 3. The actuator member 2 is bonded to the surface (lower surface).

  The wiring board 3 is a glass substrate, for example. The ink manifold 4 is formed in a horizontally long box shape having an opening 4a on the lower surface, using synthetic resin or the like. In the ink manifold 4, the opening 4 a is blocked by the wiring substrate 3 bonded to the lower surface. The internal space of the ink manifold 4 serves as an ink storage chamber 41 in which ink supplied from the ink tank 101 is stored.

  A plurality of pressure chambers (ink channels) 23 and a plurality of pseudo pressure chambers (dummy channels) 25 are formed in the actuator member 2. The pressure chamber 23 communicates with the ink storage chamber 41 through the injection hole 31 a, and volume fluctuation occurs when a voltage is applied through the wiring substrate 3. The pseudo pressure chamber 25 is located on both sides of the pressure chamber 23, and the volume fluctuation occurs due to the volume fluctuation of the pressure chamber 23.

  FIG. 2 is a flow path diagram showing the flow path of the ink in this ink jet head.

  As shown in FIGS. 1 and 2, an ink supply pipe 5 a that forms a flow path for supplying ink into the ink storage chamber 41 is connected to the ink storage chamber 41. The ink supply pipe 5 a communicates with the ink storage chamber 41 on the side (upper side) far from the pressure chamber (ink channel) 23. A connecting portion 7a is provided on the upper end side of the ink supply pipe 5a. The connecting portion 7a is detachably connected to the connecting portion 106a on the ink jet recording apparatus 100 side. The connecting portion 106 a on the ink jet recording apparatus 100 side communicates with the ink transfer tube 102. As a result, the ink jet head 1 can transfer ink from the ink jet recording apparatus 100.

  The ink storage chamber 41 is provided with an ink recovery pipe 5b that forms a flow path for recovering ink from the ink storage chamber 41. The ink recovery pipe 5 b communicates with the ink storage chamber 41 on the side farther from the pressure chamber 23 (upper side). A connecting portion 7b is provided on the upper end side of the ink recovery tube 5b. The connecting portion 7b is detachably connected to the connecting portion 106b on the ink jet recording apparatus 100 side. The connection part 106 b on the ink jet recording apparatus 100 side communicates with the ink return pipe 103. As a result, the ink jet head 1 can return ink to the ink jet recording apparatus 100.

  In the ink jet head 1, a flow path from the ink supply pipe 5a to a buffer space portion 6 to be described later in the middle of the ink recovery pipe 5b is a main flow path F1.

  The ink supply pipe 5a and the ink recovery pipe 5b are preferably arranged apart from both ends of the ink storage chamber 41 in the longitudinal direction. In the present embodiment, the ink supply pipe 5a is disposed at the left end in FIG. 1 on the top surface of the ink manifold 4, and the ink recovery pipe 5b is on the right end in FIG. Is arranged. Thereby, the ink supplied from the ink supply pipe 5a to the ink storage chamber 41 can be made to flow over the entire inside of the ink storage chamber 41 toward the ink recovery pipe 5b. Accordingly, it is difficult to form a portion where the ink stays in the ink storage chamber 41, and bubbles in the ink can be more efficiently eliminated.

  An ink discharge chamber 412 is provided in the ink manifold 4 adjacent to the ink storage chamber 41. The ink discharge chamber 412 is separated from the ink storage chamber 41 by a partition wall 45. The partition wall 45 can be formed integrally with the ink manifold 4.

  FIG. 3 is a perspective view of an actuator member of the inkjet head shown in FIG.

  FIG. 4 is an exploded perspective view of the actuator member of the inkjet head shown in FIG.

  FIG. 5 is an enlarged cross-sectional view of the actuator member of the inkjet head shown in FIG.

  As described above, the actuator member 2 is formed with a plurality of pressure chambers 23 and a plurality of pseudo pressure chambers 25 as shown in FIGS. The pressure chamber 23 includes a pair of piezoelectric elements (drive walls) 24 and 24. Two piezoelectric elements 24, 24 are provided for each pressure chamber 23, and form both wall portions of each pressure chamber 23. There is a gap between the piezoelectric element 24 constituting one pressure chamber 23 and the piezoelectric element 24 constituting the adjacent pressure chamber 23, and this gap is the pseudo pressure chamber 25. Therefore, each pressure chamber 23 can be driven (expanded or contracted) independently. The wiring board 3 is formed with wiring (not shown) for supplying power to each piezoelectric element 24.

  Each pressure chamber 23 communicates with the ink storage chamber 41 through an injection hole 31 a formed in the wiring board 3. Ink, which is a fluid in the ink storage chamber 41, is injected into each pressure chamber 23 through the injection hole 31a. Each pressure chamber 23 undergoes volume fluctuation by application of a voltage to the piezoelectric element 24. In the actuator member 2, a nozzle plate 21 provided with a plurality of discharge nozzles 22 corresponding to the pressure chambers 23 is bonded to the opposite surface (lower surface) of the wiring board 3. The discharge nozzle 22 allows the pressure chamber 23 to communicate with the outside (downward). The lower surface portion of the nozzle plate 21 becomes the ink ejection surface 1S. The ink in each pressure chamber 23 is given a discharge pressure by the action of the piezoelectric element 24, and is discharged toward the external (lower) recording medium through the discharge nozzle 22.

