The present application is based on, and claims priority from JP Application Serial Number 2018-134267, filed Jul. 17, 2018, JP Application Serial Number 2019-052210, filed Mar. 20, 2019, JP Application Serial Number 2019-052211, filed Mar. 20, 2019, and JP Application Serial Number 2019-052212, filed Mar. 20, 2019, the disclosures of which are hereby incorporated by reference herein in their entirety.
The present disclosure relates to a head unit and a liquid-discharging apparatus.
A head unit proposed in related art forms an image on a recording medium by discharging a liquid such as an ink from nozzles. JP-A-2018-039174, for example, discloses a head unit that has a piezoelectric element driven by a driving signal, an integrated circuit that includes a switch circuit making a switchover as to whether to supply a driving signal to the piezoelectric element, the piezoelectric element being provided on a rigid wiring substrate, and a pressure chamber that enables a liquid to be discharged from nozzles according the driving of the piezoelectric element.
A driving signal that drives a piezoelectric element has a large amplitude. Therefore, when a switch circuit supplies a driving signal to the piezoelectric element, the switch circuit generates heat. When heat generated in the switch circuit is transmitted to the liquid in a pressure chamber through a rigid wiring substrate, the temperature of the liquid in the pressure chamber may rise. Then, the property of the liquid discharged from the pressure chamber changes. This is problematic in that the quality of an image formed by the liquid discharged from the head unit is lowered.
To solve the above problem, a head unit according a preferred aspect of the present disclosure has: a first member in which a pressure chamber that stores a liquid to be discharged from a nozzle is formed; a piezoelectric element disposed on the pressure chamber, the piezoelectric element undergoing a displacement in response to a driving signal; a first substrate disposed on the first member so as to cover the piezoelectric element; an integrated circuit disposed on the first substrate, the integrated circuit supplying the driving signal to the piezoelectric element; a second member disposed on the first member, a holding chamber being formed in the second member, the liquid being held in the holding chamber; and a third member formed from a metal, the third member being disposed on the second member. In the second member, a heat dissipation opening for dissipating heat generated in the integrated circuit is formed between the integrated circuit and the third member.
A head unit according a preferred aspect in the present disclosure has: a first member in which a pressure chamber that stores a liquid to be discharged from a nozzle is formed; a piezoelectric element disposed on the pressure chamber, the piezoelectric element undergoing a displacement in response to a driving signal; a first substrate disposed on the first member so as to cover the piezoelectric element; an integrated circuit disposed on the first substrate, the integrated circuit supplying the driving signal to the piezoelectric element; a second member disposed on the first member, a holding chamber being formed in the second member, the liquid being held in the holding chamber; and a third member formed from a metal, the third member being disposed on the second member. The third member has a first structural body and a second structural body. The piezoelectric device, the integrated circuit, and the first substrate are disposed between the first structural body and the second structural body.
An embodiment of the present disclosure will be described below with reference to the drawings. The dimensions and scales of individual sections and portions in the drawings differ from their actual dimensions and scales, as appropriate. Since an embodiment described below is a preferred specific example in the present disclosure, various limitations that are desirable from a technical viewpoint have been added. However, the scope of the present disclosure is not limited to these forms unless, in the explanation below, there is a particular description that limits the present disclosure.
A liquid-discharging apparatus 100 according to this embodiment will be described with reference to
As illustrated in
As illustrated in
In this embodiment, the controller 20 includes a processing circuit, such as a central processing unit (CPU) or a field-programmable gate array (FPGA), and a storage circuit such as a semiconductor memory, for example. The liquid-discharging apparatus 100 controls individual elements.
In this embodiment, the transport mechanism 22 transports the medium 12 in the +Y direction under control of the controller 20. In the description below, the +Y direction and −Y direction, which is opposite to the +Y direction, will be collectively referred to as the Y-axis direction.
In this embodiment, the moving mechanism 24 reciprocates the plurality of head units 26 in the +X direction and −X direction, which is opposite to the +X direction, under control of the controller 20. The +X direction crosses the +Y direction in which the medium 12 is transported. Typically, the +X direction is orthogonal to the +Y direction. In the description below, the +X direction and −X direction will be collectively referred to as the X-axis direction.
The moving mechanism 24 has a storage case 242 that accommodates the plurality of head units 26 and also has an endless belt 244 to which the storage case 242 is fixed. It is also possible to store the liquid vessel 14 in the storage case 242 together with the head units 26.
