JP3804610B2 - Liquid jet head - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a liquid ejecting head in which a substantial length of a nozzle row for ejecting liquid is set as long as possible.
[0002]
[Prior art]
Liquid ejecting heads that eject liquid from nozzle openings are known for various liquids, and a typical example is a recording head mounted on an ink jet recording apparatus. it can. Therefore, the prior art will be described taking the ink jet recording apparatus as an example.
[0003]
FIG. 6 shows a peripheral structure of the ink jet recording apparatus.
[0004]
The apparatus includes an ink cartridge 1 and a carriage 3 to which a recording head 2 is attached. An ink jet recording apparatus which is an apparatus main body is denoted by reference numeral 50.
[0005]
The carriage 3 is connected to a stepping motor 5 via a timing belt 4 and is guided by a guide bar 6 so as to reciprocate in the paper width direction (main scanning direction) of a recording medium 7 which is a recording paper. The carriage 3 has a box shape that opens to the top, is attached so that the nozzle forming surface of the recording head 2 is exposed on the surface (the lower surface in this example) facing the recording medium 7, and the ink cartridge 1 is mounted thereon. It has become so.
[0006]
Then, ink is supplied from the ink cartridge 1 to the recording head 2 and ink droplets are ejected onto the upper surface of the recording medium 7 while moving the carriage 3 to print images and characters on the recording medium 7 in a dot matrix. ing. The carriage 3 functions as a moving unit that reciprocally moves the recording head 2 in the main scanning direction.
[0007]
In order to guide the movement of the recording medium 7, a long guide member 8 extending in the main scanning direction of the recording head 2 is disposed. Next to one end of the guide member 8, a wiper device 9 for cleaning a nozzle plate 17 (described later) of the recording head 2 and a capping device 10 for normalizing the viscosity state of the ink in the nozzle opening are disposed. ing. A flushing box 11 is disposed next to the other end side of the guide member 8, and a flushing opening 12 is formed there.
[0008]
The waste ink sucked out by the cleaning operation by the capping device 10 and the waste ink discharged from the recording head 2 by the flushing operation to the flushing opening 12 are stored in the waste ink storage unit 13.
[0009]
The ink jet recording apparatus 50 has been described as a part of the prior art, but has a structure in which the liquid jet head of the present invention can be mounted.
[0010]
The ink ejection unit U included in the recording head 2 will be described with reference to FIGS.
[0011]
The ink ejection unit U includes a head case 14 and a flow path unit 16 that is fixed to the unit fixing surface 15 of the head case 14 with an adhesive or the like. The flow path unit 16 is configured by laminating and adhering a nozzle plate 17, a flow path forming plate 18, and a sealing plate 19 exemplified in the form of a vibration plate.
[0012]
The nozzle plate 17 is made of a stainless steel plate, and a large number of nozzle openings 20 are arranged to form two nozzle rows 21. The flow path forming plate 18 is made of a silicon single crystal plate, which is a material plate, and has a pressure generating chamber 22 that communicates with the nozzle opening 20 and a damper recess 27 that communicates with the atmosphere (not shown). It is formed by isotropic etching. An ink storage chamber 23 is formed on the unit fixing surface 15 of the head case 14 and communicates with the ink supply pipe 26, and communicates with the pressure generation chamber 22 through an ink inlet 25 opened in the sealing plate 19.
[0013]
The diaphragm 19 is formed by laminating a resin film and a stainless steel plate, and an island portion 19 </ b> A of a stainless steel plate is formed on the back surface of the portion corresponding to each pressure generating chamber 22. Reference numeral 19 </ b> C denotes a compliance portion including only a resin film having substantially the same outline as the ink storage chamber 23.
[0014]
The head case 14 is an injection-molded product of a thermosetting resin or a thermoplastic resin, and an ink supply pipe 26 that introduces ink into the ink storage chamber 23 is opened. The damper recess 27 having a shape substantially matching the shape of the ink storage chamber 23 is formed in a portion of the flow path forming plate 18 corresponding to the compliance portion 19 </ b> C of the vibration plate 19.
[0015]
Reference numeral 29 denotes a fixed substrate to which the piezoelectric vibrator 30 is fixed, and reference numeral 31 denotes a storage chamber for storing a piezoelectric vibrator unit 35 in which the piezoelectric vibrator 30 is fixed to the fixed substrate 29. The piezoelectric vibrator 30 is a piezoelectric vibrator 30 in a longitudinal vibration mode, and is adapted to expand and contract in the longitudinal direction in response to the input of a drive signal so as to give a pressure fluctuation to the pressure generating chamber 22.
[0016]
The damper recess 27 is a space formed by a diaphragm 19 that seals the lower opening of the ink storage chamber 23 and a concave portion provided in the flow path forming plate 18, and is an ink storage chamber when ink droplets are ejected. The pressure fluctuation in 23 is absorbed by the deformation of the compliance portion 19C. When the compliance portion 19C is deformed, the air in the damper recess 27 escapes to the outside through an air vent hole (not shown) to prevent a pressure increase in the damper recess 27.
[0017]
The ink ejecting unit U having the above configuration is assembled as follows, for example. That is, first, an adhesive is applied to the unit fixing surface 15 of the head case 14 so that it does not flow into the ink supply pipe 26 or the storage chamber 31, or an adhesive sheet that is punched and formed in a predetermined shape is attached. On top of this, the flow path unit 16 that has been joined and assembled in advance with an adhesive or the like is placed. Next, the flow path unit 16 and the head case 14 are fixed by heating to a temperature of about 40 to 100 ° C. and pressing as necessary.
[0018]
On the other hand, a piezoelectric vibrator unit 35 in which the piezoelectric vibrator 30 is fixed to the fixed substrate 29 is prepared, and an adhesive is applied to the tip of the piezoelectric vibrator 30. Next, the head case 14 is inverted so that the flow path unit 16 is on the lower side, and the piezoelectric vibrator unit 35 is accommodated in the accommodating chamber 31 and bonded and fixed. In this state, the tip of the piezoelectric vibrator 30 is bonded and fixed to the vibration plate 19 of the flow path unit 16, and finally the fixed substrate 29 is fixed to the head case 14, thereby completing the ink ejection unit U.
[0019]
In the ink ejection unit U, a drive signal generated by a drive circuit (not shown) is input to the piezoelectric vibrator 30 via the flexible cable 32, whereby the piezoelectric vibrator 30 is expanded and contracted in the longitudinal direction. By expanding and contracting the piezoelectric vibrator 30, the island portion 19A of the diaphragm 19 is vibrated to change the pressure in the pressure generating chamber 22, and the ink in the pressure generating chamber 22 is ejected from the nozzle opening 20 as ink droplets. It has become.
