JP7074222B2 - Liquid discharge head - Google Patents

Description

The present invention relates to a liquid discharge head.

Conventionally, there is a liquid discharge head configured by combining a plurality of head units. For example, in the liquid discharge head of Patent Document 1, a plurality of head units (inkjet heads) are arranged along the main scanning direction, and two adjacent head units are arranged so as to be displaced back and forth. Further, in the liquid ejection head of Patent Document 1, each head unit receives heat from a plurality of nozzles, an actuator (piezoelectric element) for ejecting ink from these nozzles, a driver IC for driving the actuator, and a driver IC. It is equipped with a heat sink to dissipate heat.

JP-A-2015-55439

By the way, in the liquid discharge head configured by combining a plurality of head units, the driving mode is different for each head unit, so that the amount of heat generated by the driver IC is also different for each head unit. In the liquid discharge head of Patent Document 1, each driver IC is dissipated by the heat sink included in each head unit, but the temperatures of the driver ICs included in each head unit are different from each other. As described above, when the temperature of the driver IC differs for each head unit, the liquid ejection mode also differs between the head units, so that the image recorded on the recording medium has uneven density and the recording quality deteriorates. sell.

Therefore, an object of the present invention is to provide a liquid discharge head capable of suppressing deterioration of recording quality.

The liquid discharge head according to the present invention has a second head unit, which is aligned with the first head unit in the first direction and is offset to one side of the second direction orthogonal to the first direction. A head unit and a heat equalizing unit common to the first head unit and the second head unit are provided, and each of the first head unit and the second head unit has an actuator for discharging liquid from a plurality of nozzles. The unit main body is provided with a first driver IC arranged on one side of the second direction with respect to the unit main body and driving the actuator, and the heat equalizing unit is the first head unit. And a first heat equalizing body arranged on one side of the second direction with respect to the second head unit, the first heat equalizing body is aligned with the second head unit in the first direction. It has a first protruding portion that protrudes toward the first head unit on the other side in the second direction.

Further, the liquid discharge head according to another invention is arranged so as to be aligned with the first head unit in the first direction with the first head unit and shifted to one side in the second direction orthogonal to the first direction. A second head unit and a heat equalizing unit common to the first head unit and the second head unit are provided, and each of the first head unit and the second head unit discharges liquid from a plurality of nozzles. The unit main body portion provided with the actuator to be operated, the first driver IC arranged on one side of the second direction with respect to the unit main body portion, and the first driver IC for driving the actuator, and the heat equalizing unit is the first. The first heat equalizing body arranged on one side of the second direction with respect to the one head unit and the second head unit, and the first heat insulating body arranged on one side of the second direction with respect to the first head unit. Further, the intermediate heat equalizing body provided on the other side of the second direction with respect to the second head unit, the first heat equalizing body, and the intermediate heat equalizing body are in thermal contact with each other. There is.

It is a schematic plan view of the printer 1 which concerns on this embodiment. It is a top view of the inkjet head 4. It is a bottom view of the inkjet head 4. It is sectional drawing of the head unit 11 and the individual heat sink 14. It is a front view of the head unit 11 and the individual heat sink 14. It is an exploded perspective view of a head unit 11 and an individual heat sink 14. It is a left side view of a head unit 11 and an individual heat sink 14. It is a left side view of a head unit 11 and an individual heat sink 14. It is a top view of the head unit 11 and the individual heat sink 14. It is sectional drawing of the head unit 11, the common heat sink 13, and the individual heat sink 14. It is a perspective view which omitted the 2nd heat soothing body 72 of the inkjet head 4. It is a side view of the inkjet head 4. It is a top view of the inkjet head 4 which concerns on a modified form. It is a perspective view of the common heat sink 213 which concerns on the modified form. It is a top view of the common heat sink 213 and the head unit 11 which concerns on a modified form. It is a perspective view of the common heat sink 313 which concerns on the modified form. FIG. 3 is a plan sectional view of a common heat sink 313 and a head unit 11 according to a modified form.

Next, an embodiment of the present invention will be described. FIG. 1 is a schematic plan view of a printer according to the present embodiment. The transport direction shown in FIG. 1 is defined as the front-rear direction. The direction parallel to the horizontal plane and orthogonal to the transport direction is defined as the left-right direction. Further, the direction orthogonal to the transport direction and the left-right direction is defined as the vertical direction. In the following, each direction word of front, back, left, right, up and down will be described as appropriate.

<Outline configuration of printer>
As shown in FIG. 1, the printer 1 includes a platen 3, an inkjet head 4, two transport rollers 5, 6 and a control device 7 housed in a housing 2.

On its upper surface, the platen 3 supports a recording sheet 100, which is a recording medium conveyed by two transfer rollers 5 and 6. The two transfer rollers 5 and 6 are arranged on the rear side and the front side of the platen 3, respectively. The two transfer rollers 5 and 6 are each driven by a motor (not shown) to transfer the recording paper 100 on the platen 3 forward.

The inkjet head 4 is a so-called line head extending in the left-right direction over the entire length of the recording paper 100 above the platen 3, and when recording an image, ink is ejected to the recording paper 100 in a fixed position. do. Inkjet head 4 is supplied with inks of four colors (black, yellow, cyan, magenta) from an ink tank (not shown). That is, the inkjet head 4 is an inkjet head capable of ejecting four colors of ink.

As shown in FIG. 2, the inkjet head 4 includes eight head units 11a to 11h (hereinafter, referred to as "head unit 11" when the head units 11a to 11h are not distinguished), a support member 12, and a common heat sink. A 13 and an individual heat sink 14 are provided.

The eight head units 11 are arranged in the left-right direction and have the same structure as each other. Four head units 11a, 11c, 11e, 11g of the eight head units 11 are arranged on the front side in the transport direction, and the other four head units 11b, 11d, 11f, 11h are arranged on the rear side in the transport direction. Is located in. Therefore, the eight head units 11 are arranged in two rows in a staggered manner along the left-right direction.

Here, attention is paid to two head units 11 (for example, a head unit 11a and a head unit 11b) that are adjacent to each other in the left-right direction. The two adjacent head units 11 are arranged so as to be offset in the front-rear direction. Further, the right end portion of the unit main body portion 20 described later of the left head unit 11 and the left end portion of the unit main body portion 20 of the right head unit 11 are arranged side by side in the front-rear direction. That is, the ends of the two adjacent head units 11 that are adjacent to each other in the left-right direction are arranged at the same position in the left-right direction.

As shown in FIG. 3, each head unit 11 has four nozzle rows composed of a plurality of nozzles 15 arranged in the left-right direction on the lower surface thereof. The four nozzle rows are arranged side by side in the front-rear direction. These four nozzle rows include a nozzle row 16Y that ejects yellow ink, a nozzle row 16M that ejects magenta ink, a nozzle row 16C that ejects cyan ink, and a nozzle row 16K that ejects black ink. Consists of. These four nozzle rows are arranged in the order of the nozzle row 16Y, the nozzle row 16M, the nozzle row 16C, and the nozzle row 16K from the upstream side (rear side) in the transport direction.

The support member 12 is made of a metal material having relatively high rigidity such as SUS430. The support member 12 is a substantially rectangular plate-like body that is parallel to the horizontal plane and extends in the left-right direction, and both ends thereof are fixed to the housing 2. Then, the support member 12 supports the eight head units 11 so as to have the above-mentioned positional relationship. Further, the support member 12 supports the common heat sink 13.

The common heat sink 13 and the individual heat sink 14 are heat sinks for equalizing the temperature between the driver ICs 52 of the eight head units 11 while radiating heat from the driver ICs 52 described later. The common heat sink 13 is a heat sink common to the eight head units 11, while the individual heat sink 14 is a heat sink individually provided for each head unit 11.

The control device 7 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), and the like.
It is equipped with a RAM (Random Access Memory) and an ASIC (Application Specific Integrated Circuit) including various control circuits. Further, the control device 7 is connected to an external device 8 such as a PC so as to be capable of data communication, and controls each part of the printer 1 based on the image data sent from the external device 8.

More specifically, the control device 7 controls the motor that drives the transfer rollers 5 and 6 to transfer the recording paper 100 to the two transfer rollers 5 and 6 in the transfer direction. At the same time, the control device 7 controls the inkjet head 4 to eject ink toward the recording paper 100. As a result, the image is recorded on the recording paper 100.

<Detailed configuration of head unit>
Next, the configuration of the head unit 11 will be described in detail. As shown in FIGS. 4 to 9, the head unit 11 includes a unit main body 20 and two COF 21s (Chip On Films) and the like.

(Unit body)
As shown in FIG. 4, the unit main body 20 includes a flow path member 31, four actuators 32, a reservoir forming member 33, and the like.