  There are no particular means for applying discharge pressure to the ink in the pressure chamber 23, and various known means can be employed. In the present embodiment, as shown in FIG. 5, the adjacent pressure chambers 23, 23 are separated by the piezoelectric element 24 and the pseudo pressure chamber 25. The piezoelectric element 24 is applied to a driving electrode (not shown) formed on the surface facing the pressure chamber 23 by applying a driving voltage of a predetermined voltage from the control unit 104 via a wiring (not shown) formed on the wiring board 3, for example. , Shear deformation. When the piezoelectric elements 24, 24 on both sides of the pressure chamber 23 undergo shear deformation, the inside of the pressure chamber 23 expands or contracts. As a result, pressure is applied to the ink in the pressure chamber 23, and the ink is ejected through the ejection nozzle 22.

  The number of the pressure chambers 23 formed in the actuator member 2 is not particularly limited. In the actuator member 2 shown in the present embodiment, a plurality of pressure chambers 23 are arranged in a plurality of rows along the X direction in FIGS. 3 to 5, which is the longitudinal direction of the actuator member 2.

  The pressure chamber 23 and the pseudo pressure chamber 25 are communicated with each other through an introduction path 26 as shown in FIGS. The introduction path 26 guides the ink in the pressure chamber 24 to the pseudo pressure chamber 25. In the present embodiment, the introduction path 26 is a groove formed on the upper surface of the nozzle plate 21 corresponding to each pressure chamber 23 and reaching the adjacent pseudo pressure chamber 25, and the nozzle plate 21 is attached to the actuator member 2. Thus, a flow path is configured.

  The introduction path 26 may be formed so as to reach the two pseudo pressure chambers 25, 25 adjacent to each other from each pressure chamber 23.

  Further, as shown in FIGS. 4 and 5, an individual communication path 422 is formed at the side of each pseudo pressure chamber 25. These individual communication paths 422 are formed in the actuator member 2. These individual communication paths 422 communicate with and merge with the common flow path 421. The common channel 421 is a groove formed in the side surface of the actuator member 2 in the arrangement direction (X direction) of the pressure chambers 23, and the lid member 27 is attached to the side surface of the actuator member 2, Constitutes the road. The end of the common flow path 421 is in communication with a discharge channel 424 formed in the actuator member 2. The discharge channel 424 is formed on one end side in the longitudinal direction of the actuator member 2 and is positioned below the ink discharge chamber 412. In this way, the space from the injection hole 31 a through the introduction path 26 to the pseudo pressure chamber 25 is communicated with the discharge channel 424.

  As shown in FIGS. 4 and 5, a part of the ink injected into the pressure chamber 23 from the injection hole 31a reaches the pseudo pressure chamber 25 through the introduction path 26, and further passes through the individual communication path 422 to the common flow. The road 421 is reached. Then, the ink that has reached the common flow path 421 passes through the discharge channel 424, passes through the discharge hole 31 b formed in the wiring substrate 3, and reaches the ink discharge chamber 412.

  In the ink jet head 1, the individual communication path 422 and the common flow path 421 provided in the actuator member 2 serve as ink flow paths in the head, and the wiring substrate 3 that is a heat generation source via the ink flowing through the ink flow paths. The heat generated by the actuator member 2 can be dissipated. For this reason, even when the piezoelectric element 24 and the discharge nozzle 22 are close to each other, the viscosity of the ink in the discharge nozzle 22 is not reduced by the heat generated by the piezoelectric element 24, and a normal discharge operation can be ensured.

  In the inkjet head 1, it is considered that a flow path is formed from each pressure chamber 23 to each ink pressure chamber 25 via each pseudo pressure chamber 25, each individual communication path 422, and the common flow path 421. Thus, conditions such as the pressure applied by the transfer pump 105 are determined so that no meniscus break from the discharge nozzle 22 occurs under these conditions.

  As shown in FIGS. 1 and 2, the ink discharge chamber 412 is provided with an ink discharge pipe 5 c that forms a flow path for discharging ink from the ink discharge chamber 412. The upper end side of the ink discharge pipe 5c joins the ink recovery pipe 5b. The ink recovery pipe 5 b and the ink discharge pipe 5 c are joined together by being connected to the junction box 61.

  The junction box 61 is integrally formed of a synthetic resin material or a metal material, and has a buffer space 6 formed therein. First to third openings 48 a, 48 b, 48 c reaching the buffer space 6 are formed on the outer surface of the junction box 61. The flow path from the first opening 48a through the buffer space 6 to the third opening 48c is interposed in the middle of the ink recovery pipe 5b. In the mounting state, the ink recovery pipe 5b is divided into an upstream side and a downstream side in the middle part, the upstream side is connected to the first opening 48a, and the downstream side is connected to the third opening 48c. The ink discharge pipe 5c is connected to the second opening 48b.