An ink is supplied from the liquid vessel 14 to the head unit 26. A driving signal Com that drives the head unit 26 and a control signal SI that controls the head unit 26 are also supplied from the controller 20 to the head unit 26. The head unit 26 is driven by the driving signal Com under control of the control signal SI and discharges an ink from part or all of 2M nozzles N in the +Z direction, M being a natural number equal to or larger than 1. The +Z direction crosses the +X direction and +Y direction. Typically, the +Z direction is orthogonal to the +X direction and +Y direction. In the description below, the +Z direction and the −Z direction, which is opposite to the +Z direction, will sometimes be collectively referred to as the Z-axis direction. The nozzle N will be described later with reference to
The head unit 26 discharges an ink from part or all of the 2M nozzles N in synchronization with the transport of the medium 12 by the transport mechanism 22 and the reciprocating motion of the storage case 242. The discharged ink is landed on the front surface of the medium 12, forming a desired image on the front surface of the medium 12.
In this embodiment, the storage case 242 internally stores a head module 260 in which four head units 26 are included, as illustrated in
The head unit 26 will be outlined below with reference to
As illustrated in
In this embodiment, a combination of the flow path substrate 32, pressure chamber substrate 34, and vibrating section 36 is an example of a first member, the rigid wiring substrate 38 is an example of a first substrate, the holding chamber forming substrate 40 is an example of a second member, and the external case 80 is an example of a third member.
The nozzle plate 52 is a plate-like member that is elongated in the Y-axis direction and extends in substantially parallel to an XY plane. On the nozzle plate 52, 2M nozzles N are formed. Here, “substantially parallel” indicates not only that the nozzle plate 52 is completely parallel to an XY plane but also that when error is taken into consideration, the nozzle plate 52 can be regarded to be parallel to an XY plane.
Each nozzle N is a hole formed in the nozzle plate 52. The nozzle plate 52 is manufactured by, for example, using a semiconductor manufacturing technology such as etching to process a monocrystalline silicon substrate. In the manufacturing of the nozzle plate 52, however, any known material and any known manufacturing method can be used.
In this embodiment, the 2M nozzles N are disposed in two rows, a row L1 and a row L2, which is positioned closer to the +X side than is the row L1, on the nozzle plate 52. In the description below, each of the M nozzles N included in the row L1 will sometimes be referred to as the nozzle N1 and each of the M nozzles N included in the row L2 will sometimes be referred to as the nozzle N2.
In this embodiment, a case will be assumed as an example in which there is a substantially match in positions in the Y-axis direction between the m-th nozzle N1, from the −Y side, of the M nozzles N1 in the row L1 and the m-th nozzle N2, from the −Y side, of the M nozzles N2 in the row L2. Here, m is a natural number in the range of 1 to M. “Substantial match” indicates not only that there is a complete match between the two positions but also that when error is taken into consideration, it can be regarded that there is a match between the two positions. However, the 2M nozzles N may be arranged so that there is a mismatch positions in the Y-axis direction between the m-th nozzle N1, from the −Y side, of the M nozzles N1 in the row L1 and the m-th nozzle N2, from the −Y side, of the M nozzles N2 in the row L2.
This embodiment assumes that the M nozzles N in each of the row L1 and row L2 is provided with a density of 400 or more nozzles N per inch on the nozzle plate 52. This embodiment also assumes that 800 or more nozzles N are provided on the nozzle plate 52. That is, this embodiment assumes that M is a natural number equal to or larger than 400.
The external case 80 is disposed on the surface of the nozzle substrate 50 on the −Z side.
The external case 80 has an upper lid 820 in a plate shape that is elongated in the Y-axis direction and extends in substantially parallel to an XY plane, a side surface 801 that is elongated in the Y-axis direction and extends in substantially parallel to an YZ plane, and a side surface 802 that is elongated in the Y-axis direction and extends in substantially parallel to an YZ plane on a side closer to the +X side than is the side surface 801. That is, the external case 80 has a concave portion 82 composed of the surface of the upper lid 820 on the +Z side, the surface of the side surface 801 on the +X side, and the surface of the side surface 802 on the −X side. In the description below, a space that is closer to the +Z side than is the upper lid 820, closer to the +X side than is the side surface 801, and closer to the −X side than is the side surface 802 will be referred to as the space inside the concave portion 82. As is clear from form
In this embodiment, the side surface 801, which is an example of a first structural body, is fixed to the surface of the nozzle substrate 50 on the −Z side. Also, in this embodiment, the side surface 802, which is an example of a second structural body, is fixed to the surface of the nozzle substrate 50 on the −Z side.