The flow path member 31 is a flat plate-shaped member made of silicon. As shown in FIG. 4, a plurality of nozzles 15 are formed on the lower surface of the flow path member 31. On the other hand, four ink supply ports (not shown) to which ink is supplied from the reservoir forming member 33 are formed on the upper surface of the flow path member 31. Further, inside the flow path member 31, four ink flow paths 41 corresponding to the four ink colors are formed. Each ink flow path 41 includes a manifold 41a that communicates with the ink supply port and extends in the left-right direction (vertical direction on the paper surface in FIG. 4), and a plurality of pressure chambers 41b that communicate with the manifold 41a. Each pressure chamber 41b communicates with the nozzle 15. Further, the plurality of pressure chambers 41b of each ink flow path 41 are arranged in the left-right direction to form one pressure chamber row. That is, the flow path member 31 is formed with four pressure chamber rows corresponding to the four ink colors.

The four actuators 32 are arranged side by side in the front-rear direction on the upper surface of the flow path member 31. The four actuators 32 correspond to four ink colors. In other words, the four actuators 32 correspond to the four pressure chamber trains. Each actuator 32 is arranged at a position overlapping the insulating film formed in the flow path member 31 so as to cover the plurality of pressure chambers 41b of the corresponding pressure chamber row and the plurality of pressure chambers 41b on the upper surface of the insulating film. It has a plurality of piezoelectric elements. When a voltage is applied by the driver IC 52 described later, the actuator 32 changes the volume of the pressure chamber 41b due to deformation due to the inverse piezoelectric effect of each piezoelectric element, so that the ink in the pressure chamber 41b is charged from the nozzle 15 respectively. The discharge energy for discharging is given.

Wiring (not shown) extends forward from the two front actuators 32, and the two front actuators 32 are electrically connected to the COF 21a described later via the wiring, while the rear 2 Wiring (not shown) extends rearward from the one actuator 32, and the two rear actuators 32 are electrically connected to COF 21b, which will be described later, via the wiring.

The reservoir forming member 33 is arranged on the opposite side (upper side) of the flow path member 31 with the actuator 32 interposed therebetween, and is joined to the upper surface of the actuator 32. The reservoir forming member 33 is, for example, a substantially rectangular parallelepiped member made of a metal material or a synthetic resin material.

In the upper half of the reservoir forming member 33, four reservoirs 45 (only one reservoir 45 is shown in FIG. 4) corresponding to four colors of ink are formed side by side in the left-right direction. A tube connecting portion 46 is formed on the upper portion of each of the four reservoirs 45. Each of the four reservoirs 45 is connected to the ink tank via a tube (not shown) connected to the tube connecting portion 46.

In the lower half of the reservoir forming member 33, four ink supply flow paths 47 extending downward from each of the four reservoirs 45 are formed. Each ink supply flow path 47 communicates with the ink supply port of the flow path member 31. As a result, the ink in the ink tank is supplied to the plurality of pressure chambers 41b via the reservoir 45 and the ink supply flow path 47.

A groove 33a1 is formed on the front wall 33a of the reservoir forming member 33 along the left-right direction, and the elastic member 68a is fitted and provided in the groove 33a1. A groove 33b1 is also formed on the rear wall 33b of the reservoir forming member 33 along the left-right direction, and the elastic member 68b is fitted and provided in the groove 33b1. The elastic members 68a and 68b are made of sponge, rubber, or the like, and have a long outer shape with the left-right direction as the longitudinal direction. As described above, in the present embodiment, since the grooves 33a1 and 33b1 for fitting the elastic members 68a and 68b are formed in the reservoir forming member 33, the thickness of the elastic members 68a and 68b is increased in a limited space. The elastic force of the elastic members 68a and 68b can be increased. The grooves 33a1, 33b1 of the reservoir forming member 33 are not essential. For example, when the elastic members 68a, 68b are thin, the grooves 33a1, 33b1 may not be formed in the reservoir forming member 33.

Further, as shown in FIGS. 6 to 9, engaging portions 65a and 66a projecting to the left are formed on the front end portion and the rear end portion of the left surface wall 33c of the reservoir forming member 33, respectively. Engagement portions 65b and 66b (see FIG. 9) protruding to the right are formed on the front end portion and the rear end portion of the right side wall 33d of the reservoir forming member 33, respectively. The height positions of these engaging portions 65a, 65b, 66a, 66b in the vertical direction are the same. The engaging portion 65a formed at the front end of the left wall 33c has an inclined surface that inclines to the left toward the rear and a back surface that extends in the left-right direction connecting the inclined surface and the left wall 33c. It is a right-angled triangular protrusion in a plan view. The engaging portion 65b is a protrusion having a shape that is line-symmetrical with the engaging portion 65a with respect to a line along the front-rear direction. The engaging portion 66a is a protrusion having a shape that is line-symmetrical with the engaging portion 65a with respect to a line along the left-right direction. Further, the engaging portion 66b is a protrusion having the same shape as the engaging portion 65a rotated by 180 degrees in a horizontal plane (a surface parallel to the left-right direction and the front-back direction). As a modification, the shape of the engaging portions 65a, 65b, 66a, 66b may be a claw-shaped shape.

Further, on the left surface wall 33c of the reservoir forming member 33, ribs 67a projecting to the left and extending in the front-rear direction are formed at positions separated downward from the forming positions of the engaging portions 65a and 66a. .. Similarly, on the right side wall 33d of the reservoir forming member 33, ribs 67b protruding to the right and extending in the front-rear direction are formed at positions separated downward from the forming positions of the engaging portions 65b and 66b. There is.

(COF)
As shown in FIG. 4, each of the two COFs 21 has a flexible substrate 51 which is a wiring member, two driver ICs 52 mounted on the flexible substrate 51, and a plurality of circuit elements 53.

One of the two COF21s, COF21a, has an end portion of the flexible substrate 51 electrically connected to a wiring extending forward from the two front actuators 32. Then, the flexible substrate 51 of the COF 21a is pulled forward from the connection position of the actuator 32, then folded upward, extends upward along the front wall 33a of the reservoir forming member 33, and reaches the control device 7. It is connected. Two driver ICs 52 and a plurality of circuit elements 53 are provided on the front surface of a portion of the flexible substrate 51 extending upward along the front wall 33a. That is, the two driver ICs 52 of the COF 21a and the plurality of circuit elements 53 are arranged on the front side with respect to the unit main body portion 20. The front end position of each of the plurality of circuit elements 53 is arranged on the front side of the front surface of the flexible substrate 51 and on the front side of the front end position of the driver IC 52.

The other COF21b of the two COF21s has its end of the flexible substrate 51 electrically connected to wiring extending rearward from the two rear actuators 32. Then, the flexible substrate 51 of the COF 21b is pulled out rearward from the connection position of the actuator 32, then folded upward, extends upward along the rear wall 33b of the reservoir forming member 33, and reaches the control device 7. It is connected. Two driver ICs 52 and a plurality of circuit elements 53 are provided on the rear surface of the portion of the flexible substrate 51 extending upward along the rear wall 33b. That is, the two driver ICs 52 of the COF 21b and the plurality of circuit elements 53 are arranged on the rear side with respect to the unit main body portion 20. The rear end positions of the plurality of circuit elements 53 are arranged on the rear side of the rear surface of the flexible substrate 51 and on the rear side of the rear end positions of the driver IC 52.

The two driver ICs 52 included in each COF 21 each have a rectangular parallelepiped shape with the left-right direction as the longitudinal direction, and are arranged side by side in the left-right direction. These driver ICs 52 generate and output a drive signal for driving the actuator 32 based on the control signal sent from the control device 7. Further, the plurality of circuit elements 53 are circuit elements such as resistors and capacitors for noise reduction.

As described above, one head unit 11 is provided with two driver ICs 52 for each COF 21, so that a total of four driver ICs 52 are provided. Each of these driver ICs 52 corresponds to two rows of nozzle rows 16Y, 16M, 16C, 16K among four rows of nozzle rows, and an actuator 32 that discharges liquid from nozzles 15 belonging to the corresponding two rows of nozzle rows. To drive. That is, each of the four driver ICs 52 is associated with two ink colors.

In the present embodiment, the two driver ICs 52 of the COF 21a arranged on the front side with respect to the head unit 11 both correspond to the nozzle rows 16Y and 16M in the front two rows. On the other hand, the two driver ICs 52 of the COF 21b arranged on the rear side with respect to the head unit 11 both correspond to the nozzle rows 16C and 16K in the rear two rows.