[0020]
The ink ejection unit U is attached to the head holder 33 via a contact member 34 or the like. The shape of the head holder 33 is formed in a number of irregular shapes in order to give various functions, but basically has a plate shape as shown in each drawing. A pipe-shaped ink connecting portion 36 is attached to the head holder 33. The ink connecting portion 36 functions to guide ink from an ink supply source. When the ink cartridge 1 is attached to the head holder 33, the ink connecting portion 36 becomes an ink supply needle (not shown) and is stabbed into the ink cartridge 1. It becomes a state.
[0021]
A filter 37 is disposed on the downstream side of the ink connecting portion 36 so as to capture impurities and the like in the ink and prevent them from flowing down to the ink supply pipe 26.
[0022]
Since the nozzle rows 21 are arranged in two rows as described above, the pressure generation chamber 22, the ink storage chamber 23, the piezoelectric vibrator unit 35, and the like associated therewith are also arranged in pairs.
[0023]
[Patent Document 1]
JP 2001-47622 A
[0024]
[Problems to be solved by the invention]
By the way, in order to improve the printing speed, that is, to increase the printing area per unit time, it is considered to be an effective method to increase the length of the nozzle row orthogonal to the main scanning direction of the apparatus main body. However, increasing the length of the nozzle row 21 in one ink ejecting unit U maintains the relative positions of the nozzle opening 20, the pressure generating chamber 22, the piezoelectric vibrator 30 and the like in the flow path unit 16 with high accuracy. Because there are issues such as to do, it can not be an appropriate measure.
[0025]
Therefore, as shown in FIG. 9C, it is conceivable to arrange the ink ejection units U vertically, but the nozzle rows 21 are not continuous, and a discontinuous interval L is formed. In such a problem, the structure type in which the piezoelectric vibrator unit 35 is inserted into the accommodation chamber 31 is a cause of the occurrence of the interval L.
[0026]
That is, in order to attach the piezoelectric vibrator unit 35 to an accurate position, the close contact relationship between the fixed substrate 29 and the storage chamber 31 is essential. For this purpose, the end portion of the fixed substrate 29 is brought into close contact with the three positioning walls 31X, 31Y, and 31Z of the storage chamber 31 and the stopper wall 31D arranged in the insertion direction, thereby generating pressure with the piezoelectric vibrator 30. The relative position with respect to the chamber 22 is accurately maintained. As described above, since the end of the fixed substrate 29 needs a required length to perform the positioning function, the length of the piezoelectric vibrator 30 in the nozzle row 21 direction needs to be shorter than the fixed substrate 29. . At the same time, the thickness of the head case 14 is also added, and an interval of L / 2 is formed between the unit end of the ink ejection unit U and the end of the nozzle row 21 as shown in FIG. 9B. It is.
[0027]
Therefore, as shown in FIG. 10, the ink ejection units U are arranged in a staggered manner, and the nozzle rows 21 are made continuous without the interval L as described above, thereby substantially increasing the length of the nozzle rows 21. It is known. This is because the nozzle rows 21 of each ink ejection unit U are connected in a zigzag pattern to form a long nozzle row that is continuous when viewed in the sub-scanning direction. Adjacent ink ejection units U have a length corresponding to the interval L. Overlapping sequences.
[0028]
Therefore, as shown in FIG. 10, even if a long nozzle row can be formed, the width of the ink ejection unit U is simply added, so that the size of the apparatus main body in the main scanning direction becomes extremely large. The ink jet head becomes large. In addition, the stroke length in the main scanning direction needs to be overstroked by the length of the ink ejecting head beyond the recording medium 7, and there is also a reverse aspect to downsizing the apparatus main body.
[0029]
SUMMARY An advantage of some aspects of the invention is that it provides a liquid jet head that can reduce the size of the apparatus main body in the main scanning direction as much as possible to realize a long nozzle array. .
[0030]
[Means for Solving the Problems]
In order to achieve the above object, the liquid jet head according to the present invention includes a nozzle plate in which nozzle rows are formed by arranging nozzle openings, and a flow path formed in which a pressure generation chamber communicating with the nozzle openings is formed. A liquid ejecting unit including a flow path unit formed of a laminate including a plate and a sealing plate that closes the opening of the pressure generating chamber, and the liquid ejecting unit guides liquid from a liquid supply source. A liquid ejecting head attached to a holder, wherein the flow path unit is joined to a head case to form a liquid ejecting unit, and the liquid ejecting unit includes a first nozzle row and a first nozzle row. Are arranged in a state of being substantially parallel to the second nozzle row having a short length, and the head case forms an outer shape when viewed from the nozzle plate side of the liquid ejecting unit. The overlapping shape portions formed in a state where the corner portions are notched are provided at both corner portions of the head case in the nozzle row direction on the second nozzle row side of the liquid ejecting unit. A state that is composed of a surface substantially orthogonal to the scanning direction and an inclined surface provided on the second nozzle row side in a continuous state, and at least two liquid ejecting units are opposed to the inclined surface of the overlapping shape portion. The nozzles of the second nozzle row of the other liquid ejecting unit in the direction orthogonal to the nozzle row of the nozzle opening at the end of the first nozzle row of one liquid ejecting unit in the vicinity where the inclination is opposed The unit unit is formed so that each nozzle row is a nozzle group that ejects the same kind of liquid by the first nozzle row of one liquid ejecting unit and the second nozzle row of the other liquid ejecting unit. And effect.
[0031]
That is, in the liquid ejecting unit, the first nozzle array and the second nozzle array having a length shorter than the first nozzle array are arranged in a substantially parallel state, and the head case is connected to the liquid ejecting unit. The outer shape when viewed from the nozzle plate side is formed, and the corner portions of the head case in the nozzle row direction on the second nozzle row side of the liquid ejecting unit are cut out at the corners. An overlapping shape portion is provided, and the overlapping shape portion is composed of a surface substantially orthogonal to the main scanning direction and an inclined surface provided on the second nozzle row side in a continuous state, and at least two The liquid ejecting unit is disposed in a state where the inclined surfaces of the overlapping shape portions are opposed to each other, and the nozzle row at the nozzle opening at the end of the first nozzle row of one liquid ejecting unit in the vicinity where the inclined surfaces are opposed to each other. In the orthogonal direction The nozzle opening of the second nozzle row of the one liquid ejecting unit is located, and each nozzle row ejects the same kind of liquid by the first nozzle row of one liquid ejecting unit and the second nozzle row of the other liquid ejecting unit Unit units are formed in groups.