In the space inside the concave portion 82, the external case 80 also has a convex portion 810 in a rectangular parallelepiped shape on the surface of the upper lid 820 on the +Z side. The convex portion 810 is elongated in the Y-axis direction.
The external case 80 including the upper lid 820, side surface 801, side surface 802, and convex portion 810 is formed from, for example, a metal material having thermal conductivity equal to or higher than prescribed thermal conductivity. The prescribed thermal conductivity is higher than the thermal conductivity of, for example, the nozzle substrate 50, flow path substrate 32, pressure chamber substrate 34, vibrating section 36, piezoelectric element 37, rigid wiring substrate 38, holding chamber forming substrate 40, and ink. This embodiment assumes that the prescribed thermal conductivity is set to 200 W/mK, as an example. In this embodiment, therefore, a metal such as aluminum or copper, for example, can be used as the material of the external case 80.
As illustrated in
The flow path substrate 32 is a plate-like member that is elongated in the Y-axis direction and extends in substantially parallel to an XY plane. An ink flow path is formed in the flow path substrate 32. Specifically, in the flow path substrate 32, a flow path RA1 is formed in correspondence with the row L1 and a flow path RA2 is also formed in correspondence with the row L2. The flow path RA1 is an opening formed so as to be elongated in the Y-axis direction. The flow path RA2 is also an opening formed so as to be elongated along the Y-axis direction. The flow path RA2 is positioned along the +X direction when viewed from the flow path RA1.
In the flow path substrate 32, 2M flow paths 322 and 2M flow paths 324 are formed in one-to-one correspondence with the 2M nozzles N. As illustrated in
Two flow paths 326 are formed on the surface of the flow path substrate 32 on the +Z side. One of the two flow paths 326 links the flow path RA1 and M flow paths 322 disposed in one-to-one correspondence with the M nozzles N1 in the row L1 together. The other of the two flow paths 326 links the flow path RA2 and M flow paths 322 disposed in one-to-one correspondence with the M nozzles N2 in the row L2 together.
The flow path substrate 32 is manufactured by, for example, using a semiconductor manufacturing technology to process a monocrystalline silicon substrate. In the manufacturing of the flow path substrate 32, however, any known material and any known manufacturing method can be used.
As illustrated in
The pressure chamber substrate 34 is a plate-like member that is elongated in the Y-axis direction and extends in substantially parallel to an XY plane. In the pressure chamber substrate 34, 2M openings 342 are formed in one-to-one correspondence with the 2M nozzles N.
The pressure chamber substrate 34 is manufactured by, for example, using a semiconductor manufacturing technology to process a monocrystalline silicon substrate. In the manufacturing of the pressure chamber substrate 34, however, any known material and any known manufacturing method can be used.
As illustrated in
As illustrated in
In the head unit 26, 2M pressure chambers are provided in one-to-one correspondence with the 2M nozzles N. As illustrated in
As illustrated in
As described above, the piezoelectric element 37 deforms in response to a driving signal Com supplied to it. The vibrating section 36 vibrates in synchronization with the deformation of the piezoelectric element 37. When the vibrating section 36 vibrates, the pressure in the pressure chamber varies. When the pressure in the pressure chamber vibrates, the ink in the pressure chamber passes through the flow path 324 and is charged from the nozzle N.
A combination of the pressure chamber, flow path 324, nozzle N, vibrating section 36, and piezoelectric element 37 functions as a discharging section that discharges the ink supplied in the pressure chamber. A combination of 2M discharging sections and the nozzle plate 52, which are provided in the head unit 26, will sometimes be referred to as the discharging head.
As illustrated in
The rigid wiring substrate 38 is a plate-like member that is elongated in the Y-axis direction and extends in substantially parallel to an XY plane. The rigid wiring substrate 38 protects the 2M piezoelectric elements 37 formed on the vibrating section 36.
The rigid wiring substrate 38 is manufactured by, for example, using a semiconductor manufacturing technology to process a monocrystalline silicon substrate. In the manufacturing of the rigid wiring substrate 38, however, any known material and any known manufacturing method can be used.
As illustrated in
As illustrated in
The switch circuit provided on the integrated circuit 62 makes a switchover under control of the control signal SI as to whether to supply a driving signal Com to each piezoelectric element 37. Although this embodiment assumes that the driving signal Com is created in the controller 20, the driving signal Com may be created in the integrated circuit 62.