Further, as shown in FIG. 2, at least one driver IC 52 of the two driver ICs arranged on the rear side of the unit main body 20 in the head units 11a, 11c, 11e, 11g is a part thereof. Is sandwiched between the unit main body 20 of the two head units 11 adjacent to each other in the left-right direction in the front-rear direction. For example, a part of the driver IC on the right side of the two driver ICs arranged on the rear side of the unit main body 20 of the head unit 11a is the unit main body 20 of the head unit 11a and the head unit 11b. It is sandwiched between the unit main body 20 of the unit in the front-rear direction. Similarly, in the head units 11b, 11d, 11f, 11h, at least one driver IC 52 of the two driver ICs arranged on the front side of the unit main body 20 is partially adjacent to each other in the left-right direction. It is sandwiched between the unit main body 20 of the two head units 11 in the front-rear direction.

By the way, when the heat generated by the driver IC 52 is transmitted to the actuator 32 and the flow path member 31, the ink ejection operation of the head unit 11 is adversely affected, such as malfunction of the actuator 32 and change of ejection characteristics due to a change in viscosity. .. Further, in the inkjet head 4, since the driving mode is different for each head unit 11, the amount of heat generated by the driver IC 52 is also different for each head unit 11. When the temperature of the driver IC 52 differs for each head unit 11 in this way, the ink ejection mode also differs between the head units 11, resulting in uneven density in the image recorded on the recording paper 100, resulting in poor recording quality. Can deteriorate. For example, when the temperatures of the driver ICs 52 of two adjacent head units 11 are different, the density unevenness at the joint portion of the image region formed by each of the two head units 11 on the recording paper 100. Stands out.

Therefore, in the present embodiment, the common heat sink 13 and the individual heat sink 14 are configured to dissipate the heat of each driver IC 52 while reducing the temperature difference between the driver ICs 52 of the eight head units 11. Hereinafter, the common heat sink 13 and the individual heat sink 14 will be described in detail.

<Detailed configuration of individual heat sink>
As shown in FIG. 2, the individual heat sink 14 is a member made of metal, ceramics, or the like having high thermal conductivity, and two individual heat sinks 14 are provided for each head unit 11. Hereinafter, two individual heat sinks 14a and 14b provided in one head unit 11 will be described. Further, in the following, the flat plate portion 61 described later of the individual heat sink 14 will be described as being arranged in parallel with the vertical plane.

Of the two individual heat sinks 14 provided in one head unit 11, one individual heat sink 14a is arranged on the front side with respect to the head unit 11, and the other individual heat sink 14b is arranged on the rear side with respect to the head unit 11. Will be done.

As shown in FIGS. 5 to 9, the individual heat sink 14a has a rectangular flat plate portion 61 extending in the left-right direction along the front wall 33a of the reservoir forming member 33 and both ends in the left-right direction of the flat plate portion 61, respectively. It is composed of side plate portions 62 and 63 extending rearward. The flat plate portion 61 is arranged so as to cover the two driver ICs 52 of the COF 21a. The rear surface of the flat plate portion 61 is in thermal contact with the two driver ICs 52 of the COF 21a. On the other hand, the front surface of the flat plate portion 61 is a facing surface 61a that faces and directly contacts the common heat sink 13. As described above, since the individual heat sink 14a has the flat facing surface 61a, heat can be effectively conducted to and from the common heat sink 13. By the way, as described above, the front end positions of the plurality of circuit elements 53 mounted on the COF 21a are arranged on the front side of the front surface of the flexible substrate 51. Therefore, the plurality of circuit elements 53 may come into contact with the flat plate portion 61 and be damaged. Therefore, in the present embodiment, the flat plate portion 61 is formed with three through holes 61b penetrating in the front-rear direction. The plurality of circuit elements 53 mounted on the COF 21a are arranged in any of the three through holes 61b. As a result, the possibility of damage due to the circuit element 53 coming into contact with the individual heat sink 14 can be reduced.

The horizontal width of the flat plate portion 61 is slightly longer than the horizontal width of the front wall 33a. The side plate portions 62 and 63 of the individual heat sinks 14a are arranged so as to sandwich the reservoir forming member 33 in the left-right direction.

As shown in FIGS. 6 to 8, an insertion hole 62a penetrating in the left-right direction is formed in the central region in the vertical direction of the side plate portion 62 on the left side of the individual heat sink 14a. Further, an insertion hole 63a (shown only in FIG. 6) penetrating in the left-right direction is formed in the central region in the vertical direction of the side plate portion 63 on the right side of the individual heat sink 14a. These insertion holes 62a and 63a are elongated holes that are long in the vertical direction. The protruding engaging portions 65a and 65b formed in the reservoir forming member 33 are inserted and engaged with the insertion holes 62a and 63a, respectively. As a result, the individual heat sink 14a is supported with respect to the reservoir forming member 33. In this way, the individual heat sink 14a can be supported by the reservoir forming member 33 with a simple configuration in which the engaging portions 65a and 65b are inserted into the insertion holes 62a and 63a and engaged with each other. In addition, by supporting the individual heat sink 14a by the reservoir forming member 33, the configuration can be simplified as compared with the case where the individual heat sink 14a is supported by other members of the inkjet head 4.

As shown in FIGS. 7 and 8, the insertion holes 62a and 63a are larger than the protruding engaging portions 65a and 65b, and the engaging portions 65a and 65b are loosely inserted into the insertion holes 62a and 63a. .. That is, a gap is formed between the hole wall surfaces of the insertion holes 62a and 63a and the engaging portions 65a and 65b. Since the individual heat sink 14a is supported by the reservoir forming member 33 only by inserting the protruding engaging portions 65a and 65b into the insertion holes 62a and 63a, the individual heat sink 14a is provided with respect to the reservoir forming member 33. It will be loosely fixed so that it can be moved. Therefore, while being supported by the reservoir forming member 33, the individual heat sink 14a can move in the front-rear direction by the gap in the front-rear direction due to this gap, and as shown in FIG. 8, the engaging portion 65a and the engagement portion 65a and the engagement portion 14a can be moved in the front-rear direction. It is rotatable around a straight line connecting the portions 65b as a rotation axis.

Here, the elastic member 68a described above is positioned in the groove 33a1 so as to be sandwiched between the two driver ICs 52 of the COF 21a and the front wall 33a of the reservoir forming member 33. Further, when viewed from the front-rear direction, the two driver ICs 52 of the COF 21a are arranged within the formation range of the elastic member 68a.

The two driver ICs 52 of the COF 21a are urged to the front individual heat sink 14a by the elastic member 68a. As a result, the two driver ICs 52 of the COF 21a are in thermal contact with the individual heat sink 14a. The elastic member 68a also urges the individual heat sink 14a forward via the two driver ICs 52 of the COF 21a. Therefore, as shown in FIG. 7, when the individual heat sink 14a is not loaded with the load from the common heat sink 13, the individual heat sink 14a is arranged at the most distant position in the front-rear direction with respect to the reservoir forming member 33. To. At this separation position, the wall surfaces of the holes on the rear side of the insertion holes 62a and 63a come into contact with the back surfaces of the engaging portions 65a and 65b.

Further, in the present embodiment, the two driver ICs 52 of the COF 21a are arranged on a straight line connecting the engaging portion 65a and the engaging portion 65b. That is, the individual heat sink 14a is rotatable around the two driver ICs 52 of the COF 21a as rotation axes, and the rotation axis is an axis along the longitudinal direction of the driver IC 52. In other words, the reservoir forming member 33 rotatably supports the individual heat sink 14a with the position on the rotation axis, which is the axis along the longitudinal direction of the driver IC 52, as the support position. Therefore, as shown in FIG. 10, even if the individual heat sink 14a rotates around the rotation axis, the state in which the two driver ICs 52 of the individual heat sink 14a and the COF 21a are in thermal contact can be maintained. The support position of the individual heat sink 14a of the reservoir forming member 33 does not have to be a position on the rotation axis, but by arranging the support position on the rotation axis, the individual heat sink 14a can be rotatably supported. The support configuration can be simplified. Further, the elastic member 68a for urging the driver IC 52 also extends along the driver IC 52 with the axial direction of the rotation shaft as the longitudinal direction. That is, the elastic member 68a is also arranged on the rotation axis of the individual heat sink 14a or at a position close to the rotation axis thereof. As a result, the individual heat sink 14a can rotate without contacting the elastic member 68a.

As shown in FIG. 4, an elastic member 69 is provided between and around the two driver ICs 52 of the COF 21a and the individual heat sink 14a. With this elastic member 69, even if the stress from the individual heat sink 14a is concentrated on a part (for example, a corner portion) of the driver IC 52, it is possible to prevent the driver IC 52 from being damaged. The elastic member 69 can be easily formed by applying, for example, a potting material or grease to the individual heat sink 14a or the driver IC 52. Further, if the elastic member 69 is formed of a potting material made of a heat conductive material, heat conduction from the driver IC 52 to the individual heat sink 14a can be efficiently performed. The elastic member 69 may be provided only between the driver IC 52 and the individual heat sink 14a and at one of the surroundings.

