[0001] The present invention relates to an ink jet type recording head and an ink jet printer.
In such an ink jet type recording head a piezoelectric vibrator or other pressure
generating means is provided in a region of a pressure generating chamber communicating
with a nozzle opening. Ink drops are generated when the pressure generating chamber
is compressed by the deflection vibration of the piezoelectric vibrator or other pressure
generating means.
[0002] In order to conduct printing at high speed and high density, it would be desirable
to increase the number of nozzle openings per recording head. In an ink jet type recording
head, since liquid such as ink is treated in the nozzle openings, the pressure generating
chamber, etc., it is necessary to manufacture the nozzle openings and ink passages
of the recording head with high accuracy and with great uniformly. In an ink jet type
recording, a liquid ink drop is projected toward and deposited on a recording medium.
The amount of dispersion of the ink droplet is easily influenced by variations in
the accuracy of the pressure generating chamber. Furthermore, a curvature in the trajectory
of the ink droplet may result from inaccuracies in the nozzle openings.
[0003] When even one of the nozzle openings or passages is out of alignment, the printing
quality of the recording head markedly deteriorates, and the recording head becomes
useless. Therefore, the manufacturing yield for ink jet type recording heads is much
lower than the yield for wire-impact type recording heads or thermal transfer type
recording heads.
[0004] In order to solve the above problems, it is possible to construct a recording head
as follows. The recording head itself is made in such a manner that the number of
nozzle openings is relatively small. The thus formed recording head is then used as
a unit together with additional units, and the plurality of units are formed into
one body and fixed onto a base board piece, to produce one recording head. However,
the following problems may be encountered in the above recording head. The width of
the side walls of adjacent units is larger than the pitch of the arrangement of nozzle
openings. Accordingly, it is necessary to arrange the units in a zigzag pattern by
shifting every other unit laterally by a distance corresponding to the width of one
unit. As a result, the width of the recording head becomes, at a minimum, twice as
great as that of an individual unit.
[0005] In the prior art, document EP 0 659 562 A2 discloses an ink jet recording head according
to the preamble of claim 1, the head comprising a head unit having a plurality of
pressure generating means and pressure generating chambers and a flow passage unit
with a base board comprising a U-shaped reservoir wherein the arms of the U sandwich
said nozzle communication holes (see Figure 5 of this document).
[0006] Document EP 0 512 799 A2 discloses the arrangement of a plurality of ink jet type
recording heads arranged on a common bar (see Figure 6) having a common ink supply
passage for supplying ink to each respective recording head through communication
ports.
[0007] The present invention has been accomplished in view of the above problems. It is
therefore an object of the present invention to provide an ink jet recording head
composed of a plurality of individual units in which the number of nozzles per recording
head can be increased without significantly increasing the width of the recording
head overall.
[0008] This object is solved by an ink jet type recording head according to independent
claim 1 and an ink jet printer according to claim 15. Further advantageous features,
aspects and details of the invention are evident from the dependent claims, the description
and the drawings. The invention provides an ink jet type recording head having head
units with angled walls and angled pressure generating chambers.
[0009] In order to solve the above problems, the present invention according to a preferred
aspect provides an ink jet type recording head comprising a plurality of head units,
each said head unit comprising a plurality of pressure generating means and a plurality
of pressure generating chambers for pressurizing ink through actuation of said pressure
generating means. The plurality of head units house said plurality of pressure generating
chambers.
[0010] Furthermore, a flow passage unit includes a base board on which said head units are
arranged, and a nozzle plate includes nozzle opening lines.
[0011] On the base board there are provided reservoirs and nozzle communication holes for
feeding ink in accordance with the actuator units to nozzle openings which are provided
in nozzle opening lines of a nozzle plate underlying the base board. The reservoirs
are U shaped and arranged such that the arms of each U sandwich the lines of the nozzle
communication holes. The pressure generating chambers are preferably arranged in line
in an arrangement direction, and each chamber is preferably inclined at an angle θ
with respect to the arrangement direction. Outer edges of the head units in the arrangement
direction are preferably also inclined by an angle θ with respect to the arrangement
direction of the pressure generating chambers. The head units are advantageously arranged
in a pattern such that each unit is shifted along the inclination of an adjacent unit
away from a midline position of the adjacent unit. The arrangement of units according
to a further preferred aspect is then fixed onto a base board so that the pitch between
the pressure generating chambers opposing the outer edges in the arrangement direction
of the pressure chambers is the same as that between the pressure generating chambers
on the individual head units themselves.
[0012] In the above arrangement, it can be advisable that opposing outer walls of adjacent
head units are also inclined with respect to a straight line perpendicular to the
arrangement direction of the pressure generating chambers. Accordingly, when the head
units are shifted along the incline of the outer walls, a distance between adjacent
head units in the arrangement direction of the pressure generating chambers is changed.
Accordingly, an interval between the pressure generating chambers of respective adjacent
units can be changed in the arrangement direction of the pressure generating chambers
in accordance with the amount of shift between the adjacent units. Due to the'foregoing,
the head units need not be staggered in a full zigzag pattern, and the width of the
recording head can be reduced. Therefore, the increase in the width of the recording
head is minimal in light of the large number of head units arranged on the recording
head.