  In the inkjet head 1, there is a flow path from the introduction path 26 to the buffer space 6 through the individual communication path 422, the common flow path 421, the discharge channel 424, the discharge hole 31 b, the ink discharge chamber 412, and the ink discharge pipe 5 c. The discharge path 423 is formed. The discharge path 423 is a flow path that communicates with the pressure chamber 23, discharges the ink in the pressure chamber 23, and joins the ink recovery pipe 5 b in the buffer space 6. Then, through each injection hole 31a, the discharge path 423 (the inlet from the introduction path 26 to the buffer space 6) becomes the sub-flow path F2.

  In the ink jet head 1 shown in the present embodiment, since the ink recovery pipe 5b and the ink discharge pipe 5c are joined by the junction box 61, the connection portion with the pipe on the ink jet recording apparatus 100 side is the ink supply pipe 5a (connection Only the two portions of the portion 7a) and the ink recovery pipe 5b (connection portion 7b) are required. Therefore, the ink jet head 1 shown in the present embodiment is compatible with the ink jet head of a general ink jet recording apparatus provided with a circulation mechanism, and the number of connection parts does not increase, and the connection work becomes complicated. Absent.

  By the way, since the discharge path 423 is configured as a flow path that passes through all of the introduction path 26 corresponding to each pressure chamber 23 and the individual communication path 422 corresponding to each pseudo pressure chamber 25, the density of the pressure chamber 23 is increased. Accordingly, the flow path resistance of the entire discharge path 423 increases. Therefore, even if the ink discharge pipe 5c is joined to the ink recovery pipe 5b, the flow rate of the main flow path F1 passing through the ink recovery pipe 5b from the ink supply pipe 5a is large, and the sub flow path F2 extending from each injection hole 31a to the discharge path 423. It is conceivable that they do not merge smoothly because of the low flow rate. In the ink jet head 1, the main flow path F1 and the sub flow path F2 are merged (merge between the ink discharge pipe 5c and the ink recovery pipe 5b) in the buffer space portion 6, so that the main flow path F1 and the sub flow are combined. Even if the flow rates of the paths F2 are different, they can be smoothly merged.

  According to the ink jet head 1 and the ink jet recording apparatus 100 including the ink jet head 1 as described above, the heat generated by the wiring board 3 and the actuator member 2 that are heat sources is radiated only by supplying ink from the ink supply pipe 5a. Can do. Further, not only the remaining bubbles in the ink storage chamber 41 are discharged from the ink recovery pipe 5b through the main flow path F1, but also the bubbles in the vicinity of the pressure chamber 23 drawn from the discharge nozzle 22 are also passed through the sub flow path F2. It can be quickly discharged from the discharge pipe 5c. Therefore, heat radiation and residual bubble removal can be efficiently performed in the entire ink manifold 4 (in the ink storage chamber 41 and in the vicinity of the pressure chamber 23). Further, even when using ink containing particles or pigments that easily settle, the sedimentation of particles or pigments in each individual communication path 422 and common channel 421 during image recording is effectively suppressed, Ink density deviation can be suppressed.

[Other Embodiments of Introduction Path]
FIG. 6 is an enlarged cross-sectional view showing another example of the introduction path of the ink jet head shown in FIG. Since the site | part of the same code | symbol as FIG. 1 is a site | part of the same function, these description uses the said description and abbreviate | omits here.

  In this ink jet head 1, as shown in FIG. 6, the introduction path 26 has a flow path plate 33 interposed between the actuator member 2 and the nozzle plate 21 as a plate-like spacer member, and the upper surface of the flow path plate 33. You may comprise by the groove | channel formed in. In this case, the introduction path 26 is configured by bonding the flow path plate 33 to the lower surface of the actuator member 2. The nozzle plate 21 is bonded to the lower surface of the flow path plate 33. Through holes corresponding to the respective discharge nozzles 22 are formed in the flow path plate 33.

  Preferred examples of the material of the flow path plate 33 include glass, silicon, stainless steel, and polyimide resin. In terms of price (being inexpensive), glass, stainless steel, and polyimide are superior. For ease of processing, stainless steel and polyimide are superior. For processing accuracy, silicon is superior. For chemical stability, , Glass and polyimide are excellent.

  In this case, as will be described later, in an embodiment in which the individual communication path 422 and the common flow path 421 are provided below the pressure chamber 23 and the pseudo pressure chamber 25, the individual communication path 422 and the common flow path 421 are provided as flow paths. It can be constituted by a groove formed on the upper surface of the plate 33. In this case, the individual communication path 422 and the common flow path 421 are configured by bonding the flow path plate 33 to the lower surface of the actuator member 2.

  FIG. 7 is an enlarged cross-sectional view showing still another example of the introduction path of the inkjet head shown in FIG. Since the site | part of the same code | symbol as FIG. 1 is a site | part of the same function, these description uses the said description and abbreviate | omits here.