By the way, in the present embodiment, the individual heat sink 14a is movable in the front-rear direction, and the insertion hole 62a is configured to be rotatable around a straight line connecting the engaging portion 65a and the engaging portion 65b as a rotation axis. , 63a, a gap is also formed in the vertical direction between the hole wall surface and the engaging portions 65a and 65b. However, with this configuration, the individual heat sink 14a may move significantly in the vertical direction, resulting in insufficient contact between the individual heat sink 14a and the two driver ICs 52 of the COF 21a.

Therefore, in the present embodiment, as shown in FIG. 6, in the regions below the insertion holes 62a and 63a in each of the side plate portions 62 and 63, the cutout portions 62b and 63b are subsequently cut out from the outer edge toward the front. Is formed. The front ends of the ribs 67a and 67b formed on the left side wall 33c and the right side wall 33d of the reservoir forming member 33 are inserted into the cutouts 62b and 63b, respectively. The vertical width of the cutouts 62b, 63b is longer than the vertical width of the ribs 67a, 67b, and a vertical gap is formed between the inner wall surface of the cutouts 62b, 63b and the ribs 67a, 67b. ing.

The vertical gap between the inner wall surface of the cutouts 62b, 63b and the ribs 67a, 67b is narrower than the vertical gap between the hole wall surface of the insertion holes 62a, 63a and the engaging portions 65a, 65b. .. As a result, the individual heat sink 14a can move in the vertical direction only by the vertical gap between the inner wall surface of the cutout portions 62b and 63b and the ribs 67a and 67b, and the vertical movement range thereof is the ribs 67a and 67b. Is regulated by. As a result, it is possible to prevent the individual heat sink 14a from moving significantly in the vertical direction, and it is possible to maintain a state in which the individual heat sink 14a and the two driver ICs 52 of the COF 21a are in contact with each other. As a modification, the cutouts 62b and 63b are formed in the region above the insertion holes 62a and 63a in the side plate portions 62 and 63, and the ribs 67a and 67b are located at the positions where the engaging portions 65b and 66b are formed. On the other hand, it may be formed at a position separated upward. Even in this case, it is possible to prevent the individual heat sink 14a from moving significantly in the vertical direction.

When the individual heat sinks 14a are arranged at the above separated positions (see FIG. 7), between the front ends of the ribs 67a and 67b and the inner side wall extending in the vertical direction which is the bottom of the notches of the notches 62b and 63b. A gap is formed in the front-back direction. This gap is set to be equal to or larger than the gap in the front-rear direction between the hole wall surfaces of the insertion holes 62a and 63a and the engaging portions 65a and 65b. Therefore, regarding the movement of the individual heat sink 14a in the front-rear direction, the movement range is not restricted by the ribs 67a and 67b, and the individual heat sink 14a is moved in the front-rear direction between the hole wall surface of the insertion holes 62a and 63a and the engaging portions 65a and 65b. It becomes possible to move by the amount of the gap.

Next, the individual heat sink 14b will be described. The individual heat sink 14b has the same shape as the individual heat sink 14a rotated 180 degrees in a horizontal plane. Therefore, the individual heat sink 14a and the individual heat sink 14b can be manufactured in a common manufacturing process using a common manufacturing apparatus. As a result, these manufacturing costs can be kept low. For example, when the individual heat sink 14a and the individual heat sink 14b are manufactured by extrusion molding, it is not necessary to prepare individual molding dies, and it is possible to mold using a common molding die, so that the manufacturing cost is high. Can be kept cheap. The configurations of the individual heat sinks 14b are designated by the same reference numerals as those of the individual heat sinks 14a, and the description thereof will be omitted as appropriate.

The individual heat sink 14b is provided with respect to the reservoir forming member 33 by inserting the engaging portions 66a, 66b formed in the reservoir forming member 33 into the insertion holes 62a, 63a formed in the side plate portions 62, 63. It is supported. The two driver ICs 52 of the COF 21b are urged to the individual heat sink 14b by the elastic member 68b. The elastic member 68b also urges the individual heat sink 14b rearward via the two driver ICs 52 of the COF 21b. Since the support configuration of the individual heat sink 14b in the reservoir forming member 33 is the same as the support configuration of the individual heat sink 14a of the reservoir forming member 33, the description thereof will be omitted.

<Detailed configuration of common heat sink>
The common heat sink 13 is made of a metal having high thermal conductivity such as aluminum ADC 12 or ceramics. As shown in FIG. 2, the common heat sink 13 has a first heat equalizing body 71 arranged on the front side with respect to the eight head units 11 and a second equalizing body 71 arranged on the rear side with respect to the eight head units 11. It has a hot body 72. The first heat soothing body 71 and the second heat soaking body 72 are formed of separate and independent members.

The first soaking body 71 extends in the left-right direction and has four base walls 81 and five protrusions 82 protruding rearward from the base wall 81. In the first soaking body 71, the base wall 81 and the projecting portions 82 are alternately arranged in the left-right direction.

The four base walls 81 are flat plates that are parallel to the vertical plane and extend in the left-right direction. The left-right width of the base wall 81 is longer than the left-right width of the head unit 11. The four base walls 81 correspond to the four head units 11a, 11c, 11e, 11g arranged on the front side. Each base wall 81 is arranged on the front side of the corresponding head unit 11. The rear surface of each base wall 81 faces the entire facing surface 61a of the flat plate portion 61 of the individual heat sink 14a provided in the corresponding head unit 11 and is in direct contact with the entire surface. Therefore, the individual heat sinks 14a provided on the head units 11a, 11c, 11e, and 11g are arranged between the driver IC 52 of the COF 21a of the head unit 11 and the base wall 81, and are placed on both the driver IC 52 and the base wall 81. It is in thermal contact with it.

The five protrusions 82 are arranged so as to be aligned with the head units 11a, 11c, 11e, and 11g in the left-right direction. Specifically, the head unit 11 of the head units 11a, 11c, 11e, and 11g is arranged so as to sandwich the head unit 11 between the two protrusions 82 adjacent to each other in the left-right direction. That is, the protrusions 82 and the head unit 11 are alternately arranged in the left-right direction.

Each of the five protrusions 82 has a facing wall 83 and at least one connecting wall 84, respectively.

The facing wall 83 is a flat plate-shaped wall arranged behind the base wall 81, which is parallel to the vertical surface and extends in the left-right direction. The connecting wall 84 is a flat plate-shaped wall extending in the front-rear direction that connects the facing wall 83 and the adjacent base wall 81. Therefore, on the trailing edge of the first soaking body 71, a continuous wall is formed by the facing wall 83 and the connecting wall 84 of each of the five protrusions 82 and the four base walls 81. The facing wall 83 and the connecting wall 84 of the protruding portion 82 are made thicker than the base wall 81 in order to increase the heat conduction area.

As shown in FIGS. 11 and 12, the facing walls 83 of the two protrusions 82 on both sides of the first heat soaking body 71 in the left-right direction are lateral to the facing walls 83 of the three protrusions 82 in the center. The width is long. Through holes 88a and 88b penetrating in the front-rear direction are formed on the facing walls 83 of the two protrusions 82 on both sides in the left-right direction. The through hole 88a of the leftmost protrusion 82 is formed at a position on the left side of the eight head units 11, and the through hole 88b of the rightmost protrusion 82 is formed at a position on the right side of the eight head units 11. Has been done. The screw 89 is inserted into the through hole 88a and the through hole 98b described later of the second heat equalizing body 72, and the screw 89 is inserted into the through hole 88b and the through hole 98a described later of the second heat equalizing body 72. As a result, the first heat equalizing body 71 and the second heat equalizing body 72 are thermally contacted with each other and fixed.

As shown in FIG. 2, the four protrusions 82 on the right side of the five protrusions 82 correspond to the four head units 11b, 11d, 11f, 11h arranged rearward among the eight head units 11. ing. The facing walls 83 of the four protrusions 82 on the right side are arranged on the front side of the corresponding head unit 11. The rear surface of the facing wall 83 of the four protrusions 82 on the right side faces a part of the facing surface 61a of the flat plate portion 61 of the individual heat sink 14a of the corresponding head unit 11 and is in direct contact with the rear surface. Further, the individual heat sinks 14a provided in the head units 11b, 11d, 11f, 11h are arranged between the driver IC 52 of the COF 21a of the head unit 11 and the facing wall 83, and are thermally connected to the driver IC 52 and the facing wall 83. Is in contact with.