As illustrated in
As illustrated in
In this embodiment, therefore, the amount of heat that is generated in the integrated circuit 62 and is dissipated from the integrated circuit 62 to the outside of the head unit 26 through the convex portion 810 and upper lid 820 is larger than the amount of heat that is generated in the integrated circuit 62 and is transmitted to the ink supplied in the pressure chamber from the integrated circuit 62 through all or part of the rigid wiring substrate 38, piezoelectric element 37, and vibrating section 36. That is, in this embodiment, since the head unit 26 includes the external case 80, it is possible to reduce the extent to which the temperature of the ink supplied in the pressure chamber is raised due to heat generated in the integrated circuit 62 when compared with, for example, a case in which the external case 80 is not provided.
In this embodiment, the side surface 801 and side surface 802 are fixed to the vibration absorbing body 54 as described above. Therefore, even when heat generated in the integrated circuit 62 is transferred to the ink in the pressure chamber, the heat transferred to the ink in the pressure chamber can be dissipated to the outside of the head unit 26 through the ink in the flow path 322, the ink in the flow path 326, the vibration absorbing body 54, and the side surface 801 or side surface 802. That is, in this embodiment, since the external case 80 is provided, it is possible to reduce the extent to which the temperature of the ink supplied in the pressure chamber is raised due to heat generated in the integrated circuit 62 when compared with, for example, a case in which the external case 80 is not provided.
As illustrated in
As illustrated in
As illustrated in
The holding chamber forming substrate 40 is a member elongated in the Y-axis direction. The holding chamber forming substrate 40 includes a holding chamber RB1 that holds an ink to be supplied to the M pressure chambers corresponding to the M nozzles N1 through the flow path RA1, the holding chamber RB1 being a space elongated in the Y-axis direction. The holding chamber forming substrate 40 also includes a holding chamber RB2 that holds an ink to be supplied to the M pressure chambers corresponding to the M nozzles N2 through the flow path RA2, the holding chamber RB2 being a space elongated in the Y-axis direction. The holding chamber RB1 is an example of a first holding chamber, and the holding chamber RB2 is an example of a second holding chamber.
A concave portion 42 is formed in the surface of the holding chamber forming substrate 40 on the +Z side. The pressure chamber substrate 34, vibrating section 36, plurality of piezoelectric elements 37, rigid wiring substrate 38, and integrated circuit 62 are accommodated in a space inside the concave portion 42. Specifically, as seen from
The flexible wiring board 64 joined to the area E on the rigid wiring substrate 38 extends in the Y-axis direction so as to pass through the interior of the concave portion 42. As seen from
A heat dissipation opening 48 is formed in the holding chamber forming substrate 40 so as to pass through the holding chamber forming substrate 40 in the Z-axis direction. In this embodiment, the convex portion 810 in the external case 80 is disposed so as to pass through the interior of the heat dissipation opening 48 in the space between the upper lid 820 and the heat transfer agent 90 applied to the +Z side of the integrated circuit 62. As seen from
In this embodiment, the holding chamber forming substrate 40 is formed from a material separate from the materials of the flow path substrate 32 and pressure chamber substrate 34. Specifically, the holding chamber forming substrate 40 is formed by, for example, being injection-molded with a resin material. In the manufacturing of the holding chamber forming substrate 40, however, any known material and any known manufacturing method can be used. Synthetic fiber such as poly-phenylene benzobisoxazole fiber or a resin material such as a liquid crystal polymer, for example, is preferable as the material of the holding chamber forming substrate 40.
An introduction port 831 and an introduction port 832 are formed in the external case 80. An introduction port 431 communicating with the introduction port 831 and holding chamber RB1 and an introduction port 432 communicating with the introduction port 832 and holding chamber RB2 are also formed in the holding chamber forming substrate 40. An ink is supplied from the liquid vessel 14 through the introduction port 831 and introduction port 431 to the holding chamber RB1. Similarly, an ink is supplied from the liquid vessel 14 through the introduction port 832 and introduction port 432 to the holding chamber RB2.
The ink supplied from the liquid vessel 14 to the introduction port 831 passes through the introduction port 431 and holding chamber RB1 and flows into the flow path RA1. Part of the ink that has flowed into the flow path RA1 is supplied to the pressure chamber corresponding to the nozzle N1 through the flow path 326 and flow path 322. The ink supplied to the pressure chamber corresponding to the nozzle N1 flows through the flow path 324 in the +Z direction and is discharged from the nozzle N1.