[0013] In a further aspect of the invention an ink jet printer is provided which comprises
an ink jet type recording head according to the above description.
Fig. 1 is a cross-sectional view of a first embodiment of an ink jet type recording
head according to the present invention, wherein the view shows a portion close to
a pressure generating chamber.
Fig. 2 is a perspective view showing an assembly process for the head unit shown in
Fig. 1.
Fig. 3 is a front view of an example of a spacer used in the head unit.
Fig. 4 is an enlarged front view of an end portion of the spacer.
Fig. 5 is a front view of an example of a nozzle plate used as a base board, on which
the head units are mounted.
Fig. 6 is a front view showing a positional relation between two head units which
have been arranged adjacent each other so as to provide a recording head.
Fig. 7 is a perspective view showing an ink jet type recording head according to the
present invention.
Fig. 8(a) is a view showing another example of the head unit arrangement according
to the present invention, and Fig. 8(b) is a view showing another example of the nozzle
opening arrangement according to the present invention.
Fig. 9 is a cross-sectional view of another embodiment of the recording head according
to the invention, wherein the view shows a portion close to the pressure generating
chamber.
Fig. 10 is a perspective view showing an assembly process for an actuator according
to the present invention, suitable for the recording head of Fig. 9.
Fig. 11 is an exploded perspective view showing an example of a flow passage unit
suitable for constructing a recording head having an actuator unit of the type shown
in Fig. 10.
Fig. 12 shows another embodiment of a pressure generating means applicable to the
present invention.
Fig. 13 is a view showing a further embodiment of the pressure generating means applicable
to the present invention.
Fig. 14 shows yet another embodiment of the pressure generating means applicable to
the present invention.
Fig. 15 is a view showing another embodiment of the pressure generating means applicable
to the present invention.
[0014] Referring to various embodiments illustrated in the accompanying drawings, the present
invention will now be explained in detail.
[0015] Fig. 1 illustrates a first embodiment of a recording head according to the present
invention. Fig. 2 is a view showing an example of one head unit provided in the recording
head. In the drawing, reference numeral 1 designates a spacer. The spacer is preferably
composed of a base board made of ceramics such as zirconia (ZrO
2). The thickness of the spacer 1 should be appropriate for forming pressure generating
chambers 2, 3, the depth of which is preferably approximately 150 µm. As shown in
Pigs. 3 and 4, the pressure generating chambers 2, 3 provided in the base board 1
are arranged in such a manner that a longitudinal axial line of each pressure generating
chamber forms an acute angle θ with respect to the arrangement direction of the nozzle
openings 4, 5. The acute angle θ is preferably set to be greater than 45 degrees and
less than 90 degrees (i.e. 45° < θ < 90°). An illustrative longitudinal axial line
is shown in Fig. 3 at D - D, while the arrangement direction is illustrated by arrangement
lines A - A and B - B.
[0016] Outer walls 1a, 1b, forming an outer periphery of the spacer 1 near the pressure
generating chambers 2a, 2b, 3a, 3b, located adjoining to these walls are approximately
parallel to the axial lines of the pressure generating chambers 2, 3. Also, the remaining
outer walls 1c, 1d, which are located on the right and left in Fig. 3, are approximately
parallel to the arrangement lines A - A and B - B of the nozzle openings. The outer
walls 1a, 1b are constructed so that the end widths W1, W2 are reduced as much as
possible.
[0017] When the pressure generating chambers 2, 3 are arranged to be inclined so that the
axial direction of the pressure generating chambers 2, 3 forms an acute angle θ with
respect to the nozzle opening arrangement lines A - A and B - B, the lengths of the
pressure generating chambers 2, 3 can be increased so that they are longer than comparable,
conventional pressure generating chambers that are arranged perpendicularly to the
nozzle opening arrangement lines A - A and B - B. Due to the foregoing, even when
the width of the recording head must be reduced, e.g., to increase recording head
density, it is nonetheless possible to ensure that each pressure generating chamber
has a sufficiently large ink capacity.
[0018] Referring again to Figs. 1 and 2, reference numeral 6 designates a diaphragm, which
preferably is composed of a sheet of zirconia and has a thickness of, e.g., 10 µm.
Therefore, when the diaphragm 6 is baked integrally with the spacer 1, a sufficiently
high joining force can be achieved. If the diaphragm is composed of a sheet of zirconia,
just like the spacer 1 is, it can be elastically deformed when piezoelectric vibrators
7, 8 are actuated.
[0019] Reference numerals 7, 8, designate the piezoelectric vibrators mentioned above. The
piezoelectric vibrators 7, 8 are preferably made by sintering a green sheet of piezoelectric
material onto a surface of drive electrodes 9, 10 formed on a surface of the diaphragm
6.
[0020] In Figs. 1-2, a cover sheet, indicated at 12, is integrally adhered onto the other
surface of the spacer 1. In this example, the cover sheet 12 is preferably made of
a sheet of zirconia, the thickness of which is, e.g., 150 µm. On the cover sheet 12,
through-holes 13, 14 connect the nozzle openings 4, 5 of the nozzle plate 28 with
the pressure generating chambers 2, 3. In addition, through-holes 17, 18 connect reservoirs
15, 16 with the pressure generating chambers 2, 3.