As described above, the four protrusions 82 on the right side of the first heat soaking body 71 project rearward toward the corresponding head unit 11 and thermally contact the individual heat sinks 14a provided on the corresponding head unit 11. is doing. The first heat equalizing body 71 is in direct contact (thermal contact) with the individual heat sinks 14a provided in the eight head units 11. As a result, the heat of the driver IC 52 of the COF 21a of each head unit 11 can be conducted to each other via the individual heat sink 14a of each head unit 11 and the first heat equalizing body 71. As a result, the temperature difference between the driver ICs 52 of the COF 21a of the eight head units 11 can be reduced.

Further, in the present embodiment, there is a driver IC 52 in which at least a part thereof is sandwiched by the adjacent head units 11 in the front-rear direction. Here, in the case where the inkjet head 4 does not have the individual heat sink 14 and the heat of the driver IC 52 is dissipated only by the common heat sink 13, the entire driver IC 52 sandwiched between the adjacent head units 11 is the common heat sink. It is difficult to make contact with 13. Therefore, the heat of the driver IC 52 cannot be efficiently conducted to the common heat sink 13. However, in the present embodiment, the head unit 11 is provided with an individual heat sink 14a, and the individual heat sink 14a is provided so as to cover the entire driver IC 52. Therefore, the heat of the driver IC 52 sandwiched by the adjacent head units 11 can be efficiently conducted to the common heat sink 13 via the individual heat sink 14a. As described above, in the present embodiment, when the facing wall 83 of the protrusion 82 partially overlaps with the driver IC 52 of the corresponding head unit 11 when viewed from the front-rear direction, or with respect to the driver IC 52. Even when they do not overlap at all, the heat of the driver IC 52 can be efficiently conducted to the common heat sink 13 via the individual heat sink 14.

Further, in the present embodiment, the facing wall 83 of the protruding portion 82 has a smaller contact area with the individual heat sink 14a than the base wall 81. However, as shown in FIG. 2, since the facing wall 83 and the connecting wall 84 of the protruding portion 82 are thicker than the base wall 81 and have a large heat conduction area, the protruding portion 82 has a corresponding head. Heat can be efficiently conducted to and from the driver IC 52 of the unit 11.

Further, the front surface of the facing wall 83 of the two protrusions 82 on both sides in the left-right direction (the outer peripheral surface opposite to the head unit 11) and the front surface of each of the four base walls 81 project forward and along the vertical direction. The extending heat radiation fin 85 is formed. The front end positions of the heat radiation fins 85 coincide with each other. With these plurality of heat dissipation fins 85, the first heat soaking body 71 can be continuously air-cooled.

Further, as shown in FIG. 12, on the front surface of the facing wall 83 of the five projecting portions 82 and the front surface of the four base walls 81, plate portions 86a projecting forward and extending along the left-right direction, respectively, are provided. It is formed. The plurality of plate portions 86a are connected to each other and form continuous ribs 86 from the left end to the right end of the first heat soaking body 71. The rib 86 can improve the rigidity of the first soaking body 71.

Further, as shown in FIG. 10, the formation position of the rib 86 in the vertical direction is the same as the arrangement position of the two driver ICs 52 of the COF 21a in the vertical direction. Therefore, the heat of the two driver ICs 52 can be dissipated more effectively through the rib 86. Further, as described above, the rib 86 is continuous from the left end to the right end of the first heat soaking body 71. In other words, the rib 86 extends in the left-right direction from the left end position of the driver IC 52 on the left side of the head unit 11a to the right end position of the driver IC on the right side of the head unit 11h. Thereby, the temperature difference of the driver IC 52 of the COF 21a of the eight head units 11h can be further reduced.

Next, the second soaking body 72 will be described. The second heat equalizing body 72 has the same shape as the first heat equalizing body 71 rotated by 180 degrees in a horizontal plane. Therefore, the first heat equalizing body 71 and the second heat equalizing body 72 can be manufactured in a common manufacturing process using a common manufacturing apparatus. As a result, these manufacturing costs can be kept low. For example, when the first heat equalizing body 71 and the second heat equalizing body 72 are manufactured by extrusion molding, it is not necessary to prepare individual molding dies, and it is possible to mold using a common molding die. Therefore, the manufacturing cost can be kept low. The description of each configuration of the second heat soothing body 72 will be omitted as appropriate by adding a reference numeral of “10” to the code of the configuration corresponding to the first heat soaking body 71.

As shown in FIG. 2, the second heat soothing body 72 has four base walls 91 and five protrusions 92, similarly to the first heat soaking body 71. The four base walls 91 correspond to the four head units 11b, 11d, 11f, 11h arranged on the rear side. Each base wall 91 is located behind the corresponding head unit 11. The front surface of each base wall 91 faces the entire facing surface 61a of the flat plate portion 61 of the individual heat sink 14b provided in the corresponding head unit 11 and is in direct contact with the entire surface.

The five protrusions 92 are arranged so as to line up with the head units 11b, 11d, 11f, and 11h in the left-right direction. Of the five protrusions 92, the four protrusions 92 on the left side correspond to the four head units 11a, 11c, 11e, 11g. The facing walls 93 of the four protrusions 92 on the left side are arranged on the rear side of the corresponding head unit 11. The front surface of the facing wall 93 of the four protrusions 92 on the left side faces a part of the facing surface 61a of the flat plate portion 61 of the individual heat sink 14b of the corresponding head unit 11 and is in direct contact with the front surface. As described above, the four protrusions 92 on the left side project forward toward the corresponding head unit 11 and are in thermal contact with the individual heat sink 14b provided on the corresponding head unit 11.

With the above configuration, the second heat soaking body 72 is in direct contact with the individual heat sinks 14b provided on the eight head units 11. As a result, the heat of the driver IC 52 of the COF 21b of each head unit 11 is conducted to each other via the individual heat sink 14b and the second heat soaking body 72 of each head unit 11. As a result, the temperature difference between the driver ICs 52 of the COF 21b of the eight head units 11 can be reduced.

Further, in the present embodiment, the first heat soothing body 71 and the second heat soaking body 72 are formed of separate and independent members, but they are fixed so as to be in thermal contact with each other. As a result, heat conduction can be performed between the first heat equalizing body 71 and the second heat equalizing body 72. As a result, the temperature difference between the driver IC 52 of the COF 21a and the driver IC 52 of the COF 21b of the eight head units 11 can also be reduced. That is, the temperature difference of all the driver ICs 52 included in the inkjet head 4 can be reduced.

The configuration for fixing the first heat equalizing body 71 and the second heat equalizing body 72 is not particularly limited. However, in the present embodiment, as described above, the eight head units 11 are arranged along the left-right direction, and the adjacent ends of the unit body 20 of the two head units 11 adjacent to each other in the left-right direction. The portions are arranged at the same position in the left-right direction. In this case, in the configuration in which the central regions in the left-right direction of the first heat equalizing body 71 and the second heat equalizing body 72 are brought into contact with each other and fixed, the presence of the head unit 11 may complicate the process and reduce the contact area. be. Therefore, in the present embodiment, the first heat equalizing body 71 and the second heat equalizing body 72 are fixed to each other at both ends in the left-right direction of each. At both ends of the first heat equalizing body 71 and the second heat equalizing body 72 in the left-right direction, the head unit 11 is not arranged between the first heat equalizing body 71 and the second heat equalizing body 72, so that they are in contact with each other. It is possible to increase the area and fix each other. As a result, the thermal conductivity between the first soaking body 71 and the second soaking body 72 can be enhanced.

Specifically, the facing wall 83 of the leftmost protrusion 82 of the first heat soothing body 71 and the facing wall 93 of the leftmost protrusion 92 of the second heat soaking body 72 face each other and are in direct contact with each other. A screw 89 (see FIG. 12) is inserted through the through hole 88a formed in the facing wall 83 and the through hole 98b formed in the facing wall 93. Similarly, the facing wall 83 of the rightmost protrusion 82 of the first heat soothing body 71 and the facing wall 93 of the rightmost protrusion 92 of the second heat soaking body 72 face each other and are in direct contact with each other. The screw 89 is inserted into the through hole 88b formed in the facing wall 83 and the through hole 98a formed in the facing wall 93. As described above, the first heat equalizing body 71 and the second heat equalizing body 72 are fixed by the screw 89. Therefore, heat can be conducted between the first heat equalizing body 71 and the second heat equalizing body 72 even through the screw 89.

Further, since the first heat equalizing body 71 and the second heat equalizing body 72 are formed of separate and independent members, the first heat equalizing body 71 is mounted from the front side of the eight head units 11 and is second. Since the heat equalizing body 72 can be mounted from the rear side of the eight head units 11, compared with the case where the first heat equalizing body 71 and the second heat equalizing body 72 are integrally formed, the heat equalizing body 72 can be mounted from the rear side. Assembling work becomes easy.

The bottom surface of the common heat sink 13 is fixed in contact with the mounting surface 12a of the support member 12. Since the support member 12 is a member having relatively high rigidity, the common heat sink 13 can be stably supported and fixed.