[0032]
For this reason, by forming the unit unit with the inclined surfaces of the overlapping shape portion facing each other, the dimension in the facing direction (main scanning direction) occupied by the two liquid ejecting units corresponds to the notch of the overlapping shape portion. The size can be reduced, and the size of the liquid ejecting head including the unit unit in the main scanning direction can be reduced as much as possible. In the case where a liquid ejecting head including a plurality of unit units is configured, the dimensional reduction effect is further increased. Furthermore, each nozzle row of the two liquid ejection units forms a nozzle group that ejects the same kind of liquid, the length of the effective nozzle row is apparently elongated, and the liquid ejection to a predetermined area is performed for a short time. Is executed.
Further, since the overlapping shape portion is composed of a surface substantially orthogonal to the main scanning direction and an inclined surface provided on the second nozzle row side in a continuous state, the overlapping surface portion is formed by forming the inclined surface. The reduced amount of the liquid ejecting unit width contributed to the reduction of the total width of the two liquid ejecting units. At the same time, the surface substantially orthogonal to the main scanning direction lengthens the overlapping length of the two liquid ejecting units in the nozzle array direction, and thereby the first nozzle array of one liquid ejecting unit and the other liquid ejecting unit. Continuity in the sub-scanning direction with the second nozzle row can be ensured.
[0033]
In addition, the first nozzle row has a so-called standard performance with the most stable liquid ejection performance, while the second nozzle row has a shorter length than the first nozzle row. There is no factor that lowers the ejection performance, and the long nozzle group formed by the first and second nozzle arrays has a stable liquid ejection performance as a whole. Since different types of liquid are ejected for each nozzle group, when a predetermined number of nozzle groups are used, a wide variety of liquid ejection is possible. When the unit unit as described above is applied to an ink jet recording apparatus, the printing speed can be increased and various printing qualities can be obtained.
[0034]
In the liquid jet head of the present invention, when the width dimension of the unit unit in the main scanning direction of the apparatus main body is less than twice the unit width of one liquid jet unit, the overlapping shape of the two liquid jet units A compact liquid ejecting head in which the size of the main scanning direction is reduced while increasing the length of the nozzle row by arranging the parts facing each other, and when applied to an ink jet recording apparatus, the printing speed is high. Is realized.
[0036]
In the liquid ejecting head according to the aspect of the invention, the inclined surface may include two inclined directions when the inclination direction is set so that the dimension in the nozzle row direction decreases from the first nozzle row toward the second nozzle row. Since the inclined surface forms part of the overlapping shape portion on both sides in a so-called “tapered” state, the unit units can be arranged in the nozzle row direction, and a long nozzle group can be configured.
[0037]
In the liquid ejecting head according to the aspect of the invention, when the inclined surfaces are substantially symmetrical when viewed in the length direction of the nozzle row, an orderly arrangement can be made when the unit units are arranged in the nozzle row direction. Also, continuity with the first nozzle row and the second nozzle row of other unit units can be ensured with high accuracy.
[0038]
In the liquid jet head according to the aspect of the invention, when the first nozzle row and the second nozzle row are arranged so as to be substantially symmetric when viewed in the length direction of the nozzle row, the second of the opposing liquid jet units. The continuity in the sub-scanning direction with the nozzle row and the first nozzle row can be regularly secured.
[0039]
In the liquid ejecting head according to the aspect of the invention, the first liquid storage chamber corresponding to the first nozzle row is disposed on the opposite side to the second nozzle row when viewed from the first nozzle row, and the second liquid storage corresponding to the second nozzle row. When the chamber is arranged on the side opposite to the first nozzle row when viewed from the second nozzle row, the first nozzle row and the second nozzle row are directly adjacent to each other with a nozzle plate having a predetermined width interposed therebetween. It will be in a good state. Accordingly, the distance between the first nozzle row and the second nozzle row is minimized, and maintenance caps corresponding to both the first and second nozzle rows can be miniaturized, and the apparatus main body is compact. This is also effective.
[0040]
In the liquid jet head of the present invention, the nozzle rows of the nozzle groups adjacent to each other when viewed in the main scanning direction of the apparatus main body have an opening pitch of the nozzle row of the other nozzle group with respect to the opening pitch of the nozzle row of one nozzle group. If the amount of displacement is half the opening pitch, the nozzle rows of both nozzle groups that are shifted in the sub-scanning direction are arranged in the main scanning direction. If combined, the opening pitch becomes a substantially small opening pitch. Here, if the so-called half pitch is used in the nozzle row having a small opening pitch, the liquid ejection per unit area with respect to the member that receives the liquid ejection becomes extremely dense. On the other hand, in a nozzle array having a relatively large opening pitch, if the half pitch is used as described above, the number of strokes in the main scanning direction of the liquid ejecting head can be reduced by setting this half pitch to an integral multiple of the recording resolution. Can be reduced. These advantages are that in the ink jet recording apparatus, the former is effective in ensuring precise ejection quality, and the latter is useful in shortening the ejection time and saving power consumption.
[0041]
In the liquid jet head of the present invention, the nozzle rows of the unit units adjacent to each other when viewed in the main scanning direction of the apparatus main body have an opening pitch of the nozzle row of the other unit unit with respect to the opening pitch of the nozzle row of one unit unit. When the nozzles of both unit units in a shifted relationship are combined in the main scanning direction when the amount of deviation is half of the opening pitch, The opening pitch becomes a substantially small opening pitch. Here, if the so-called half pitch is used in the nozzle row having a small opening pitch, the liquid ejection per unit area with respect to the member that receives the liquid ejection becomes extremely dense. On the other hand, in a nozzle array having a relatively large opening pitch, if the half pitch is used as described above, the number of strokes in the main scanning direction of the liquid ejecting head can be reduced by setting this half pitch to an integral multiple of the recording resolution. Can be reduced. These advantages are that in the ink jet recording apparatus, the former is effective in ensuring precise ejection quality, and the latter is useful in shortening the ejection time and saving power consumption.
[0042]
In the liquid ejecting head according to the aspect of the invention, when a plurality of the unit units are arranged in the main scanning direction and / or a direction orthogonal thereto, the unit units are arranged in the main scanning direction, or in the main scanning direction. It is possible to arrange in a direction orthogonal to each other, or in both directions of the main scanning direction and the direction orthogonal thereto, so that it can be freely adapted to the desired liquid ejection mode and the nozzle group and the main scanning which are elongated This is realized in a liquid jet head having a width reduced in the direction.