  In the inkjet head 1, the introduction path 26 may be provided in the piezoelectric element 24 corresponding to each pressure chamber 23 as shown in FIG. 7. The introduction path 26 is a groove formed on the upper surface of the actuator member 2 corresponding to each pressure chamber 23, and the wiring board 3 is overlaid on the actuator member 2 to form a flow path. The introduction path 26 can also guide the ink in the pressure chamber 24 to the pseudo pressure chamber 25.

  The introduction path 26 may be formed in each of the piezoelectric elements 24 between the two pseudo pressure chambers 25 and 25 adjacent to each pressure chamber 23.

  FIG. 8 is an enlarged cross-sectional view showing still another example of the introduction path of the inkjet head shown in FIG. Since the site | part of the same code | symbol as FIG. 1 is a site | part of the same function, these description uses the said description and abbreviate | omits here.

  In the inkjet head 1, the introduction path 26 may be provided in the wiring board 3 corresponding to each pressure chamber 23 as shown in FIG. 8. The introduction path 26 is a groove formed on the lower surface of the wiring board 3 corresponding to each pressure chamber 23, and constitutes a flow path by overlapping the wiring board 3 on the actuator member 2. The introduction path 26 can guide a part of the ink injected into the pressure chamber 24 from the injection hole 31 a to the pseudo pressure chamber 25.

  The introduction path 26 may be formed so as to reach the two pseudo pressure chambers 25, 25 adjacent to each other from each pressure chamber 23.

  FIG. 9 is an enlarged sectional view showing still another example of the introduction path of the inkjet head shown in FIG. Since the site | part of the same code | symbol as FIG. 1 is a site | part of the same function, these description uses the said description and abbreviate | omits here.

  In the inkjet head 1, the introduction path 26 may be a through hole provided in the wiring board 3 corresponding to each pseudo pressure chamber 25 as shown in FIG. 9. In this case, the ink in the ink storage chamber 41 is introduced directly into the pseudo pressure chamber 25 via the introduction path 26, separately from the path for injecting into the pressure chamber 23.

  In this case, each pressure chamber 23 communicates with the common flow path 421 through the individual communication path 425 in the same manner as each pseudo pressure chamber 25, and the ink in the pressure chamber 23 is discharged to the ink discharge chamber 412. It is preferable to do so.

[Other Embodiments of Individual Communication Channel and Common Channel]
FIG. 10 is an enlarged cross-sectional view showing another example of the individual communication path of the ink jet head shown in FIG. Since the site | part of the same code | symbol as FIG. 1 is a site | part of the same function, these description uses the said description and abbreviate | omits here.

  In the inkjet head 1, the individual communication path 422 and the common flow path 421 may be configured by grooves formed on the lower surface of the wiring board 3 as shown in FIG. 10. In this case, the individual communication path 422 and the common flow path 421 are configured by overlapping the wiring board 3 on the actuator member 2.

  Also in this case, the ink in each pseudo pressure chamber 25 merges through the individual communication path 422 to the common flow path 421, and reaches the ink discharge chamber 412 through the discharge channel 424 and the discharge hole 31b.

  FIG. 11 is an enlarged cross-sectional view showing still another example of the individual communication path of the inkjet head shown in FIG. Since the site | part of the same code | symbol as FIG. 1 is a site | part of the same function, these description uses the said description and abbreviate | omits here.

  In the inkjet head 1, the individual communication path 422 and the common flow path 421 may be configured by grooves formed on the upper surface of the nozzle plate 21 as shown in FIG. 11. In this case, the nozzle plate 21 is bonded to the lower surface of the actuator member 2 to form the individual communication path 422 and the common flow path 421.

  Also in this case, the ink in each pseudo pressure chamber 25 merges through the individual communication path 422 to the common flow path 421, and reaches the ink discharge chamber 412 through the discharge channel 424 and the discharge hole 31b.

  In the inkjet head 1, as described above, the individual communication path 422 and the common flow path 421 have the flow path plate 33 interposed between the actuator member 2 and the nozzle plate 21 as shown in FIG. 6. The groove may be formed by a groove formed on the upper surface of the flow path plate 33. In this case, the individual communication path 422 and the common flow path 421 are configured by bonding the flow path plate 33 to the lower surface of the actuator member 2. The nozzle plate 21 is bonded to the lower surface of the flow path plate 33.

  In addition, each embodiment of the introduction path 26 described above and each embodiment of the individual communication path 422 and the common flow path 421 can be arbitrarily combined to constitute the inkjet head 1.

[Other Embodiments of Actuator Member]
FIG. 12 is an enlarged cross-sectional view showing another example of the actuator member of the ink jet head shown in FIG. Since the site | part of the same code | symbol as FIG. 1 is a site | part of the same function, these description uses the said description and abbreviate | omits here.