By the way, when the temperature of the common heat sink 13 becomes high, the support member 12 thermally expands and deforms due to the heat from the common heat sink 13. As a result, the support position of each head unit 11 may deviate from the design position, and the recording quality of the image recorded on the recording paper 100 may deteriorate.

Therefore, in the present embodiment, as shown in FIGS. 11 and 12, an arcuate protrusion 87 protruding downward is formed on the bottom surface of each of the two protrusions 82 on both sides in the left-right direction of the first heat soaking body 71. Has been done. Then, only the protrusion 87 is in contact with and fixed to the mounting surface 12a of the support member 12 of the first heat soaking body 71. That is, both ends of the first heat soaking body 71 in the left-right direction are fixed to the mounting surface 12a of the support member 12 by point contact. Similarly, an arc-shaped protrusion 97 protruding downward is formed on the bottom surface of each of the two protrusions 92 on both sides in the left-right direction of the second heat soaking body 72. Then, only the protrusion 97 of the second heat soaking body 72 is in contact with and fixed to the mounting surface 12a of the support member 12. Here, from the viewpoint of the heat generation density of the driver IC 52 of the eight head units 11, the temperature of the common heat sink 13 is lower at both ends in the left-right direction than in the vicinity of the center in the left-right direction. Therefore, by contacting and fixing only both ends of the common heat sink 13 in the left-right direction with respect to the support member 12, thermal expansion of the support member 12 due to heat from the common heat sink 13 can be suppressed. In addition, since the first heat equalizing body 71 is fixed to the support member 12 by point contact, the heat of the first heat equalizing body 71 is difficult to be transferred to the support member 12. Further, in the present embodiment, the support member 12 is formed of a member having a smaller thermal expansion than the first soaking body 71, and specifically, the coefficient of thermal expansion of the support member 12 is 10.4 × 10. It is ^-6 / ° C, and the coefficient of thermal expansion of the soaking body 71 is 21 × 10 ^-6 / ° C. With the above configuration, even if the common heat sink 13 becomes hot, the support member 12 is not easily deformed, so that deterioration of recording quality can be suppressed.

Further, in order to improve the thermal conductivity from the driver IC 52 of each head unit 11 to the common heat sink 13, the adhesion between the individual heat sink 14 and the common heat sink 13 is important. However, if the head unit 11 is misaligned due to an assembly error or the like, the adhesion between the individual heat sink 14 and the common heat sink 13 may be insufficient. In this respect, in the present embodiment, as described above, the individual heat sinks 14 provided on the head units 11 are urged outward in the front-rear direction by the elastic members 68a and 68b, and the driver IC 52 is used as the rotation axis. Since it is configured to be rotatable, it is possible to maintain and improve the adhesion between the individual heat sink 14 and the common heat sink 13. Hereinafter, the adhesion between the individual heat sink 14a and the facing wall 83 of the protruding portion 82 of the first heat soaking body 71 will be specifically described as an example.

In this embodiment, when the individual heat sinks 14a and 14b are arranged at the above-mentioned separated positions (see FIG. 7), the base wall 81 is larger than the separated distance between the flat plate portions 61 of the individual heat sinks 14a and 14b. The distance between the front and rear of the facing wall 83 and the distance between the base wall 91 and the facing wall 93 in the front-rear direction are set to be slightly shorter. Therefore, the individual heat sinks 14a provided in each head unit 11 receive a load from the first heat soaking body 71 and are arranged behind the separated position against the urging force of the elastic member 68a. Similarly, the individual heat sinks 14b provided in each head unit 11 receive a load from the second heat soaking body 72 and are arranged in front of the separated position against the urging force of the elastic member 68b.

If the support position of the head unit 11 of the support member 12 is displaced in the front-rear direction, the distance between the head unit 11 and the first heat soaking body 71 in the front-rear direction changes. However, since the individual heat sink 14a is urged forward by the elastic member 68a, the individual heat sink 14a maintains the adhesion with the driver IC 52, and the facing surface 61a of the flat plate portion 61 faces the facing wall 83. It can be moved to a position where it comes into direct contact. That is, the urging force of the elastic member 68a can absorb the deviation of the support position of the head unit 11 in the front-rear direction, so that the individual heat sink 14a and the first heat soaking body 71 can be brought into direct contact with each other.

Further, as shown in FIG. 10, when the head unit 11 is tilted back and forth and supported by the support member 12, the individual heat sink 14a rotates with the driver IC 52 of the COF 21a as a rotation axis, whereby the driver While maintaining the close contact with the IC 52, the facing surface 61a of the flat plate portion 61 can be brought into contact with the facing wall 83 in parallel. That is, by rotating the individual heat sink 14a, the tilted portion of the head unit 11 can be absorbed and the individual heat sink 14a and the first heat soaking body 71 can be brought into direct contact with each other.

As described above, in the present embodiment, even if the head units 11 are misaligned, the urging forces of the elastic members 68a and 68b ensure that the common heat sink 13 of the individual heat sink 14 and the driver IC 52 adhere to each other. Can be maintained and improved. As a result, the heat of the driver IC 52 of the head unit 11 can be efficiently conducted to the common heat sink 13 via the individual heat sinks 14a and 14b, and the heat dissipation performance of the common heat sink 13 can be improved.

In addition, when the driver IC 52 is arranged on both the front side and the rear side of the unit main body 20 in each head unit 11 as in the present embodiment, the front side and the rear side of the unit main body 20 are arranged. The individual heat sinks 14 are arranged on both sides of the above. As a result, even if the head unit 11 is misaligned, the heat of the driver IC 52 arranged on the front side with respect to the unit main body 20 is arranged on the rear side with respect to the unit main body 20 via the individual heat sink 14a. The heat of the driver IC 52 can be conducted to the common heat sink 13 via the individual heat sink 14b.

Although it has been described above that the individual heat sink 14 can absorb the misalignment of the head unit 11, the individual heat sink 14 of the present embodiment is not limited to the misalignment of the head unit 11, and the head unit 11 of the common heat sink 13 is not limited to the misalignment of the head unit 11. Similarly, it is possible to absorb the misalignment with respect to the misalignment, the misalignment of the COF 21 on which the driver IC 52 is mounted, and the like. That is, by providing the individual heat sink 14 in each head unit 11, even if at least one of the head unit 11, the common heat sink 13, and the COF 21 is misaligned, the individual heat sink 14 causes the misalignment. Can be absorbed. As a result, the heat of each driver IC 52 can be conducted to the common heat sink 13 via the individual heat sink 14.

Further, as described above, each head unit 11 receives a load from the common heat sink 13 via the individual heat sink 14. Here, when the common heat sink 13 is firmly fixed to the support member 12 by screwing or the like, for example, the common heat sink 13 is attached to the driver IC 52 of the head unit 11 whose support position is deviated as described above. A large load may be applied from the driver IC 52 to damage the driver IC 52. In addition, the support position of the head unit 11 of the support member 12 may shift due to the load from the common heat sink 13.

Therefore, in the present embodiment, the common heat sink 13 is loosely fixed to the mounting surface 12a of the support member 12. Specifically, each of the protrusion 87 of the first heat soothing body 71 and the protrusion 97 of the second heat soaking body 72 and the mounting surface 12a are fixed by heat caulking or an adhesive. Therefore, the common heat sink 13 can be moved by a small amount with respect to the mounting surface 12a. As a result, the common heat sink 13 can be moved to a position where an excessive load is not applied to each head unit 11. That is, the common heat sink 13 can be moved to a position where the magnitudes of the elastic forces of the elastic members 68a and 68b of the eight head units 11 are substantially the same. As a result, it is possible to prevent the driver IC 52 from being damaged, and it is possible to prevent the support position of the head unit 11 of the support member 12 from being displaced. When the common heat sink 13 is fixed to the mounting surface 12a with an adhesive, the adhesive must be a heat insulating adhesive in order to make it difficult for heat to be transferred from the common heat sink 13 to the support member 12. Is preferable. Further, an elastic member may be interposed between the common heat sink 13 and the mounting surface 12a, and the common heat sink 13 may be loosely fixed to the support member 12 by the elastic member. The elastic member is also preferably a heat insulating elastic member in order to make it difficult for heat to be transferred from the common heat sink 13 to the support member 12.

As described above, in the present embodiment, the first heat equalizing body 71 and the second heat equalizing body 72 of the common heat sink 13 have protrusions 82 and 92 according to the arrangement mode of the eight head units 11. Therefore, 8 It is possible to contact the driver IC 52 of one head unit 11 via the individual heat sink 14. As a result, the temperature difference between the driver ICs 52 of the eight head units 11 can be reduced, and as a result, deterioration of the recording quality can be suppressed.