[0043]
In the liquid ejecting head according to the aspect of the invention, when the positioning holder of the liquid ejecting unit is provided on the head holder, each liquid ejecting unit is attached to the head holder in contact with the positioning projecting portion, Unit units or nozzle groups can be formed with high accuracy, and good liquid ejection can be obtained from the elongated nozzle groups. In addition, as described above, even when the nozzle row is shifted in the sub-scanning direction to make the nozzle openings half pitch, a highly accurate opening pitch can be secured.
[0044]
In the liquid ejecting head according to the aspect of the invention, when the outer peripheral wall member for positioning the liquid ejecting unit is provided in the head holder, each liquid ejecting unit is attached to the head holder in contact with the outer peripheral wall member for positioning. Thus, the unit unit or nozzle group can be formed with high accuracy, and good liquid ejection can be obtained from the elongated nozzle group. In addition, as described above, even when the nozzle row is shifted in the sub-scanning direction to make the nozzle openings half pitch, a highly accurate opening pitch can be secured.
[0045]
In the liquid ejecting head of the present invention, the flow path unit is joined to a head case to constitute a liquid ejecting unit, and the pressure generating element that applies pressure fluctuation to the pressure generating chamber is a longitudinal vibration mode piezoelectric vibrator, When the piezoelectric vibrator is fixed to the fixed substrate, the piezoelectric vibrator and the fixed substrate are inserted into the accommodation chamber provided in the head case in a state corresponding to the pressure generation chamber, and the fixed substrate is fixed in the accommodation chamber. The longitudinal vibration mode piezoelectric vibrator itself has good response to the applied drive signal, and the longitudinal drive displacement output can be obtained, so the liquid in the pressure generation chamber is pressurized moderately. The liquid ejection from the nozzle row is reliably performed with high reliability. Since the nozzle group is made to function by the piezoelectric vibrator having such characteristics, the liquid ejection from the connected nozzle group can be satisfactorily achieved in any nozzle row. Therefore, even if ejection unevenness occurs over the entire length of the elongated nozzle group, it can be kept at a level where there is substantially no harm.
[0046]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described in detail.
[0047]
As described above, the liquid ejecting head of the present invention can function for various liquids. In the illustrated embodiment, as a typical example, a recording head employed in an ink jet recording apparatus is used. The target of the embodiment.
[0048]
The apparatus main body, that is, the ink jet recording apparatus 50 in the present embodiment is of a normal type and is the same as that shown in FIG.
[0049]
A structure of a liquid ejecting unit, that is, an ink ejecting unit, which is an important component of the liquid ejecting head of the present invention is shown in FIG. The ink ejection unit U is provided with a first nozzle row 21A and a second nozzle row 21B having a length shorter than that of the first nozzle row 21A. It corresponds to the length of 21B.
[0050]
In FIG. 1 and FIG. 2, the ink ejection unit U includes a head case 14 and a flow path unit 16 that is fixed to the unit fixing surface 15 of the head case 14 with an adhesive or the like. The flow path unit 16 is configured by laminating and adhering a nozzle plate 17, a flow path forming plate 18, and a sealing plate 19 exemplified in the form of a vibration plate. FIG. 2 is a cross-sectional view in which only a portion on the second nozzle row 21B side is broken.
[0051]
The nozzle plate 17 is made of a stainless steel plate, and a large number of nozzle openings 20 are arranged in a direction perpendicular to the paper surface of FIG. 2 to form a first nozzle row 21A and a second nozzle row 21B. The first nozzle row 21A and the second nozzle row 21B are arranged in a substantially parallel state, and are arranged so as to be substantially symmetric when viewed in the length direction of the nozzle row.
[0052]
In the following description, the number with “A” corresponds to the first nozzle row 21A, and the number with “B” corresponds to the second nozzle row 21B.
[0053]
The flow path forming plate 18 is made of a silicon single crystal plate as a material plate, and communicates with the first pressure generation chamber 22A and the second pressure generation chamber 22B communicating with the nozzle opening 20 and the atmosphere (not shown). The first damper recess 27A and the second damper recess 27B are formed by anisotropic etching. Reference numerals 23A and 23B denote first and second ink storage chambers communicating with ink supply pipes 26A and 26B formed on the unit fixing surface 15 of the head case 14, respectively. The first pressure generating chamber 22A and the second pressure generating chamber 22B communicate with each other through 25B.
[0054]
The first ink storage chamber 23A corresponding to the first nozzle row 21A is arranged on the opposite side to the second nozzle row 21B when viewed from the first nozzle row 21A, and the second ink storage chamber 23B corresponding to the second nozzle row 21B is It is arranged on the opposite side to the first nozzle row 21A when viewed from the second nozzle row 21B. That is, as shown in FIG. 3B, the first nozzle row 21A and the second nozzle row 21B are arranged between the first ink storage chamber 23A and the second ink storage chamber 23B. With the above arrangement, the first nozzle row 21A and the second nozzle row 21B are directly adjacent to each other with the nozzle plate 17 having a predetermined width interposed therebetween. Therefore, the interval between the first nozzle row 21A and the second nozzle row 21B is minimized, and the capping device 10 and the flushing opening 12 corresponding to both the first and second nozzle rows 21A and 21B are downsized. This is also effective by making the apparatus main body compact.
[0055]
The diaphragm 19 is formed by laminating a resin film and a stainless steel plate, and stainless steel island portions 19A and 19B having only a resin film as a periphery are formed on the back surface of the portion corresponding to each pressure generating chamber 22A and 22B. ing. Reference numerals 19C and 19D denote compliance portions made only of resin films having substantially the same outline as the ink storage chambers 23A and 23B.
[0056]
The head case 14 is an injection-molded product of a thermosetting resin or a thermoplastic resin, and ink supply pipes 26A and 26B for introducing ink into the first ink storage chamber 23A and the second ink storage chamber 23B on the unit fixing surface 15. Is open. In addition, the first and second damper recesses 27A and 27B having a shape substantially corresponding to the shapes of the ink storage chambers 23A and 23B are formed in portions corresponding to the first ink storage chamber 23A and the second ink storage chamber 23B. Has been.
[0057]
Reference numerals 29A and 29B denote fixed substrates to which the piezoelectric vibrators 30A and 30B are fixed. Reference numerals 31A and 31B denote accommodations for accommodating the piezoelectric vibrator units 35A and 35B in which the piezoelectric vibrators 30A and 30B are fixed to the fixed boards 29A and 29B. It is a room. The piezoelectric vibrators 30A and 30B are piezoelectric vibrators 30A and 30B in a longitudinal vibration mode, and expand and contract in the longitudinal direction in response to the input of a drive signal to cause pressure fluctuations in the first pressure generation chamber 22A and the second pressure generation chamber 22B. Is supposed to give.