[0021] Reference numeral 19 indicates an ink feed passage composing sheet, which is preferably
made of a sheet member, such as a stainless steel sheet having the anticorrosion property,
and which has a thickness of e.g. 150 µm or so. On the ink feed passage composing
sheet 19, there are formed both through-holes which function as reservoirs 15, 16,
and through-holes 20, 21 to connect the pressure generating chambers 2, 3 with the
nozzle openings 4, 5.
[0022] The reservoirs 15, 16 are respectively connected with ink feed ports 22, 23 formed
on the cover sheet 12. Therefore, the reservoirs 15, 16 receive ink from an ink tank
arranged outside the recording head and feed it to the pressure generating chambers
2, 3 via the through-holes 17, 18.
[0023] As described above, the recording head includes members 1, 6, 12 and 19. Of these
members, the members 1, 6 and 12 are preferably made of ceramics such that they can
be integrated into one body by means of baking. The member 19 is advantageously made
of metal and is joined to the ceramic elements by an appropriate conventional method.
In this way, these members are incorporated into a head unit 40.
[0024] As illustrated, e.g., in Figs. 3-5, holes 30, 31, used for positioning, are provided
substantially on a center line between the pressure generating chambers 2, 3. Due
to the presence of the positioning holes 30, 31, even if the entire head unit contracts
in the process of baking, the head unit can be correctly positioned at a reference
position.
[0025] Figs. 1, 5 and 7 show a nozzle plate at reference numeral 28. In the present embodiment,
the nozzle plate 28 also functions as a fixing base board-of the head unit. On the
nozzle plate 28, two sets of nozzle openings 4, 5 and 4', 5' are provided. An interval
between the nozzle openings 4 and 5 is set to a constant value L; likewise, an interval
between the nozzle openings 4' and 5' is set to a constant value L. Finally, the nozzle
openings 4' are shifted over from the nozzle openings 4 by a distance ΔL in the scanning
direction, and the nozzle openings 5' are shifted from the nozzle openings 5 by the
same distance ΔL in the scanning direction.
[0026] In this case, the shift distance ΔL is determined so that the head units 40, 41 do
not overlap each other when they are fixed as shown in Fig. 5. Also, the shift distance
ΔL is set so that the pitch of the nozzle openings in the paper feed direction is
a constant value P0 even in a region where the units 40 and 41 oppose each other.
In other words, the shift distance ΔL is determined so that the pitch of nozzle openings
4-1, 5-1 in particular, relative to the nozzle openings 4'-1, 5'-1, is the same as
the pitch of the nozzle openings in other regions. More specifically, the shift amount
ΔL is preferably no more than 80% of the distance from the outer wall 1c to the outer
wall 1d.
[0027] In the head unit constructed as described above, as shown in Figs. 6 and 7, the first
head unit 40 and the second head unit 41 are shifted relative to each other by a lateral
distance ΔL so that an interval P1 between the lowermost nozzle opening of the first
head unit 40 and the uppermost nozzle opening of the second head unit 41 is the same
as the pitch P0 for the sets of nozzle openings 4, 5 and 4', 5'. When necessary, a
gap ΔG can be provided in the boundary; to produce the desired identity in pitch P1
and P0. The first and the second head unit are then fixed onto the nozzle plate 28.
[0028] In this case, the lower outer wall 1b of the first head unit 40 and the upper outer
wall 1a of the second head unit 41 are respectively inclined by an angle θ with respect
to the arrangement lines A-A and B-B. Also, the first and the second head unit are
disposed slightly offset but still adjacent to each other in the upward and downward
direction. Accordingly, it is possible to make the pitch P1 in the boundary coincide
with the pitch P0 in the scanning direction by a shift distance ΔL which is shorter
than the width of an entire unit (40, 41).
[0029] Reference numerals 42 to 45 in Fig. 7 designate ink feed pipes to feed ink from the
ink tank to the reservoirs 15, 16. When printing signals are sent to the first head
unit 40 and the second head unit 41, they are sent in timed relation so that the signal
for the latter unit is shifted by a period of time corresponding to the number of
dots which corresponds to the interval ΔL. When this is done, the recording head constructed
as described above can conduct printing in the same manner as can a recording head
in which nozzle openings are formed along the same straight line.
[0030] In the above example, the recording head is composed of two head units. However,
three or more head units 50, 50, constructed as those described above, may be arranged
in a column, as shown in Fig. 8. Alternatively, a plurality of columns may be arranged.
[0031] As shown in Fig. 8, when a large number of head units are arranged, in one column
of width ΔL', e.g., when 30 head units are arranged with a shift ΔL (as shown in Fig.
5) formed between the head units forming the respective columns, a shift ΔL' results
between an upper end and a lower end of the column of head units. Due to the foregoing,
a triangular dead space is formed.
[0032] In this example, on both sides of the center line C with respect to the upward and
downward direction, the head units 54, 55 are arranged in the same manner as described
above. That is, one head unit extends downward with respect to the center line C,
and the other head unit extends upward with respect to the center line C. The nozzle
openings 51, 52 are located on a line of the nozzle openings 53 formed by the head
unit 50 in the moving direction of the recording head.