In the present embodiment, although the first heat equalizing body 71 and the second heat equalizing body 72 are in thermal contact with each other, the temperature of the first heat equalizing body 71 and the second heat equalizing body 72 is slightly different. different. Therefore, for example, in the two head units 11, when the driver ICs 52 corresponding to the same ink color are in contact with different heat equalizing bodies via the individual heat sinks 14, the image recorded on the recording paper 100 is recorded. May cause density unevenness related to the ink color. In that respect, in the present embodiment, in the eight head units 11, all the driver ICs 52 corresponding to the same ink color are in contact with each other with the same heat soaking body via the individual heat sink 14. For example, the driver ICs 52 corresponding to the black ink colors of the eight head units 11 are all arranged on the front side with respect to the reservoir forming member 33 of each head unit 11, and are the first heat equalizing bodies via the individual heat sinks 14a. It is in contact with 71. As a result, the temperature difference between the driver ICs 52 corresponding to the same ink color can be surely reduced, so that it is possible to suppress the occurrence of density unevenness for each ink color.

In the embodiment described above, the inkjet head 4 corresponds to a "liquid ejection head". The left-right direction corresponds to the "first direction", one of the left side and the right side corresponds to "one side of the first direction", and the other corresponds to "the other side of the first direction". The front-rear direction corresponds to the "second direction", the front side corresponds to "one side of the second direction", and the rear side corresponds to "the other side of the second direction". The vertical direction corresponds to the "third direction". Of the two head units 11 adjacent to each other in the left-right direction, the head unit 11 arranged on the rear side corresponds to the "first head unit", and the head unit 11 arranged on the front side corresponds to the "second head unit". do. The common heat sink 13 corresponds to a "heat equalizing unit". The individual heat sink 14a corresponds to the "first individual radiator", and the individual heat sink 14b corresponds to the "second individual radiator". The driver IC 52 of COF21a corresponds to the "first driver IC", and the driver IC 52 of COF21b corresponds to the "second driver IC". The protruding portion 82 of the first heat soaking body 71 corresponds to the “first protruding portion”, and the protruding portion 92 of the second heat soaking body 72 corresponds to the “second protruding portion”.

Next, a modified embodiment in which various modifications are made to the embodiment will be described. However, those having the same configuration as that of the above-described embodiment are designated by the same reference numerals and the description thereof will be omitted as appropriate.

First, a modified form of the common heat sink will be described. As in the common heat sink 113 shown in FIG. 13, the first heat soothing body 171 and the second heat soaking body 172 may be integrally formed. The common heat sink 113 is the same as the common heat sink 13 except that the first heat soothing body and the second heat soaking body are integrally formed. The common heat sink 113 can be fixed to the support member 12 by mounting the common heat sink 113 so as to cover the eight head units 11 supported by the support member 12. In this way, by integrally forming the first heat soothing body 171 and the second heat soaking body 172, the assembling work can be performed as compared with the case where the first heat soothing body 171 and the second heat soaking body 172 are integrally formed of separate and independent members as in the above embodiment. Although it becomes difficult, the thermal conductivity between the first soaking body 171 and the second soaking body 172 can be enhanced. In addition, the number of parts can be reduced, and the step of fixing the first heat soothing body 171 and the second heat soaking body 172 at the time of manufacturing can be omitted.

Next, another modification of the common heat sink will be described with reference to FIGS. 14 and 15. As shown in FIGS. 14 and 15, the common heat sink 213 includes a base 270, a first heat soothing body 271, a second heat soaking body 272, an intermediate heat soaking body 273, a plurality of first connecting bodies 274, and a plurality of first heat sinks. It has two connectors 275.

The base portion 270 is a rectangular plate-like body that is parallel to the horizontal plane and extends in the left-right direction. Eight through holes (not shown) arranged in a staggered pattern corresponding to the eight head units 11 are formed in the base 270, and the lower portions of the eight head units 11 are inserted through the through holes. ing. Further, the first heat equalizing body 271, the second heat equalizing body 272, the intermediate heat equalizing body 273, the plurality of first connecting bodies 274, and the plurality of second connecting bodies 275 were erected above the base 270. It is a plate-shaped body.

The first heat soaking body 271 is arranged on the front side with respect to the eight head units 11, and extends along the left-right direction. The rear surface of the first heat soaking body 271 is in direct contact with the individual heat sinks 14a provided on the head units 11a, 11c, 11e, 11g.

The second heat soaking body 272 is arranged on the rear side with respect to the eight head units 11, and extends along the left-right direction. The front surface of the second heat soaking body 272 is in direct contact with the individual heat sinks 14b provided on the head units 11b, 11d, 11f, 11h.

The intermediate heat equalizing body 273 is arranged on the rear side with respect to the head units 11a, 11c, 11e, 11g, and is arranged on the front side with respect to the head units 11b, 11d, 11f, 11h. The intermediate heat equalizing body 273 also extends along the left-right direction, and the front surface thereof directly contacts the individual heat sinks 14b provided on the head units 11a, 11c, 11e, 11g, and the rear surface thereof is the head unit 11b. , 11d, 11f, 11h are in direct contact with the individual heat sinks 14a.

Further, as shown in FIG. 15, a part of the intermediate heat equalizing body 273 is arranged at a position sandwiched in the front-rear direction by the unit main body portion 20 of two adjacent head units 11. As a result, even with respect to the driver IC 52 in which at least a part of the driver IC 52 is arranged at a position sandwiched in the front-rear direction by the unit main body 20 of the two adjacent head units 11, the intermediate heat soaking body 273 is the driver IC 52. Can be contacted with respect to the entire surface of the surface via the individual heat sink 14. As a result, the heat of the driver IC 52 can be efficiently conducted to the intermediate heat equalizing body 273.

Further, the intermediate heat equalizing body 273 extends at least in the left-right direction from the left end position of the driver IC 52 on the left side of the COF 21b of the head unit 11a to the right end position of the driver IC 52 on the right side of the COF 21a of the head unit 11h. Therefore, it is possible to efficiently conduct the heat of the driver IC 52 of the COF 21b of the head units 11a, 11c, 11e, 11g and the driver IC 52 of the COF 21a of the head units 11b, 11d, 11f, 11 to the intermediate heat equalizing body 273. Become.

The left end of each of the first heat soothing body 271, the second heat soaking body 272, and the intermediate heat soaking body 273 is located on the left side of the eight head units 11, and the right end thereof is located on the left side of the eight head units 11. It is located on the right side. Further, a plurality of heat radiation fins 285 projecting forward and extending in the vertical direction are formed on the outer peripheral surface on the front side of the first heat soaking body 271. Similarly, on the outer peripheral surface on the rear side of the second heat soaking body 272, a plurality of heat radiation fins 295 projecting forward and extending in the vertical direction are formed.

The plurality of first connecting bodies 274 are arranged in the area where the head units 11a, 11c, 11e, 11g are not arranged in the area sandwiched between the first heat equalizing body 271 and the intermediate heat equalizing body 273. The plurality of first connecting bodies 274 extend along the front-rear direction, and connect the first heat equalizing body 271 and the intermediate heat equalizing body 273.

The plurality of second connecting bodies 275 are arranged in a region where the head units 11b, 11d, 11f, 11h are not arranged in the region sandwiched between the second heat equalizing body 272 and the intermediate heat equalizing body 273. The plurality of second connecting bodies 275 extend along the front-rear direction, and connect the second heat equalizing body 272 and the intermediate heat equalizing body 273.

With the above configuration, the first heat equalizing body 271, the second heat equalizing body 272, and the intermediate heat equalizing body 273 are via the base 270, the plurality of first connecting bodies 274, and the plurality of second connecting bodies 275. They are in thermal contact with each other and are configured to be able to conduct heat with each other. As a result, even in this modification, the driver ICs 52 of the eight head units 11 can conduct heat to each other via the common heat sink 213, so that the temperature difference between the driver ICs 52 can be reduced. can.

Next, another modification of the common heat sink will be described with reference to FIGS. 16 and 17. As shown in FIGS. 16 and 17, the common heat sink 313 has a first heat sink 371 and a second heat sink 372.

The first heat sink 371 has a first plate body 381, a second plate body 382, and a third plate body 383. Both the first plate body 381 and the second plate body 382 are substantially rectangular plate-shaped bodies parallel to the vertical plane and with the left-right direction as the longitudinal direction. The first plate body 381 and the second plate body 382 are arranged side by side in the front-rear direction so as to sandwich the head units 11a, 11c, 11e, 11g in the front-rear direction. The rear surface of the first plate body 381 is in direct contact with the individual heat sinks 14a provided on the head units 11a, 11c, 11e, 11g. On the other hand, the front surface of the second plate body 382 is in direct contact with the individual heat sinks 14b provided on the head units 11a, 11c, 11e, 11g.