[0058]
The first and second damper recesses 27A and 27B are formed by the vibration plate 19 that seals the lower openings of the first and second ink storage chambers 23A and 23B and the concave portion provided in the flow path forming plate 18. The pressure variation in the first and second ink storage chambers 23A and 23B when ink droplets are ejected is absorbed by deformation of the compliance portions 19C and 19D. When the compliance portions 19C and 19D are deformed, the air in the first and second damper recesses 27A and 27B escapes from the air vent holes (not shown) to the outside, and the first and second damper recesses 27A and 27B The pressure rise is prevented.
[0059]
The ink ejecting unit U having the above configuration is assembled as follows, for example. That is, first, an adhesive is applied to the unit fixing surface 15 of the head case 14 so that it does not flow into the ink supply pipes 26A and 26B and the storage chambers 31A and 31B, or an adhesive sheet that has been punched into a predetermined shape is pasted. The flow path unit 16 that has been assembled by being bonded with an adhesive or the like in advance is placed thereon. Next, the flow path unit 16 and the head case 14 are fixed by heating to a temperature of about 40 to 100 ° C. and pressing as necessary.
[0060]
On the other hand, piezoelectric vibrator units 35A and 35B in which the piezoelectric vibrators 30A and 30B are fixed to the fixed substrates 29A and 29B are prepared, and an adhesive is applied to the tips of the piezoelectric vibrators 30A and 30B. Next, the head case 14 is inverted so that the flow path unit 16 is on the lower side, and the piezoelectric vibrator units 35A and 35B are accommodated in the accommodating chambers 31A and 31B, respectively, and fixedly bonded. In this state, the tips of the piezoelectric vibrators 30A and 30B are bonded and fixed to the diaphragm 19 of the flow path unit 16, and finally the fixed substrates 29A and 29B are fixed to the head case 14, thereby completing the ink ejection unit U. .
[0061]
In the ink ejection unit U, a drive signal generated by a drive circuit (not shown) is input to the piezoelectric vibrators 30A and 30B via the flexible cables 32A and 32B, thereby causing the piezoelectric vibrators 30A and 30B to move in the longitudinal direction. Extend and retract. By expansion and contraction of the piezoelectric vibrators 30A and 30B, the island portions 19A and 19B of the diaphragm 19 are vibrated to change the pressures in the first and second pressure generation chambers 22A and 22B, and thereby the first and second pressure generation chambers. The ink in 22A and 22B is ejected from the nozzle opening 20 as ink droplets.
[0062]
The ink ejection unit U is attached to the head holder 33 via contact members 34A, 34B and the like. The shape of the head holder 33 is formed in a number of irregular shapes in order to give various functions, but basically has a plate shape as shown in each drawing. Pipe-shaped ink connecting portions 36 </ b> A and 36 </ b> B are attached to the head holder 33. The ink connecting portions 36A and 36B function to guide ink from an ink supply source. When the ink cartridge 1 is attached to the head holder 33, the ink connection portions 36A and 36B serve as ink supply needles (not shown) and are disposed inside the ink cartridge 1. It will be stabbed.
[0063]
Filters 37A and 37B are disposed on the downstream side of the ink connecting portions 36A and 36B so that impurities and the like in the ink are captured and do not flow down to the ink supply pipes 26A and 26B.
[0064]
The assembly order of the ink ejecting unit U is as described above, and the reference hole is utilized in the assembly. 17H is a reference hole of the nozzle plate 17, 18H is a reference hole of the flow path forming plate 18, 19H is a reference hole of the sealing plate 19, and 14H is a reference hole of the head case 14. The reference holes 17H, 18H, 19H are positioned by inserting positioning pins (not shown) when the nozzle plate 17, the flow path forming plate 18, and the sealing plate 19 are laminated to complete the flow path unit 16. Used for use. Therefore, the flow path unit 16 that maintains the assembly accuracy of the flow path unit 16 properly and has a normal ink discharge function is configured.
[0065]
Further, when the flow path unit 16 is joined to the unit fixing surface 15 of the head case 14, the reference holes 17H, 18H, 19H communicated with the flow path unit 16 and the reference hole 14H on the head case 14 side are also provided. The two are integrated using positioning pins (not shown). The nozzle plate 17, the flow path forming plate 18, the sealing plate 19, and the head case 14 are each provided with a consistent bolt hole 28, and the head (the ink ejection unit U) is connected to the head by a bolt (not shown) penetrating therethrough. The holder 33 is fixed. The reference hole 14H can also be used when the ink ejecting unit U is fixed to the head holder 33. At this time, when the reference hole 14H of the head case 14 is matched with the reference hole or reference pin (not shown) on the head holder 33 side and the positional relationship between the plurality of ink ejection units U is set normally. Can also be used.
[0066]
The outer shape of the ink ejection unit U is deformed to form an overlapping shape portion, and a plurality of ink ejection units U combined through the overlapping shape portion constitute a long nozzle row. At the same time, the installation space for the ink ejection unit U is reduced.
[0067]
The overlapping shape portion 40 is configured by deforming the outer shape of the ink ejection unit U. For this purpose, the head case 14 is mainly deformed, and the flow path unit 16 is also deformed in accordance with the deformation. Overlapping shapes 40 are formed at both corners of the head case 14 on the second nozzle row 21B side, with the corners notched. By cutting out the corners as described above, a surface 40A substantially orthogonal to the main scanning direction and an inclined surface 40B continuous therewith are formed. The inclined surfaces 40B forming the above-mentioned pairs are set with the inclination directions of both inclined surfaces 40B so that the interval dimension in the nozzle row direction decreases from the first nozzle row 21A toward the second nozzle row 21B, It is a so-called “tapered” form. Further, both inclined surfaces 40B are substantially symmetrical when viewed in the length direction of the nozzle row.
[0068]
The surface 40A is also in a paired state, and it is optimal that the surface be a flat surface. Accordingly, the head case 14 has a surface 40A and an inclined surface 40B continuous with the surface 40A arranged on both sides in the nozzle row direction to form an overlapping shape portion 40, and the inclined surface 40B is a top surface provided at the central portion of the head case 14. 40C is connected. In accordance with the arrangement of the surface 40A and the inclined surface 40B of the head case 14 as described above, as shown in FIGS. 1 and 3B, the nozzle plate 17, the flow path forming plate 18, the sealing plate 19, etc. The channel unit 16 is also cut out in the same shape.