In the inkjet head 1, at least one of the pseudo pressure chambers 25 may be an air chamber 34 that forms a closed space where fluid does not flow as shown in FIG. That is, in the actuator member 2, at least one of the pseudo pressure chambers 25 described above can be an air chamber 34 that is not communicated with the introduction path 26 and the common flow path 421. In this embodiment, the same number of air chambers 34 as the number of pressure chambers 23 are provided between each pressure chamber 23 and each pseudo pressure chamber 25. That is, the arrangement is such that "pseudo pressure chamber 25 -air chamber 34 -pressure chamber 23" is repeated as a unit.

  The air chamber 34 and the pressure chamber 23 are separated by a piezoelectric element 24. The wall surface 35 that separates the air chamber 34 and the pseudo pressure chamber 25 does not need to be deformed and therefore does not need to be the piezoelectric element 24. However, the wall surface 35 may be formed integrally with the piezoelectric element 24 by the same material as the piezoelectric element 24 so that no voltage is applied.

  The air chamber 34 is closed by the wiring board 3 on the upper side and closed by the nozzle plate 21 on the lower side. The air chamber 34 is a closed space because it does not communicate with the introduction channel 26 or the common channel 421.

  The number of air chambers 34 may be provided between each pressure chamber 23 and each pseudo pressure chamber 25 by twice the number of pressure chambers 23. That is, “pseudo pressure chamber 25−air chamber 34−pressure chamber 23−air chamber 34” may be repeated as a unit.

  By providing the air chamber 34 in this way, the crosstalk due to the driving of each pressure chamber 23 can be reduced, but the driving efficiency of the pressure chamber 23 is increased, although the resolution is inferior to each of the embodiments described above. be able to.

  Even in the case where the air chamber 34 is provided in this way, the introduction path 26, the individual communication path 422, and the common flow path 421 are the same as the embodiments of the introduction path 26, the individual communication path 422, and the common flow path 421. The ink jet head 1 can be configured by applying any combination of the embodiments.

[Still Other Embodiment of Actuator Member]
FIG. 13 is an enlarged cross-sectional view showing still another example of the actuator member of the inkjet head shown in FIG. Since the site | part of the same code | symbol as FIG. 1 is a site | part of the same function, these description uses the said description and abbreviate | omits here.

  In this inkjet head 1, the actuator member 2 may be configured such that a fluid (liquid or gas) that is not ink is supplied to the pseudo pressure chamber 25 as shown in FIG. This fluid is preferably a heat medium (refrigerant or warming medium).

  That is, a fluid that is not ink is supplied to the pseudo pressure chamber 25 via a supply path 28 including a common supply path 29 and an individual supply path 30. An individual supply path 30 communicates with each pseudo pressure chamber 25. Each individual supply path 30 communicates with the common supply path 29 and is branched from the common supply path 29. The common supply path 29 and the individual supply path 30 have the same structure as the individual communication path 422 and the common flow path 421 described above.

  Further, a fluid other than ink is discharged from the pseudo pressure chamber 25 through the individual communication path 33 and the common flow path 32. An individual communication path 33 communicates with each pseudo pressure chamber 25. Each individual communication path 33 communicates with and merges with the common flow path 32. The common supply path 32 and the individual supply path 33 have the same structure as the individual communication path 422 and the common flow path 421 described above.

  The fluid that is not ink supplied to the pseudo pressure chamber 25 is supplied to the pseudo pressure chamber 25 and discharged from the pseudo pressure chamber 25 by a circulation mechanism (not shown) different from the ink. That is, fluid that is not ink is supplied to the pseudo pressure chamber 25 from a fluid tank (not shown) through a common supply path 29 and an individual supply path 30 by a pump. The fluid that is not ink supplied to the pseudo pressure chamber 25 is discharged from the individual communication path 33 by the pressure supplied by the pump, and is returned to the fluid tank via the common flow path 32.

  The individual supply path 30 and the common supply path 29 that communicate with the pseudo pressure chamber 25, and the individual communication path 33 and the common flow path 32 include the individual communication path 422 and the common flow path 421 described above for the fluid that is not ink. It is possible to apply any combination of the structures in the embodiments.

  The ink in the pressure chamber 23 is discharged via the individual communication path 422 and the common flow path 421 described above. In this embodiment, an individual communication path 422 communicates with each pressure chamber 23. Each individual communication path 422 communicates with and merges with the common flow path 421. The individual communication path 422 and the common flow path 421 have the same structure as the individual communication path 422 and the common flow path 421 in the above-described embodiments. That is, the embodiments of the individual communication path 422 and the common flow path 421 described above can be applied to the pressure chamber 23 for the ink.

  In the inkjet head 1, the common supply path 29, the individual supply path 30, the individual communication path 33 and the common flow path 32 provided in the actuator member 2 serve as fluid flow paths in the head, and the fluid flowing through the fluid flow path is Thus, the heat generated by the wiring board 3 and the actuator member 2 that are heat sources can be radiated. Further, if necessary, the wiring board 3 and the actuator member 2 can be heated via the fluid flowing through the fluid flow path.