[0033] Due to the foregoing construction, it is possible to conduct color printing in a
wide region as follows even when the carriage conducts only one scanning operation.
Inks of different colors, such as cyan, magenta and yellow inks, are respectively
jetted out from two lines of nozzles which are continuously formed substantially linearly.
Also, black ink is jetted out from two lines of nozzle openings which are divided
to the right and left.
[0034] Due to the foregoing construction, as shown in Fig. 8(b), it is possible to arrange
a large number of head units in line without changing the number of lines of nozzle
openings. Also, the dead space is effectively utilized and the width of the recording
head is not increased. In this connection, even in the recording head in which one
line of nozzle openings is divided into two in the width direction, when the printing
time is adjusted, it is possible to form dots in accordance with the printing position
of the continuously formed nozzle opening line.
[0035] In the above example, the recording head is constructed as follows. One surface of
the actuator unit 1, that is, a surface opposite to the surface onto which the diaphragm
6 is fixed, is open, and this surface is sealed by a flow passage forming plate 12.
When the actuator unit 1 and the flow passage unit 12 are joined into one body in
this way and arranged on the nozzle forming base board 28 in a predetermined manner,
the recording head is completed.
[0036] However, it is also possible to construct a recording head as follows. As shown in
Figs. 9 and 10, one surface of the spacer 1 is sealed with the diaphragm 6 having
piezoelectric vibrators 7, 8. The other surface of the spacer 1 is sealed with the
cover member 60 having ink feed ports 61, 62 and nozzle communicating holes 63, 64,
to thereby construct the actuator unit 65. This actuator unit 65 is fixed in the common
flow passage unit 85, which also functions as a fixing base board. According to the
above construction, it is possible to provide the same effect and benefits achieved
by the previous embodiment.
[0037] As shown in Fig. 11, a plurality of stages of nozzle opening lines, in this example,
two stages of nozzle opening lines, are provided. Each stage of nozzle opening lines
is composed of two lines of nozzle openings 70, 71, 70', 71' communicating with the
actuator units 65, 65'. A plurality of sets of nozzle opening lines 70, 71, 70', 71',
in this example, 3 sets of nozzle opening lines 70, 71, 70', 71', are provided in
the paper width direction. As explained before with reference to Fig. 5, a relation
between the nozzle opening lines 70, 71 and the nozzle opening lines 70', 71', arranged
in the paper feed direction, is determined as follows. In the boundary region where
the upper and the lower nozzle opening line oppose each other, one head unit and the
other head unit are shifted relative to each other so that an interval between the
lowermost nozzle opening of the nozzle opening lines 70, 71 and the uppermost nozzle
opening of the nozzle opening lines 70', 71' is the same as the pitch for each set
of nozzle openings. The nozzle plate 72 results.
[0038] On a reservoir-forming base board 73, cooperating with the nozzle plate 72, there
are provided reservoirs 74, 74' and nozzle communicating holes 75, 76, 75', 76' for
feeding ink in accordance with the actuator units 65, 65'. A cover member 77 seals
the other surface of the reservoir forming base board 73, and is provided with nozzle
communicating holes 78, 79, 78', 79' and ink feed ports 80, 81, 80', 81' in the same
manner. When they are laminated, the flow passage unit 85 is constructed.
[0039] The actuator units 65, 65' are positioned in accordance with the nozzle communicating
holes 75, 76, 75', 76' and the ink feed ports 80, 81, 80', 81' of the flow passage
unit 85, and the ink feed ports 86, 86' communicating with the reservoirs 74, 74'.
When the flow passage unit 85 and units 65, 65' are integrally fixed into the holder
88 by means of windows 87, the recording head is constructed. In this connection,
reference numerals 89, 90, 89', 90' are recess portions formed at positions opposed
to the reservoirs 74, 74', for the purpose of forming thin portions so that a compliance
can be given to the reservoirs 74, 74'.
[0040] In the above example, two lines of nozzle openings are provided in the head unit.
However, the present invention can be applied to a head unit in which only a single
line or three or more lines of nozzle openings are provided.
[0041] In the above example, the pressure generating means includes a piezoelectric vibrator
which performs deflection vibrations. However, it should be noted that the present
invention is not limited to the above pressure generating means, and various other
types of pressure generating means may be adopted.
[0042] In the variant shown in Fig. 12, the diaphragm 6 for sealing the pressure generating
chamber 2 is composed of a piezoelectric vibrating layer 101 formed as one piece,
and the common electrode 100 is formed on the lower surface of the piezoelectric vibrating
layer 101 over the entire region, or at least in regions opposing the pressure generating
chamber 2. The individual electrodes 102 are respectively formed in regions opposing
each pressure chamber 2 on the upper surface of the layer 101. Then, drive signals
are selectively imparted to the common electrode 100 and the individual electrodes
102 on the piezoelectric layer 101 facing the various pressure generating chambers
2, to jet out ink drops by means of the resulting deflection displacement.