The ink supplied from the liquid vessel 14 to the introduction port 832 passes through the introduction port 432 and holding chamber RB2 and flows into the flow path RA2. Part of the ink that has flowed into the flow path RA2 is supplied to the pressure chamber corresponding to the nozzle N2 through the flow path 326 and flow path 322. The ink supplied to the pressure chamber corresponding to the nozzle N2 flows through the flow path 324 in the +Z direction and is discharged from the nozzle N2.
As illustrated in
As described above, since the head unit 26 according to this embodiment has the external case 80, it is possible to lower the possibility that the temperature of ink at the discharging section.
To clarify the advantages of the head unit 26 according to this embodiment, a head unit 26W provided in a head module 260W included in a liquid-discharging apparatus in a reference example will be described below.
As illustrated in
As described above, the head unit 26W lacks the external case 80 made of a material having thermal conductivity equal to higher than the prescribed thermal conductivity. In other words, all the constituent components of the head unit 26W are made of materials having thermal conductivity lower than the prescribed thermal conductivity. That is, the head unit 26W cannot efficiently dissipate heat generated in the integrated circuit 62 to the outside of the head unit 26W. In the head unit 26W, therefore, the ink supplied in the pressure chamber may become hot due to heat generated in the integrated circuit 62.
In contrast to this, the head unit 26 according to this embodiment has the external case 80 made of a material having thermal conductivity equal to higher than the prescribed thermal conductivity. In the head unit 26 according to this embodiment, the external case 80 is disposed so that the distance D1 between the external case 80 and the integrated circuit 62 is shorter than the distance D2 between the integrated circuit 62 and the piezoelectric element 37. Therefore, the amount of heat that the head unit 26 dissipates to the outside of the head unit 26, the heat being part of heat generated in the integrated circuit 62, is larger than the amount of heat that the head unit 26W dissipates to the outside of the head unit 26W, the heat being part of heat generated in the integrated circuit 62. Therefore, the amount of heat that the head unit 26 transfers from the integrated circuit 62 to the ink supplied in the pressure chamber is smaller than the amount of heat that the head unit 26W transfers from the integrated circuit 62 to the ink supplied in the pressure chamber. In other words, according to this embodiment, it is possible to reduce the extent to which the temperature of the ink supplied in the pressure chamber is raised due to heat generated in the integrated circuit 62 when compared with, for example, the reference example. Thus, according to this embodiment, it is possible to reduce the possibility that the quality of an image formed by the liquid-discharging apparatus 100 is lowered due to heat generated in the integrated circuit 62 when compared with, for example, the reference example.
In
T3=T2+ΔT
T2=T1+ΔT
T1=T0+ΔT
Since all the constituent components of the head unit 26W included in the liquid-discharging apparatus in the reference example are made of materials having thermal conductivity lower than the prescribed thermal conductivity as described above, the head unit 26W cannot efficiently dissipate heat generated in the integrated circuit 62. Therefore, a portion of the head unit 26W near its center is likely to become hotter than the edges of the head unit 26W in a plan view in the Z-axis direction. In particular, when 800 or more discharging sections are provided in the head unit 26W with a density of 400 or more discharging sections per inch, the possibility that the temperature of a portion of the head unit 26W near its center becomes higher than the temperature of the edges of the head unit 26W is increased.
Specifically, in the head unit 26W, a nozzle N-Wa is positioned in an area Ar-2, a nozzle N-Wb is positioned in an area Ar-3, and a nozzle N-Wc is positioned in an area Ar-4, the nozzles N-Wa, N-Wb, and N-Wc being included in the 2M nozzles N provided in the head unit 26W, as indicated in the temperature distribution map MP-W in
In contrast to this, since the head unit 26 provided in the liquid-discharging apparatus 100 according to this embodiment has the external case 80 made of a material having thermal conductivity equal to higher than the prescribed thermal conductivity, the head unit 26 can more efficiently dissipate heat generated in the integrated circuit 62 than the head unit 26W. Thus, even when 800 or more discharging sections are provided in this embodiment with a density of 400 or more discharging sections per inch, it is possible to reduce the temperature difference between a portion near the center of the head unit 26 and its edges below the temperature difference between a portion near the center of the head unit 26W and its edges.
Specifically, of the 2M nozzles N provided in the head unit 26, the nozzles N-a, N-b, and N-c are all positioned in the area Ar-1, as indicted by the temperature distribution map MP in
With the liquid-discharging apparatus 100 according to this embodiment, since the fan 250 is provided in the storage case 242, the temperature of the whole of the head unit 26 can be made lower than in, for example, an aspect in which the fan 250 is not provided in the storage case 242. Thus, with the liquid-discharging apparatus 100 according to this embodiment, it is possible to reduce the extent to which the quality of an image formed by the liquid-discharging apparatus 100 is lowered due to heat generated in the integrated circuit 62 when compared with an aspect in which the fan 250 is not provided in the storage case 242.