[0069]
As described above, the second nozzle row 21B is arranged at the trapezoidal portion where the interval in the nozzle row direction is narrowed by the arrangement of the inclined surface 40B, while the interval in the nozzle row direction is kept long by the surface 40A. 21 A of 1st nozzle rows are arrange | positioned in the location.
[0070]
The “unit unit 39” is configured by arranging the two ink ejection units U with the overlapping shape portion 40 facing each other. By facing the overlapping shape portion 40, the inclined surfaces 40B of the two ink ejection units U are opposed to each other over substantially the entire surface, and the surface 40A is opposed to a half-side portion of the top surface 40C. . As described above, when the two ink ejecting units U are combined with the overlapping shape portion 40 facing each other, the first nozzle row 21A of one ink ejecting unit U and the second nozzle of the other ink ejecting unit U are combined. The row 21B has a continuous relationship in the sub-scanning direction. In this way, both nozzle rows 21A and 21B form a “nozzle group 38” that ejects the same color ink continuously.
[0071]
As described above, when the first nozzle row 21A and the second nozzle row 21B are made continuous in the unit unit 39, two continuous nozzle rows, that is, the nozzle group 38 are formed. The ink of the same color may be ejected from either of the two nozzle groups 38, or the ink of a different color may be ejected for each nozzle group 38.
[0072]
When the state of the end portions of the functionally continuous nozzle rows 21A and 21B is enlarged, there is a case as shown in FIG. That is, in order to stabilize the discharge characteristics of the nozzle openings 20 near the ends of the nozzle rows 21A and 21B, even if the nozzle openings 20 and the corresponding first and second pressure generation chambers 22A and 22B exist, One or two nozzle openings 20 indicated by black circles in the figure may not be used. Accordingly, the first nozzle row 21A and the second nozzle row 21B are spaced apart by the pitch P of the nozzle openings 20, but the nozzle rows constituted by the effective nozzle openings 20 that do not consider the nozzle openings 20 shown in the black circles. Thus, the functional continuity of the nozzle row 21 is obtained.
[0073]
Therefore, by forming the unit unit 39 in which the overlapping shape portion 40 is opposed, the size in the facing direction (main scanning direction) occupied by the two ink ejection units U is a size corresponding to the notch of the overlapping shape portion 40. The size in the main scanning direction of the ink jet head 2 including the unit unit 39 can be reduced as much as possible. When the ink jet head 2 including a plurality of the unit units 39 is configured, the dimensional reduction effect is further increased. Further, the nozzle rows 21A and 21B of the two ink ejection units U form a nozzle group 38 that ejects the same color ink, and the lengths of the effective nozzle rows 21A and 21B are apparently elongated and determined. Ink ejection to the region is executed in a short time.
[0074]
The first nozzle row 21A has a so-called standard performance with the most stable ink discharge performance, whereas the second nozzle row 21B has a shorter length than the first nozzle row 21A. The long nozzle group 38 formed by the first and second nozzle arrays 21A and 21B has a stable ink discharge performance as a whole. Since different colors of ink are ejected for each nozzle group 38, when a predetermined number of nozzle groups 38 are used, a wide variety of ink ejection is possible, and printing speed is increased and various print qualities are achieved. Can be obtained.
[0075]
The reduction in the ink ejection unit width obtained by forming the inclined surface 40B contributes to the reduction in the total width of the two ink ejection units U. At the same time, the surface 40A substantially orthogonal to the main scanning direction lengthens the overlapping length of the two ink ejecting units U in the nozzle array direction, whereby the first nozzle array 21A of one ink ejecting unit U and the other Continuity in the sub-scanning direction with the second nozzle row 21B of the ink ejection unit U can be ensured.
[0076]
Since the two inclined surfaces 40B form part of the overlapping shape portion 40 on both sides in a so-called “tapered” state, the unit units 39 can be arranged in the nozzle row direction, and a long nozzle Groups 38 can be configured. Further, by arranging the inclined surface 40B to be substantially symmetric when viewed in the length direction of the nozzle row, an orderly arrangement can be made when the unit units 39 are arranged in the nozzle row direction. Furthermore, continuity with the first nozzle row 21A and the second nozzle row 21B of the other unit units 39 can be ensured with high accuracy.
[0077]
As shown in FIG. 3D, the nozzle rows 21A and 21B of the nozzle group 38 or the unit unit 39 adjacent to each other when viewed in the main scanning direction of the apparatus main body have an opening pitch P of one first nozzle row 21A. Thus, the opening pitch P of the other second nozzle row 21B is arranged so as to be shifted in the sub-scanning direction, and the shift amount is set to a half of the opening pitch P. As described above, when the two nozzle arrays 21 that are shifted in the sub-scanning direction are combined in the main scanning direction, the opening pitch P becomes a substantially small opening pitch.
[0078]
Here, if the so-called half pitch is used in the nozzle rows 21A and 21B in which the opening pitch P is reduced, ink droplet ejection per unit area with respect to the recording medium 7 becomes extremely dense. On the other hand, if the nozzle rows 21A and 21B having a relatively large opening pitch P are set to a half pitch as described above, the half pitch is set to an integral multiple of the recording resolution, whereby the main scanning of the ink ejecting head 2 is performed. The number of strokes in the direction can be reduced. With respect to these advantages, the former is effective for ensuring precise print quality, and the latter is useful for shortening printing time and saving power consumption.
[0079]
FIG. 4 shows a second embodiment of the liquid jet head of the present invention.
[0080]
4A is a plan view seen from the nozzle plate surface side, and FIG. 4B is a plan view seen from the piezoelectric vibrator units 35A and 35B side. Four sets of unit units 39 are arranged in the main scanning direction. This is a case where three sets are arranged in a direction orthogonal to the main scanning direction. In (A), 46B is a “unit unit row” in which three sets of unit units 39 are arranged in a direction perpendicular to the main scanning direction, and black ink is ejected. Similarly, from the unit unit row 46M, Magenta, cyan unit ink is ejected from the unit unit row 46C, and yellow ink is ejected from the unit unit row 46Y. It is also possible to increase the number of unit unit rows for light magenta, light cyan, etc., for example, to 8 rows. Other than that, it is the same as that of the said embodiment, and the same code | symbol is attached | subjected to the same part.
[0081]
Therefore, the unit units 39 are arranged in the main scanning direction, arranged in a direction orthogonal to the main scanning direction (sub-scanning direction), and further in both directions of the main scanning direction and the direction orthogonal to it (sub-scanning direction). The ink jet head 2 having a long nozzle group 38 and a width reduced in the main scanning direction can be freely adapted to the desired ink discharge mode. Other than that, there exists an effect similar to the said embodiment.