[0043] The above piezoelectric vibrating layer 101 can be easily made by a method appropriate
for forming piezoelectric material into a sheet of film. Examples of usable methods
are described below. For instance, piezoelectric material is baked to product a sheet.
Alternatively piezoelectric material may be spattered onto a surface of conductive
material, such as a metal sheet, to be used as a common electrode 100. According to
yet another alternative, piezoelectric material may be placed onto a surface of conductive
material by a hydrothermal method.
[0044] Also, it is possible to adopt the following construction. As shown in Fig. 13, the
diaphragm 6 is formed as a common electrode 103 made of a metal sheet having both
conductivity and elasticity. On the pressure generating chamber side 2 of this common
electrode 103, a piezoelectric vibrator 104 and an individual electrode 105 corresponding
to each pressure generating chamber 2 are mounted. If necessary, a sheet of material
capable of being elastically deformed, for example, a sheet of zirconia may be laminated
onto a surface of the common electrode 103.
[0045] Yet another possible construction is illustrated in Fig. 14. As shown there, a Joule
heat generating element 107 is provided on a surface of the diaphragm 6 to seal the
spacer 1 on the pressure generating chamber 2 side. Alternatively, the element 107
may be provided on a surface of another member to define the pressure generating chamber
2 on the pressure generating chamber side. When necessary, an ink protective layer
108 can be formed on the Joule heat generating element 107. When the Joule heat generating
element 107 is heated by application of a drive signal, the ink accommodated in the
pressure generating chamber is vaporized so as to generate pressure.
[0046] Also, it is possible to adopt the following construction. As shown in Fig. 15, piezoelectric
vibrators 110, 110 having a longitudinal vibration mode are fixed to the base board
111 so that front ends of piezoelectric vibrators contact the diaphragm 6. Due to
the above construction, when the piezoelectric vibrators 110, 110 are linearly displaced,
the pressure generating chambers 2, 3 expand and contract accordingly.
[0047] As explained above, according to a preferred aspect of the present invention, a plurality
of pressure generating chambers in which ink is pressurized by pressure generating
means are arranged in a column. The individual pressure generating chambers are inclined
at an angle θ with respect to the arrangement direction of the pressure chambers.
Furthermore, an end surface of the head unit in the arrangement direction of the pressure
chambers is inclined by the same angle θ with respect to the arrangement direction
of the pressure chambers. To provide a recording head, a plurality of head units are
fixed onto a base board in such a manner that they are shifted along the inclination.
As a result, the pitch between the last pressure generating chamber on one unit and
the first pressure generating chamber on the adjacent unit in the arrangement direction
can be made to equal the pitch between the pressure generating chambers on the individual
units. Accordingly, by moving the head unit laterally along the outer wall of the
adjacent head unit, a pitch distance in the arrangement direction of the pressure
generating chamber can be adjusted to achieve this equality. As a result, it is possible
to arrange a plurality of head units without unduly increasing the width of the recording
head.
[0048] Since the pressure generating chambers are inclined with respect to a direction perpendicular
to the arrangement line of the nozzle openings, the length of the pressure generating
chambers can be increased in relation to comparable pressure generating chambers that
are arranged on a line perpendicular to the arrangement line of the nozzle openings.
Therefore, it is possible to enhance the density of the pressure chamber arrangement
without reducing the volume of individual chambers.
1. An ink jet type recording head comprising:
a head unit (40, 41) comprising a plurality of pressure generating means (7, 8, 65,
65'), and a plurality of pressure generating chambers (2, 3) for pressurizing ink
through actuation of said pressure generating means (7, 8), said head unit (40, 41)
housing said plurality of pressure generating chambers (2, 3);
a flow passage unit (85) including a base board (73) on which said head unit is arranged;
and
a nozzle plate (72) including a plurality of nozzle openings (4,5) arranged in nozzle
opening lines (70, 71);
wherein the base board (73) comprises a reservoir (74, 74') and a plurality of nozzle
communication holes (75, 76, 75', 76'); and
wherein each nozzle communication hole (75, 76, 75', 76') is associated with a respective
pressure generating chamber (2, 3) for feeding ink from said pressure generating chamber
to a respective nozzle opening (4, 5);
characterized in that
a plurality of head units (40, 41) is provided on a single flow passage unit, wherein
said base board (73) is formed as a common board providing a plurality of reservoirs
(74, 74'); and
an amount of shift (ΔL) along the direction of extension of outer edges (1a,1b) between
each said head unit (40) and said adjacent head unit (41) is set such that a pitch
(P1) between first opposing ones of said pressure generating chambers that oppose
each other across the outer edges (1a,1b) of said head unit (40) and said adjacent
head unit (41) is equal to a pitch (P0) between second opposing one of said pressure
generating chambers that oppose each other on said head unit (40).
2. The ink jet type recording head according to Claim 1, wherein said reservoir (74,
74') is U shaped and arranged such that the arms of said U sandwich said nozzle communication
holes (75, 76, 75', 76').
3. The ink jet type recording head according to claim 1, wherein said pressure generating
chambers (2, 3) are arranged in line along an arrangement direction (A-A, B-B) and
each pressure generating chamber (2,3) is inclined at an angle θ with respect to the
arrangement direction (A-A, B-B) with the angle θ having a value other than 90°.