[Pressure loss adjusting means]
The ink jet head 1 may be provided with pressure loss adjusting means for adjusting the relative relationship between the channel resistance of the main channel F1 and the channel resistance of the sub-channel F2.

  This pressure loss adjusting means applies a pressure loss ΔP corresponding to the difference in flow path resistance between the main flow path F1 and the sub flow path F2 to the main flow path F1. Alternatively, the pressure loss adjusting means reduces the flow resistance of the sub flow path F2 to correspond to the flow resistance of the main flow path F1.

  The channel resistance of the sub-channel F2 is determined by the channel diameter, the channel length, the number of bent portions, the flow velocity, etc. in the entire discharge channel 423 including all the injection holes 31a, all the individual communication channels 422 and the common channel 421. It is channel resistance. Since the individual communication path 422 and the common flow path 421 have a very small flow path diameter and a long flow path length, a large flow resistance is generated.

  In this ink jet head 1, the pressure loss adjusting means balances the flow resistance of the main flow path F1 and the flow resistance of the sub flow path F2 so that the ink pressure P0 in the ink supply pipe 5a can be easily adjusted. Ink can flow equally in both the main flow path F1 and the sub flow path F2.

  An example of the pressure loss adjusting means is shown in FIG. FIG. 14 is a perspective view showing a state in which the ink recovery pipe 5b provided with an example of the pressure loss adjusting means is partially broken.

  As the pressure loss adjusting means, for example, as shown in FIG. 14, a flow rate adjusting member 9 that partially narrows the flow path cross-sectional area of the ink recovery pipe 5b can be used. The flow rate adjusting member 9 is a member that is held in the ink recovery tube 5b and partially narrows the inner diameter of the ink recovery tube 5b. The flow rate adjusting member 9 of the present embodiment is integrally configured with a cylindrical portion 95 along the inner wall of the ink recovery pipe 5b and a disk portion 96 that closes one end of the cylindrical portion 95. A flow path hole 94 is formed in the center of the disk portion 96. The flow path of the ink recovery pipe 5b at the portion where the flow rate adjusting member 9 is disposed is only the flow path hole 94. Accordingly, the flow rate adjusting member 9 partially narrows the flow path cross-sectional area of the ink recovery pipe 5b by the flow path hole 94, thereby losing the pressure of the ink flowing in the ink recovery pipe 5b.

  The material of the flow rate adjusting member 9 is not particularly limited, and examples thereof include metals such as stainless steel, ceramics, and synthetic resins that are excellent in ink impermeability, easy to insert into the ink recovery tube 5b, and excellent in corrosion resistance against ink.

  In addition, by shortening the flow path length in the flow path hole 94 of the flow rate adjusting member 9, it is possible to suppress fluctuation in flow path resistance when bubbles enter the flow path hole 94, and to suppress variations in flow velocity. . The channel length in the channel hole 94 of the flow rate adjusting member 9 shown in FIG. 12 is, for example, about 0.5 mm. By setting the channel length in the channel hole 94 to about 0.5 mm, fluctuations in channel resistance due to bubbles can be suppressed.

  The pressure loss ΔP applied by the flow rate adjusting member 9 is a pressure loss ΔP corresponding to the difference in flow resistance between the main flow path F1 and the sub flow path F2, and is adjusted by the inner diameter of the flow path hole 94. The pressure loss ΔP balances the flow resistance of the main flow path F1 and the flow resistance of the sub flow path F2. That is, the ink pressure P0 in the ink supply pipe 5a is reduced to the pressure P1 immediately before the buffer space 6 in the main flow path F1, and becomes substantially equal to the pressure P2 immediately before the buffer space 6 in the sub flow path F2. . Further, the ink pressure P0 in the ink supply pipe 5a is substantially equal to the pressure applied by the transfer pump 105. The pressure P2 in the sub flow path F2 is set to be smaller than the pressure Px at which the meniscus break occurs so that the meniscus break from the discharge nozzle 22 does not occur.

  Needless to say, the pressure is not limited to the following cases. For example, when P0 = −2 kPa, the post-merging pressure is reduced so that P2 = −12 kPa, and P1 = −12 kPa. By providing a loss ΔP (depending on the flow path configuration, for example, 10 kPa), the flow path resistance of the main flow path F1 and the flow path resistance of the sub flow path F2 are balanced, and are equal to both the main flow path F1 and the sub flow path F2. The ink can be circulated while flowing ink. That is, [P1 = (P0−ΔP) = P2 <Px]. As a result, the ink pressure P0 in the ink supply pipe 5a allows the ink to flow evenly in both the main flow path F1 and the sub flow path F2. Here, the balance between the channel resistance of the main channel F1 and the channel resistance of the sub-channel F2 indicates that the pressure P1 and the pressure P2 are substantially equal (± 10%).

  The ink pressure P0 can be measured with a manometer at the tip of the ink supply pipe 5a provided with a T-shaped branch. The pressure P1 can be measured with a manometer at the tip of the ink recovery pipe 5b (downstream from the flow rate adjusting member 9 and upstream from the buffer space 6) where a T-shaped branch is provided. The pressure P2 can be measured by a manometer at the tip of the ink discharge pipe 5c (upstream from the buffer space 6) provided with a T-shaped branch.