[0082]
FIG. 5 shows a third embodiment of the liquid jet head of the present invention.
[0083]
FIG. 5 shows a structure for accurately attaching the ink ejection unit U to the head holder 33. 5A is an overall plan view, FIG. 5B is a [B]-[B] cross section of (A), and (C) is a [C]-[C] cross section of (A).
[0084]
A positioning outer peripheral wall member 42 is formed around the rectangular head holder 33, and the outer wall surface of the ink ejection unit U is in contact with the inner surface thereof. Accordingly, since the ink ejecting unit U is attached to the head holder 33 in contact with the positioning outer peripheral wall member 42, the relative positions of the plurality of attached ink ejecting units U are accurately set, and each ink ejecting unit U is positioned between them. The relative positions of the nozzle rows 21A and 21B can be ensured with high accuracy.
[0085]
Further, a positioning projection 43 is provided integrally with the head holder 33 on the surface of the head holder 33 on the side where the ink ejection unit U is attached. The convex portion 43 is shaped like a block, and restricts the movement of each unit U in the main scanning direction and the reference plane 44 that restricts the movement of each unit U in the direction orthogonal to the main scanning direction (sub-scanning direction). The reference surface 45 to be inclined and the inclined reference surface 47 are formed. The surface 40A and the top surface 40C of the ink ejecting unit U are in contact with the reference surface 45, and the inclined surface 40B is in contact with the reference surface 47.
[0086]
With the above configuration, the unit unit 39 or the nozzle group 38 can be formed with high accuracy, and good ink droplet ejection can be obtained from the elongated nozzle group 38. Further, as described above, even when the nozzle rows 21A and 21B of the adjacent unit units 39 are shifted in the sub-scanning direction to make the nozzle openings 20 half pitch, a highly accurate pitch P / 2 can be secured.
[0087]
Except for the configuration and operational effects described in the third embodiment, the configuration is the same as that in each of the above embodiments.
[0088]
The fourth embodiment of the liquid jet head according to the present invention relates to the arrangement of the piezoelectric vibrator 30 shown in FIGS. 1 and 2.
[0089]
In this embodiment, the pressure generating elements that give pressure fluctuations to the first and second pressure generating chambers 22A and 22B are the piezoelectric vibrators 30A and 30B in the longitudinal vibration mode, and the piezoelectric vibrators 30A and 30B are fixed substrates. The piezoelectric vibrators 30A and 30B and the fixed substrates 29A and 29B are fixed to the housing chambers 31A and 31B provided in the head case 14 so as to correspond to the first and second pressure generating chambers 22A and 22B. The fixed substrates 29A and 29B are inserted and fixed in the storage chambers 31A and 31B. Other than that, it is the same as the above embodiments, and the same reference numerals are given to the same parts.
[0090]
With the above configuration, the piezoelectric vibrators 30A and 30B themselves in the longitudinal vibration mode have good operation responsiveness to the applied drive signal, and a longitudinal drive displacement output can be obtained. The ink in the generation chambers 22A and 22B is pressurized moderately, and ink droplet ejection from the nozzle arrays 21A and 21B is reliably performed with high reliability. Since each of the ink ejection units U is caused to function by the piezoelectric vibrators 30A and 30B having such characteristics, the ink droplet ejection from the connected nozzle group 38 is satisfactorily achieved in any nozzle group 38. Therefore, even if ejection unevenness occurs over the entire length of the elongated nozzle group 38, it can be kept at a level where there is substantially no harm. Other than that, there exists an effect similar to said each embodiment.
[0091]
The above-described embodiment is intended for an ink jet recording apparatus. However, the liquid ejecting head obtained according to the present invention is not intended only for ink for an ink jet recording apparatus, but a glue, nail polish. , Conductive liquid (liquid metal) or the like can be ejected. Furthermore, in the above-described embodiment, the ink jet recording apparatus using ink that is one of the liquids has been described. However, the ink jet recording apparatus is used for manufacturing color filters such as recording heads and liquid crystal displays used in image recording apparatuses such as printers. Applicable to all liquid ejecting heads for ejecting liquid, such as color material ejecting head, organic EL display, electrode material ejecting head used for electrode formation such as FED (surface emitting display), bio-organic ejecting head used for biochip manufacturing, etc. It is also possible.
[0092]
【The invention's effect】
As described above, according to the liquid jet head of the present invention, by forming the unit unit with the overlapping shape portions facing each other, the dimensions in the facing direction (main scanning direction) occupied by the two liquid jet units are as follows: The size corresponding to the notch of the overlapping shape portion is reduced, and the size of the liquid jet head including the unit unit in the main scanning direction can be reduced as much as possible. In the case where a liquid ejecting head including a plurality of unit units is configured, the dimensional reduction effect is further increased. Furthermore, each nozzle row of the two liquid ejection units forms a nozzle group that ejects the same kind of liquid, the length of the effective nozzle row is apparently elongated, and the liquid ejection to a predetermined area is performed for a short time. Is executed.
[0093]
In addition, the first nozzle row has a so-called standard performance with the most stable liquid ejection performance, while the second nozzle row has a shorter length than the first nozzle row. There is no factor that lowers the ejection performance, and the long nozzle group formed by the first and second nozzle arrays has a stable liquid ejection performance as a whole. Since different types of liquid are ejected for each nozzle group, when a predetermined number of nozzle groups are used, a wide variety of liquid ejection is possible. When the unit unit as described above is applied to an ink jet recording apparatus, the printing speed can be increased and various printing qualities can be obtained.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view illustrating a liquid jet head according to an embodiment of the present invention.
2 is a cross-sectional view of FIG.
3A is a plan view of a unit unit, FIG. 3A is a plan view seen from the piezoelectric vibrator unit side, and FIG. 3B is a plan view seen from the nozzle plate side.
4A and 4B are diagrams illustrating a state in which a unit unit is attached to a head holder, where FIG. 4A is a plan view seen from the piezoelectric vibrator unit side, and FIG. 4B is a plan view seen from the nozzle plate side.
FIG. 5 is a plan view showing a state in which each ink ejecting unit is attached to a head holder.
FIG. 6 is a perspective view of an ink jet recording apparatus to which the present invention is applied.
FIG. 7 is an exploded perspective view showing a conventional ink jet head.
8 is a cross-sectional view of FIG.