4. The ink jet type recording head according to any one of the preceding claims,
wherein said outer edges (1a, 1b) of said head units (40, 41) in the arrangement direction
are inclined at the angle θ with respect to the arrangement direction (A-A,B-B) thereby
providing an inclination for each said head unit (40,41).
5. The ink jet type recording head according to any one of the preceding claims,
said head units (40, 41) are arranged on said base board (73) such that each said
head unit (40,41) is shifted along the inclination of said adjacent one of said head
units (40,41) away from a position aligned with said adjacent head unit (40, 41).
6. The ink jet type recording head according to any one of the preceding claims,
wherein said pressure generating chambers are arranged in at least two columns in
each said head unit, each column being aligned in the arrangement direction (A-A,B-B).
7. The ink jet type recording head according to any one of the preceding claims,
wherein the pitch (P0) between second opposing ones of said pressure generating chambers
that oppose each other on said head unit (40) is equal to a pitch between third opposing
ones of said pressure generating chambers on said adjacent head unit (41).
8. The ink jet type recording head according to any one of the preceding claims,
wherein said pressure generating means comprises a piezoelectric vibrator (7,8) capable
of causing a deflection vibration.
9. The ink jet type recording head according to any one of the preceding claims,
wherein said pressure generating means comprises a piezoelectric vibrator (110) capable
of causing a longitudinal vibration.
10. The ink jet type recording head according to any one of the claims 1 to 8,
wherein said pressure generating means comprises electric resistors (107) respectively
accommodated in said pressure generating chambers.
11. The ink jet type recording head according to any one of the preceding claims,
wherein nozzle openings (4,5) are formed on said base board.
12. The ink jet type recording head according to any one of the preceding claims,
wherein a hole (30,31) used for positioning is formed on a center line of each said
head unit (40,41) located between selected ones (2,3) of said pressure generating
chambers.
13. The ink jet type recording head according to any one of the preceding claims, wherein:
the arrangement of said head units (40,41) on said base board includes a first column
(54) of said head units and a second column (55) of said head units extending in parallel
to said first column; and
a first (51) and a second (52) column of nozzle.openings, corresponding respectively
to said first and second columns of head units, are formed into said base board (28).
14. The ink jet type recording head according to any of the preceding claims,
wherein the amount of shift (ΔL) is less than a width of each said head unit, the
width being measured in a direction perpendicular to the arrangement direction (A-A,B-B).
15. An ink jet printer comprising an ink jet type recording head according to any of the
claims 1 to 14.
1. Schreibkopf vom Tintenstrahltyp, umfassend:
eine Kopfeinheit (40, 41), umfassend eine Mehrzahl von Druckerzeugungsmitteln (7,
8, 65, 65') und eine Mehrzahl von Druckerzeugungskammern (2, 3) zum Beaufschlagen
von Tinte mit Druck durch Betätigung der Druckerzeugungsmittel (7, 8), wobei die Kopfeinheit
(40, 41) die Mehrzahl von Druckerzeugungskammern (2, 3) aufnimmt;
eine Durchflusskanaleinheit (85), umfassend eine Grundplatte (73), auf welcher die
Kopfeinheit angeordnet ist; und
eine Düsenplatte (72), umfassend eine Mehrzahl von Düsenöffnungen (4, 5), die in Düsenöffnungsreihen
(70, 71) angeordnet sind;
wobei die Grundplatte (73) einen Speicher (74, 74') und eine Mehrzahl von Düsenkommunikationslöchern
(75, 76, 75', 76') umfasst; und
wobei jedes Düsenkommunikationsloch (75, 76, 75', 76') einer entsprechenden Druckerzeugungskammer
(2, 3) zugeordnet ist, und zwar zum Zuführen von Tinte aus der Druckerzeugungskammer
zu einer entsprechenden Düsenöffnung (4, 5);
dadurch gekennzeichnet, dass
eine Mehrzahl von Kopfeinheiten (40, 41) auf einer einzigen Durchflusskanaleinheit
vorgesehen ist, wobei die Grundplatte (73) als gemeinsame Platte ausgebildet ist,
welche eine Mehrzahl von Speichern (74, 74') vorsieht; und
ein Ausmaß an Verschiebung (ΔL) entlang der Erstreckungsrichtung der Außenkanten (1a,
1b) zwischen der jeweiligen Kopfeinheit (40) und der benachbarten Kopfeinheit (41)
derart gewählt wird, dass ein Abstand (P1) zwischen ersten einander gegenüberliegenden
der Druckerzeugungskammern, die einander über die Außenkanten (1a, 1b) der Kopfeinheit
(40) und der benachbarten Kopfeinheit (41) gegenüberliegen, gleich einem Abstand (P0)
zwischen zweiten einander gegenüberliegenden der Druckerzeugungskammern, die einander
auf der Kopfeinheit (40) gegenüberliegen, ist.
2. Schreibkopf vom Tintenstrahltyp gemäß Anspruch 1, wobei der Speicher (74, 74') U-förmig
und derart angeordnet ist, dass die Arme des U die Düsenkommunikationslöcher (75,
76, 75', 76') beidseitig umschließen.