  The specific inner diameter of the flow path hole 94 of the flow rate adjusting member 9 is determined so that the pressure loss of the ink recovery pipe 5b is a desired pressure loss in consideration of pressure loss due to pressure loss elements such as the individual communication path 422 and the common flow path 421. It adjusts suitably so that it may become. If the inner diameter of the flow path hole 94 of the flow rate adjusting member 9 is adjusted, ink can be made to flow evenly in both the main flow path F1 and the sub flow path F2. Accordingly, ink can be quickly stored in the ink storage chamber 41 (main flow path F1), the pressure chambers 23, the individual communication paths 422, and the common flow path 421 (sub-flow path F2). In particular, it is preferable at the initial introduction of ink.

  In addition, by adjusting the inner diameter of the flow path hole 94 of the flow rate adjusting member 9, the ink flow rate (main flow path F1) recovered from the ink recovery pipe 5b and the ink discharge through each individual communication path 422 and the common flow path 421. The flow rate of ink discharged from the tube 5c (sub-flow path F2) can be made different. For example, the flow path resistance of the flow rate adjusting member 9 is increased, and the ink discharge pipe 5c passes through the individual communication paths 422 and the common flow path 421 rather than the ink flow rate (main flow path F1) recovered from the ink recovery pipe 5b. By increasing the discharged ink flow rate (sub-flow path F2) (increasing the flow rate of the sub-flow path F2), it is possible to more easily remove bubbles that are attached around the pressure chamber 23 and are difficult to remove. Conversely, the flow resistance of the flow rate adjusting member 9 can be lowered to increase the flow rate in the main flow path F1 (increase the flow rate of the main flow path F1) than in the sub flow path F2. In this case, it is possible to easily remove bubbles adhering to the ceiling surface and corners in the main channel F1. Further, in this case, even when a damper member (MF (Manifold) damper member) located above the pressure chamber 22 is provided in the ink manifold 4, bubbles easily remaining around the damper member are easily removed. can do.

  The flow rate adjusting member 9 may be provided in the junction box 61. If the flow rate adjusting member 9 is held in the junction box 61 in advance, a desired pressure loss can be applied to the ink recovery pipe 5b only by interposing the junction box 61 to the ink recovery pipe 5b. Further, when it is desired to change or replace the flow rate adjusting member 9, the entire junction box 61 can be replaced, so that quick and easy replacement can be performed. Furthermore, even when foreign matter adheres to the vicinity of the flow rate adjusting member 9 and is contaminated, the neat state can be achieved quickly and easily by replacing the junction box 61.

  As shown in FIGS. 1 and 2, a check valve 8 may be provided in the ink discharge pipe 5 c. The check valve 8 functions to allow ink to flow out from the ink discharge chamber 412 toward the buffer space 6 and to block the ink flow in the opposite direction. For example, when the individual communication paths 422 and the common flow path 421 are clogged by contaminants contained in the ink and the pressure P2 of the sub flow path F2 decreases, the pressure P1 of the main flow path F1 in the ink storage chamber 41 decreases. A pressure difference occurs between them. In this case, the ink recovered from the ink recovery tube 5b may flow back to the ink discharge tube 5c through the buffer space 6. By providing the check valve 8 in the ink discharge pipe 5c, it is possible to prevent air bubbles and impurities from returning to the individual communication paths 422 and the common flow path 421 due to the back flow of ink.

  Since the check valve 8 is also one of the pressure loss elements, the check valve cracking pressure (valve opening pressure) should be low, and the pressure Px (for example, about 5 kPa) at which the meniscus break from the discharge nozzle 22 occurs. Need to be lower. In order to prevent meniscus breakage from the discharge nozzle 22 without fail, the ink return pipe 103 is not pressurized by the transfer pump 105 (rather than the buffer space 6 between the ink recovery pipe 5b and the discharge path 423). A suction pump may be provided (on the downstream side), and the ink may be circulated only by the negative pressure generated by the suction pump.

  As described above, the ink pressure in the ink supply pipe is P0 (see FIG. 2), the pressure in the main flow path F1 is P1, the pressure in the sub flow path F2 is P2, the pressure loss in the sub flow path F2 is ΔP, and the discharge nozzle 22 [P1 = (P0−ΔP) = P2 <Px] where Px is the pressure at which the meniscus break occurs. Here, if the pressure of the flow F3 flowing into the ink discharge chamber 412 from the discharge channel 424 is P3, it is necessary that [P3 <P2 = P1 = (P0−ΔP) <Px]. This is because if the pressure P3 of the flow F3 is larger than the pressure P2 of the sub flow path F2, the ink may flow backward from the discharge hole 31b provided in the wiring board 3 to the pressure chamber 23 side.