9A is a plan view showing a part of the head case in a cutaway state, FIG. 9B is a plan view of the head case viewed from the nozzle plate side, and FIG. 9C is a state in which the ink ejection units are arranged; FIG.
FIG. 10 is a plan view showing a state in which a plurality of ink ejecting units are assembled to a head holder.
[Explanation of symbols]
1 Ink cartridge
2 Recording head, ink jet head
3 Carriage
4 Timing belt
5 Stepping motor
6 Guide bar
7 Recording media
8 Guide members
9 Wiper device
10 Capping device
11 Flushing box
12 Flushing opening
13 Waste ink reservoir
14 Head case
14H reference hole
15 Unit fixing surface
16 Channel unit
17 Nozzle plate
17H Reference hole
18 Flow path forming plate
18H reference hole
19 Sealing plate, diaphragm
19A island
19B Shimabe
19C Compliance Department
19D Compliance Department
19H Reference hole
20 Nozzle opening
21 Nozzle row
21A First nozzle row
21B Second nozzle row
22 Pressure generation chamber
22A First pressure generation chamber
22B Second pressure generation chamber
23 Ink storage chamber
23A First ink storage chamber
23B Second ink storage chamber
25 Ink inlet
25A ink inlet
25B Ink inlet
26 Ink supply pipe
26A ink supply pipe
26B ink supply pipe
27 Recess for damper
27A First damper recess
27B Concave for second damper
28 Bolt hole
29 Fixed substrate
29A fixed board
29B Fixed substrate
30 Piezoelectric vibrator
30A Piezoelectric vibrator
30B Piezoelectric vibrator
31 containment room
31A containment room
31B containment room
31X inner wall
31Y inner wall
31Z inner wall
31D Stopper wall
32 Flexible cable
32A flexible cable
32B flexible cable
33 Head holder
34 Joint members
34A Joint member
34B Joint member
35 Piezoelectric vibrator unit
35A Piezoelectric vibrator unit
35B Piezoelectric vibrator unit
36 Ink connection
36A Ink connection
36B Ink connection
37 Filter
37A filter
37B filter
38 nozzle group
39 units
40 Overlapping shape part
40A side
40B inclined surface
40C Top surface
42. Outer wall member for positioning
43 Convex part for positioning
44 Reference plane
45 Reference plane
46B unit unit row
46M unit unit row
46C unit unit row
46Y unit unit row
47 Reference plane
50 Inkjet recording device
U Ink jet unit
L interval
P Nozzle opening pitch

Claims (12)

A nozzle plate in which nozzle rows are formed by arranging nozzle openings, a flow path forming plate in which a pressure generation chamber communicating with the nozzle openings is formed, and a sealing plate for closing the openings of the pressure generation chambers A liquid ejecting unit including a flow path unit formed from a laminate including the liquid ejecting unit, wherein the liquid ejecting unit is attached to a head holder that guides liquid from a liquid supply source. A path unit is joined to the head case to form a liquid ejecting unit, and in the liquid ejecting unit, a first nozzle array and a second nozzle array having a length shorter than the first nozzle array are substantially parallel. And the head case forms an outer shape when viewed from the nozzle plate side of the liquid ejecting unit, and the nozzle row on the second nozzle row side of the liquid ejecting unit The two corners of the head case countercurrent, overlapping shape portion is provided which is formed is cut away corners,
The overlapping shape portion is composed of a surface substantially orthogonal to the main scanning direction and an inclined surface provided on the second nozzle row side in a continuous state thereto,
At least two liquid ejecting units are arranged in a state where the inclined surfaces of the overlapping shape portions are opposed to each other, and the nozzle openings at the end of the first nozzle row of one liquid ejecting unit in the vicinity where the inclined surfaces are opposed to each other. Nozzle openings of the second nozzle row of the other liquid ejecting unit are positioned in a direction orthogonal to the nozzle row, and the same kind of each nozzle row is provided by the first nozzle row of one liquid ejecting unit and the second nozzle row of the other liquid ejecting unit. A liquid ejecting head characterized in that a unit unit is formed so as to form a nozzle group for ejecting the liquid. The liquid ejecting head according to claim 1, wherein a width dimension of the unit unit in the main scanning direction of the apparatus main body is less than twice a unit width of one liquid ejecting unit. The liquid ejecting head according to claim 2, wherein the inclined surface has an inclined direction set such that a dimension in the nozzle row direction decreases from the first nozzle row toward the second nozzle row.   The liquid ejecting head according to claim 3, wherein the inclined surface is substantially symmetric when viewed in the length direction of the nozzle row.   5. The liquid ejecting head according to claim 1, wherein the first nozzle row and the second nozzle row are arranged so as to be substantially symmetric when viewed in the length direction of the nozzle row.   The first liquid storage chamber corresponding to the first nozzle row is disposed on the opposite side to the second nozzle row when viewed from the first nozzle row, and the second liquid storage chamber corresponding to the second nozzle row is viewed from the second nozzle row. The liquid ejecting head according to claim 1, wherein the liquid ejecting head is disposed on a side opposite to the first nozzle row.   The nozzle rows of adjacent nozzle groups as viewed in the main scanning direction of the apparatus main body are arranged such that the opening pitch of the nozzle row of the other nozzle group is shifted in the sub-scanning direction with respect to the opening pitch of the nozzle row of one nozzle group. The liquid ejecting head according to claim 1, wherein the shift amount is a half of the opening pitch.   The nozzle rows of the unit units adjacent to each other in the main scanning direction of the apparatus main body are arranged such that the opening pitch of the nozzle row of the other unit unit is shifted in the sub-scanning direction with respect to the opening pitch of the nozzle row of one unit unit. The liquid ejecting head according to claim 1, wherein the shift amount is a half of the opening pitch.   The liquid ejecting head according to claim 1, wherein a plurality of the unit units are arranged in at least one of a main scanning direction and a direction orthogonal to the main scanning direction.   The liquid ejecting head according to claim 1, wherein the head holder is provided with a positioning projection for the liquid ejecting unit.   The liquid ejecting head according to claim 1, wherein the head holder is provided with a positioning outer peripheral wall member for the liquid ejecting unit.   The flow path unit is joined to the head case to form a liquid ejecting unit, and a pressure generating element that applies pressure fluctuation to the pressure generating chamber is a longitudinal vibration mode piezoelectric vibrator, and the piezoelectric vibrator is attached to a fixed substrate. The piezoelectric vibrator and a fixed substrate are inserted into a storage chamber provided in the head case so as to correspond to the pressure generation chamber, and the fixed substrate is fixed in the storage chamber. The liquid jet head according to Item.

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