3. Schreibkopf vom Tintenstrahltyp gemäß Anspruch 1, wobei die Druckerzeugungskammern
(2, 3) in einer Linie entlang einer Anordnungsrichtung (A-A, B-B) angeordnet sind
und jede Druckerzeugungskammer (2, 3) in einem Winkel θ in Bezug auf die Anordnungsrichtung
(A-A, B-B) geneigt ist, wobei der Winkel θ einen Wert aufweist, der ungleich 90° ist.
4. Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen der vorhergehenden Ansprüche,
wobei die Außenkanten (1a, 1b) der Kopfeinheiten (40, 41) in der Anordnungsrichtung
im Winkel θ in Bezug auf die Anordnungsrichtung (A-A, B-B) geneigt sind, wodurch sie
eine Neigung für jede Kopfeinheit (40, 41) vorsehen.
5. Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen der vorhergehenden Ansprüche,
wobei die Kopfeinheiten (40, 41) auf der Grundplatte (73) derart angeordnet sind,
dass jede Kopfeinheit (40, 41) entlang der Neigung der benachbarten der Kopfeinheiten
(40, 41) aus einer Position, die mit der benachbarten Kopfeinheit (40, 41) ausgefluchtet
ist, weg verschoben ist.
6. Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen der vorhergehenden Ansprüche,
wobei die Druckerzeugungskammern in mindestens zwei Kolonnen in jeder Kopfeinheit
angeordnet sind, wobei jede Kolonne in der Anordnungsrichtung (A-A, B-B) ausgefluchtet
ist.
7. Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen der vorhergehenden Ansprüche,
wobei der Abstand (P0) zwischen zweiten gegenüberliegenden der Druckerzeugungskammern,
die einander auf der Kopfeinheit (40) gegenüberliegen, gleich einem Abstand zwischen
dritten gegenüberliegenden der Druckerzeugungskammern auf der benachbarten Kopfeinheit
(41) ist.
8. Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen der vorhergehenden Ansprüche,
wobei das Druckerzeugungsmittel einen piezoelektrischen Vibrator (7, 8) umfasst, der
in der Lage ist, eine Durchbiegungsvibration zu bewirken.
9. Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen der vorhergehenden Ansprüche,
wobei das Druckerzeugungsmittel einen piezoelektrischen Vibrator (110) umfasst, der
in der Lage ist, eine Längsvibration zu bewirken.
10. Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen der Ansprüche 1 bis 8, wobei
das Druckerzeugungsmittel elektrische Widerstände (107) umfasst, die jeweils in den
Druckerzeugungskammern untergebracht sind.
11. Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen der vorhergehenden Ansprüche,
wobei Düsenöffnungen (4, 5) auf der Grundplatte ausgebildet sind.
12. Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen der vorhergehenden Ansprüche,
wobei ein Loch (30, 31), das zum Positionieren verwendet wird, auf einer Mittellinie
jeder der Kopfeinheiten (40, 41) ausgebildet und zwischen ausgewählten (2, 3) der
Druckerzeugungskammern angeordnet ist.
13. Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen der vorhergehenden Ansprüche,
wobei:
die Anordnung der Kopfeinheiten (40, 41) auf der Grundplatte eine erste Kolonne (54)
der Kopfeinheiten und eine zweite Kolonne (55) der Kopfeinheiten, die sich parallel
zur ersten Kolonne erstreckt, umfasst; und
eine erste (51) und eine zweite (52) Kolonne von Düsenöffnungen, die jeweils den ersten
und zweiten Kolonnen von Kopfeinheiten entsprechen, in der Grundplatte (28) ausgebildet
sind.
14. Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen der vorhergehenden Ansprüche,
wobei das Ausmaß an Verschiebung (ΔL) kleiner als eine Breite jeder der Kopfeinheiten
ist, wobei die Breite in einer Richtung gemessen wird, welche senkrecht auf die Anordnungsrichtung
(A-A, B-B) verläuft.
15. Tintenstrahldrucker, der einen Schreibkopf vom Tintenstrahltyp gemäß einem beliebigen
der Ansprüche 1 bis 14 umfasst.
1. Tête d'enregistrement du type à jets d'encre, comprenant :
une unité de tête (40, 41) qui comprend plusieurs dispositifs générateurs de pression
(7, 8, 65, 65') et plusieurs chambres génératrices de pression (2, 3) destinées à
mettre sous pression de l'encre par manoeuvre des dispositifs générateurs de pression
(7, 8), l'unité de tête (40, 41) logeant les chambres génératrices de pression (2,
3),
une unité (85) à passages de circulation qui comporte une carte de base (73) sur laquelle
est disposée l'unité de tête, et
une plaque à buses (72) comprenant plusieurs ouvertures de buse (4, 5) disposées en
lignes d'ouvertures de buse (70, 71),
dans laquelle la carte de base (73) comporte un réservoir (74, 74') et plusieurs
trous de communication avec une buse (75, 76, 75', 76'),
dans laquelle chaque trou de communication avec une buse (75, 76, 75', 76') est
associé à une chambre génératrice de pression respective (2, 3) destinée à transmettre
l'encre de la chambre génératrice de pression à une ouverture de buse respective (4,
5),
caractérisée en ce que
plusieurs unités de tête (40, 41) sont disposées sur une seule unité à passages
de circulation, la carte de base (73) étant sous forme d'une carte commune formant
plusieurs réservoirs (74, 74'), et
l'amplitude de déplacement (ΔL) dans la direction d'allongement des bords externes
(1a, 1b) entre chaque unité de tête (40) et l'unité de tête adjacente (41) est réglée
de manière que le pas (P1 de premières chambres parmi les chambres génératrices de
pression qui sont opposées de part et d'autre des bords externes (1a, 1b) de l'unité
de tête (40) et de l'unité de tête adjacente (41) est égal au pas (P0) de secondes
chambres parmi les chambres génératrices de pression qui sont opposées sur l'unité
de tête (40).