  In the inkjet recording apparatus 100 of the embodiment described above, ink is circulated between the inkjet head 1 and the ink tank 101, but the present invention is not limited to this. Although not shown, the ink flowing out from the ink recovery pipe 5b and the ink discharge pipe 5c may be discharged to the waste ink tank without returning to the ink tank 101. In addition, a fluid that is not ink for cooling or heating the wiring board 3 and the actuator member 2 is also circulated between the inkjet head 1 and the fluid tank. You may comprise so that the discharged | emitted fluid may be discharged to a waste fluid tank, without returning to a fluid tank.

1: Inkjet head 2: Actuator member 21: Nozzle plate 22: Discharge nozzle 23: Pressure chamber 24: Piezoelectric element 25: Pseudo pressure chamber 26: Introduction path 27: Closing member 28: Supply path 29: Common supply path 30: Individual Supply path 3: Wiring board 31a: Injection hole 31b: Discharge hole 32: Common flow path 33: Individual communication path 34: Air chamber 35: Wall surface 4: Ink manifold 41: Ink storage chamber 412: Ink discharge chamber 421: Common flow path 422: Individual communication path 423: Discharge path 424: Discharge channel 45: Partition 5a: Ink supply pipe 5b: Ink collection pipe 5c: Ink discharge pipe 6: Buffer space 61: Junction box 8: Check valve 9: Flow rate adjusting member F1: Main flow path F2: Sub flow path 100: Inkjet recording apparatus 101: Ink tank 102: Ink transfer pipe 103: In Return pipe 104: Control unit 105: transfer pump

Claims (10)

An ink storage chamber;
At least one pressure chamber communicating with the ink storage chamber via an injection hole and causing a volume variation by application of a voltage;
A discharge nozzle that communicates with the pressure chamber and discharges the ink in the pressure chamber to the outside;
A pseudo pressure chamber that is formed at a position including both adjacent positions sandwiching the pressure chamber, and capable of changing the volume by an external pressure;
An ink jet head, comprising: a supply passage that communicates with the pseudo pressure chamber and supplies a fluid into the pseudo pressure chamber.   2. The ink jet head according to claim 1, wherein the supply path includes a common supply path and an individual supply path branched from the common supply path and communicating with the pseudo pressure chamber.   The inkjet head according to claim 1, wherein the fluid is a heat medium. The fluid is the ink;
2. The ink jet head according to claim 1, wherein the supply path is an introduction path that connects the pressure chamber and the pseudo pressure chamber and guides ink in the pressure chamber into the pseudo pressure chamber. The inkjet head according to claim 1, wherein at least one of the pseudo pressure chambers is an air chamber that forms a closed space where a fluid does not flow. A wiring board in which the injection hole is formed;
An actuator member in which the pressure chamber and the pseudo pressure chamber are formed, and the volume of the pressure chamber is changed by being fed through a wiring provided in the wiring board;
A nozzle plate on which the discharge nozzle is formed;
A plurality of individual communication passages communicating with each of the pseudo pressure chambers, and a common flow path communicating with the individual communication passages, and a discharge passage for discharging the fluid in the pseudo pressure chambers,
The inkjet head according to claim 1, wherein the individual communication path is formed in the wiring board. A wiring board in which the injection hole is formed;
An actuator member in which the pressure chamber and the pseudo pressure chamber are formed, and the volume of the pressure chamber is changed by being fed through a wiring provided in the wiring board;
A nozzle plate on which the discharge nozzle is formed;
A plurality of individual communication passages communicating with each of the pseudo pressure chambers, and a common flow path communicating with the individual communication passages, and a discharge passage for discharging the fluid in the pseudo pressure chambers,
The inkjet head according to claim 1, wherein the individual communication path is formed in the actuator member. A wiring board in which the injection hole is formed;
An actuator member in which the pressure chamber and the pseudo pressure chamber are formed, and the volume of the pressure chamber is changed by being fed through a wiring provided in the wiring board;
A nozzle plate on which the discharge nozzle is formed;
A plurality of individual communication passages communicating with each of the pseudo pressure chambers, and a common flow path communicating with the individual communication passages, and a discharge passage for discharging the fluid in the pseudo pressure chambers,
The inkjet head according to claim 1, wherein the individual communication path is formed in the nozzle plate. A wiring board in which the injection hole is formed;
An actuator member in which the pressure chamber and the pseudo pressure chamber are formed, and the volume of the pressure chamber is changed by being fed through a wiring provided in the wiring board;
A nozzle plate on which the discharge nozzle is formed;
A spacer member interposed between the actuator member and the nozzle plate;
A plurality of individual communication passages communicating with each of the pseudo pressure chambers, and a common flow path communicating with the individual communication passages, and a discharge passage for discharging the fluid in the pseudo pressure chambers,
The inkjet head according to claim 1, wherein the individual communication path is formed in the spacer member. An inkjet head according to any one of claims 1 to 9,
An ink tank for storing ink transferred to the inkjet head;
An ink jet recording apparatus comprising: an ink transfer unit configured to transfer ink in the ink tank to the ink jet head.

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