The third plate body 383 is a substantially rectangular plate-like body that is parallel to the horizontal plane and has the longitudinal direction in the left-right direction. Then, the third plate body 383 connects the upper end of the first plate body 381 and the upper end of the second plate body 382. Thereby, the first plate body 381 and the second plate body 382 can conduct heat to each other through the third plate body 383. Further, the third plate body 383 is formed with four through holes 383a that penetrate in the vertical direction corresponding to the head units 11a, 11c, 11e, and 11g. The tube connection portion 46, COF21a, and the like of the head units 11a, 11c, 11e, and 11g are inserted into the through hole 383a.

Since the second heat sink 372 has substantially the same structure as the first heat sink 371, each configuration of the second heat sink 372 is designated by adding "10" to the code of the configuration corresponding to the first heat sink 371. The explanation is omitted as appropriate.

The second heat sink 372 has a first plate body 391, a second plate body 392, and a third plate body 393, similarly to the first heat sink 371. The first plate body 391 and the second plate body 392 are arranged side by side in the front-rear direction so as to sandwich the head units 11b, 11d, 11f, 11h in the front-rear direction. The rear surface of the first plate body 391 is in direct contact with the individual heat sinks 14a provided on the head units 11b, 11d, 11f, 11h. On the other hand, the front surface of the second plate body 392 is in direct contact with the individual heat sinks 14b provided on the head units 11b, 11d, 11f, 11h.

The first plate body 391 and the second plate body 392 can conduct heat to each other via the third plate body 393. Further, the third plate body 393 is formed with four through holes 393a that penetrate in the vertical direction corresponding to the head units 11b, 11d, 11f, and 11h.

The second plate body 382 and the second plate body 392 so that the rear surface of the second plate body 382 of the first heat sink 371 and the front surface of the second plate body 392 of the second heat sink 372 face each other and are in direct contact with each other. And are fixed to each other. The fixing method between the second plate body 382 and the second plate body 392 is not particularly limited as long as it is a fixing method capable of conducting heat to each other, and for example, the second plate body 382. And the second plate body 392 are fixed with a heat conductive double-sided tape, or are fastened with a screw with a heat conductive grease sandwiched between them. With the above configuration, even in this modification, the driver ICs 52 of the eight head units 11 can conduct heat to each other via the common heat sink 313, so that the temperature difference between the driver ICs 52 can be reduced. Can be done. As a result, deterioration of recording quality can be suppressed.

In this modified form, the first plate body 381 of the first heat sink 371 corresponds to the "first heat soaking body". The second plate body 392 of the second heat sink 372 corresponds to the "second heat soaking body". Further, the second plate body 382 of the first heat sink 371 and the first plate body 391 of the second heat sink 372 correspond to the "intermediate heat soaking body".

Any of the common heat sinks 13, 113, 213, and 313 described above has a shape corresponding to the arrangement mode of the eight head units 11. That is, the common heat sinks 13, 113, 213, and 313 are the first average of the two head units 11 adjacent to each other in the left-right direction, which are lined up on the front side with respect to the head unit (first head unit) arranged on the front side. The heat portion (corresponding to the base wall 81, the first heat equalizing body 271, and the first plate body 381) and the head unit (second head unit) arranged on the rear side are lined up on the front side and the first heat equalizing body. Connection connecting the second heat equalizing part (corresponding to the facing wall 83, the intermediate heat equalizing body 273, the second plate body 382), the first heat equalizing part and the second heat equalizing part arranged behind the part. It has a portion (corresponding to a connection wall 84, a first connection body 274, and a third plate body 383). With this configuration, the common heat sinks 13, 113, 213, and 313 can be brought into contact with the driver ICs 52 of the eight head units 11 via the individual heat sinks 14, and the temperature between the driver ICs 52 of the eight head units 11 can be reached. The difference can be reduced.

Hereinafter, other modified forms will be described.

In the above embodiment, the individual heat sink 14 is supported by the unit main body portion 20, but is not particularly limited thereto, and may be supported by, for example, the housing 2. Further, the individual heat sink 14 itself may be an elastic material having thermal conductivity. In this case, the elastic members 68a and 68b are not essential because the elasticity of the individual heat sink 14 itself can absorb the deviation of the support position of the head unit 11 of the support member 12. Further, the individual heat sink 14 may not be configured to be rotatable.

Each head unit 11 is provided with four driver ICs 52, but is not limited to this, and may be one or more. Further, the inkjet head 4 is an inkjet head capable of ejecting four colors of ink, but is not limited to this, and may be an inkjet head capable of ejecting only one color of ink.

Further, the driver ICs 52 of the eight head units 11 may be arranged only on either the front side or the rear side with respect to the unit main body portion 20. For example, the driver ICs 52 of all eight head units 11 may be arranged on the front side with respect to the unit main body portion 20. In this case, the common heat sink 13 may have only the first heat soaking body 71 arranged on the front side with respect to the eight head units 11, and each head unit 11 has only the individual heat sink 14a. It may be provided.

The individual heat sink 14b has the same shape as the individual heat sink 14a rotated 180 degrees with respect to the horizontal plane, but may have a different shape. Further, the individual heat sink 14a and the individual heat sink 14b may have a shape symmetrical with respect to a line along the left-right direction.

The shape of the driver IC 52 of the embodiment is a rectangular parallelepiped, but the shape is not particularly limited to this, and may be, for example, a cube. Further, the individual heat sink 14 is configured to be rotatable about the longitudinal direction of the driver IC 52 as a rotation axis, but if it rotates about the driver IC 52 as an axis, it rotates in a direction intersecting the longitudinal direction of the driver IC 52. It may rotate as a moving axis.

As long as the number of head units 11 is 2 or more, the number is not limited. Further, the individual heat sink 14 is not essential, and the common heat sinks 13, 113, 213, and 313 may be configured to come into direct contact with the driver IC 52.

The inkjet head 4 of the embodiment is a so-called line type head whose position is fixed and does not move with respect to the recording paper 100 during image recording. On the other hand, it is also possible to apply the present invention to a so-called serial type head that ejects ink while moving in the width direction of the recording paper 100.

In the embodiment described above, the present invention is applied to an inkjet head that ejects ink onto recording paper to record an image or the like, but the liquid ejection head is used for various purposes other than recording images or the like. The present invention can also be applied to the above. For example, the present invention can be applied to a liquid discharge head that discharges a conductive liquid onto a substrate to form a conductive pattern on the surface of the substrate.

4 Inkjet head (liquid ejection head)
11 Head unit 13 Common heat sink (heat soaking unit)
14 Individual heat sink (individual radiator)
20 Unit body 52 Driver IC
71 1st heat soothing body 72 2nd heat soaking body

Claims (3)

With the first head unit
A second head unit that is aligned with the first head unit in the first direction and is arranged so as to be offset to one side of the second direction orthogonal to the first direction.
A heat equalizing unit common to the first head unit and the second head unit,
Equipped with
Each of the first head unit and the second head unit
A unit body equipped with an actuator that discharges liquid from multiple nozzles,
A first driver IC, which is arranged on one side of the second direction with respect to the unit main body and drives the actuator,
Equipped with
The heat equalizing unit is
A first heat soaking body arranged on one side of the second direction with respect to the first head unit and the second head unit.
An intermediate heat soaking body, which is arranged on one side of the second direction with respect to the first head unit and is arranged on the other side of the second direction with respect to the second head unit, is provided.
The first heat equalizing body and the intermediate heat equalizing body are in thermal contact with each other .
Each of the first head unit and the second head unit
A second driver IC, which is arranged on the other side of the second direction with respect to the unit main body and drives the actuator, is further provided.
The heat equalizing unit is
Further provided with a second heat soaking body arranged on the other side of the second direction with respect to the first head unit and the second head unit.
The first heat equalizing body, the intermediate heat equalizing body, and the second heat equalizing body are in thermal contact with each other.
In the unit main body of the first head unit and the unit main body of the second head unit, the end portions adjacent to each other in the first direction are arranged at the same position with respect to the first direction. ,
At least a part of the first driver IC of the first head unit is sandwiched between the unit main body of the first head unit and the unit main body of the second head unit in the second direction. A liquid discharge head characterized by being arranged in. At least a part of the intermediate heat equalizing body is arranged at a position sandwiched between the unit main body of the first head unit and the unit main body of the second head unit in the second direction. The liquid discharge head according to claim 1 . The intermediate heat soaking body is the second driver of the second head unit from the end position of the first driver IC of the first head unit opposite to the second head unit in the first direction. The liquid discharge head according to claim 2 , wherein the IC extends along the first direction toward an end position of the IC opposite to the first head unit in the first direction.

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