2. Tête d'enregistrement du type à jets d'encre selon la revendication 1, dans laquelle
le réservoir (74, 74') a une forme en U et est disposé afin que les bras du U entourent
les trous de communication avec les buses (75, 76, 75', 76').
3. Tête d'enregistrement du type à jets d'encre selon la revendication 1, dans laquelle
les chambres génératrices de pression (2, 3) sont disposées sous forme alignée dans
une direction d'arrangement (A-A, B-B) et chaque chambre génératrice de pression (2,
3) est inclinée dans l'angle θ par rapport à la direction d'arrangement (A-A, B-B),
l'angle θ ayant une valeur autre que 90°.
4. Tête d'enregistrement du type à jets d'encre selon l'une quelconque des revendications
précédentes,
dans laquelle les bords externes (1a 1b) des unités de tête (40, 41) dans la direction
de l'arrangement sont inclinés de l'angle θ par rapport à la direction d'arrangement
(A-A, B-B) et donnent ainsi une inclinaison à chaque unité de tête (40, 41).
5. Tête d'enregistrement du type à jets d'encre selon l'une quelconque des revendications
précédentes, dans laquelle
les unités de tête (40, 41) sont disposées sur la carte de base (73) afin que chaque
unité de tête (40, 41) soit décalée suivant l'inclinaison de l'unité adjacente parmi
les unités de tête (40, 41) du côté opposé à un emplacement aligné sur l'unité de
tête adjacente (40, 41).
6. Tête d'enregistrement du type à jets d'encre selon l'une quelconque des revendications
précédentes,
dans laquelle les chambres génératrices de pression sont disposées en au moins
deux colonnes dans chacune des unités de tête, chaque colonne étant alignée dans la
direction d'arrangement (A-A, B-B).
7. Tête d'enregistrement du type à jets d'encre selon l'une quelconque des revendications
précédentes,
dans laquelle le pas (P0) de secondes chambres parmi les chambres génératrices
de pression qui sont opposées sur l'unité de tête (40) est égal au pas de troisièmes
chambres opposées parmi les chambres génératrices de pression sur l'unité de tête
adjacente (41).
8. Tête d'enregistrement du type à jets d'encre selon l'une quelconque des revendications
précédentes,
dans laquelle le dispositif générateur de pression comprend un vibrateur piézoélectrique
(7, 8) capable de provoquer une vibration de flexion.
9. Tête d'enregistrement du type à jets d'encre selon l'une quelconque des revendications
précédentes,
dans laquelle le dispositif générateur de pression comprend un vibrateur piézoélectrique
(110) capable de provoquer une vibration longitudinale.
10. Tête d'enregistrement du type à jets d'encre selon l'une quelconque des revendications
1 à 8,
dans lequel le dispositif générateur de pression comprend des résistances électriques
(107) disposées respectivement dans les chambres génératrices de pression.
11. Tête d'enregistrement du type à jets d'encre selon l'une quelconque des revendications
précédentes,
dans laquelle des ouvertures de buse (4, 5) sont formées sur la carte de base.
12. Tête d'enregistrement du type à jets d'encre selon l'une quelconque des revendications
précédentes,
dans laquelle un trou (30, 31) utilisé pour le positionnement est formé sur un
axe central de chaque unité de tête (40, 41) disposée entre des chambres sélectionnées
(2, 3) parmi les chambres génératrices de pression.
13. Tête d'enregistrement du type à jets d'encre selon l'une quelconque des revendications
précédentes,
dans laquelle :
l'arrangement des unités de tête (40, 41) sur la carte de base comporte une première
colonne (54) d'unités de tête et une seconde colonne (55) d'unités de tête qui s'étend
parallèlement à la première colonne, et
une première colonne (51) et une seconde colonne (52) d'ouvertures de buse, correspondant
respectivement à la première et à la seconde colonne d'unités de tête sont formées
dans la carte de base (28).
14. Tête d'enregistrement du type à jets d'encre selon l'uns quelconque des revendications
précédentes,
dans laquelle l'amplitude du déplacement ((ΔL) est inférieure à la largeur de chacune
des unités de tête, la largeur étant mesurée en direction perpendiculaire à la direction
d'arrangement (A-A, B-B).
15. Imprimante à jets d'encre comprenant une tête d'enregistrement du type à jets d'encre
selon l'une quelconque des revendications 1 à 14.