In this embodiment, one nozzle N of the M nozzles N arranged in the Y-axis direction is an example of a first nozzle, and each of the other nozzles N is an example of a second nozzle. In this embodiment, a pressure chamber disposed in correspondence with the first nozzle is an example of a first pressure chamber, and a pressure chamber disposed in correspondence with the second nozzle is an example of a second pressure chamber. In this embodiment, the piezoelectric element 37 disposed in correspondence with the first nozzle is an example of a first piezoelectric element, and the piezoelectric element 37 disposed in correspondence with the second nozzle is an example of a second piezoelectric element. In this embodiment, a common flow path is a general name for the flow path RA1 and flow path RA2.
The embodiment exemplified above can be varied in various ways. Aspects of specific variations will be exemplified below. Two or more aspects arbitrarily selected from examples below can be combined within a range in which any mutual contradiction does not occur.
Although, in the embodiment described above, the external case 80 provided in the head unit 26 has the convex portion 810, the present disclosure is not limited to this aspect. The external case 80 may be structured without the convex portion 810.
As illustrated in
In the head unit 26A, the side surface 801 and side surface 802 of the external case 80A are fixed to the vibration absorbing body 54. In this variation, therefore, even when heat generated in the integrated circuit 62 is transferred to the ink supplied in the pressure chamber, the heat transferred to the ink supplied in the pressure chamber can be dissipated to the outside of the head unit 26A through the ink in the flow paths 322 and flow paths 326, the vibration absorbing body 54, and the side surface 801 or side surface 802.
In the head unit 26A, a nozzle N-Aa and a nozzle N-Ab are positioned in the area Ar-1, and a nozzle N-Ac is positioned in an area Ar-2, the nozzles N-Aa, N-Ab, and N-Ac being included in the 2M nozzles N provided in the head unit 26A, as indicated in the temperature distribution map MP-A in
Although, in the embodiment described above, the external case 80 provided in the head unit 26 has the convex portion 810, the side surface 801, and side surface 802, the present disclosure is not limited to this aspect. The external case 80 may be structured without the convex portion 810, the side surface 801, and side surface 802.
As illustrated in
In the head unit 26B, the upper lid 820 of the external case 80B is fixed to the holding chamber forming substrate 40W. In this variation, therefore, even when heat is generated in the integrated circuit 62, the heat can be dissipated to the outside of the head unit 26B through the rigid wiring substrate 38, vibrating section 36, pressure chamber substrate 34, and holding chamber forming substrate 40W.
In the head unit 26B, a nozzle N-Ba is positioned in the area Ar-1, a nozzle N-Bb is positioned in the area Ar-2, and a nozzle N-Bc is positioned in the area Ar-3, the nozzles N-Ba, N-Bb, and N-Bc being included in the 2M nozzles N provided in the head unit 26B, as indicated in the temperature distribution map MP-B in
Although, a case in which the head unit 26 included in the liquid-discharging apparatus 100 has the heat transfer agent 90 has been described in the above embodiment, the present disclosure is not limited to this aspect. The liquid-discharging apparatus 100 may be structured without the heat transfer agent 90.
Although, in the embodiment and first to third variations described above, a serial liquid-discharging apparatus in which the storage case 242 in which head units are mounted is reciprocated has been exemplified, the present disclosure is not limited to this aspect. The liquid-discharging apparatus may be a line liquid-discharging apparatus in which a plurality of nozzles N are distributed across the width of the medium 12.
In the embodiment and first to fourth variations described above, structures in which an ink exits from an pressure chamber and enters the flow path 324, after which the ink is discharged from the nozzle N corresponding to the pressure chamber have been exemplified for the head units 26, 26A, and 26C. However, the present disclosure is not limited to this aspect. The liquid-discharging apparatus may have a structure in which part or all of the ink in a pressure chamber can be exhausted from other than the nozzle N corresponding to the pressure chamber.
The flow path substrate 32D differs from the flow path substrate 32 in the above embodiment in that the flow path substrate 32D is a member that is elongated in the Y-axis direction and has M flow paths RX1 in one-to-one correspondence with the M nozzles N1, M flow paths RX2 in one-to-one correspondence with the M nozzles N2, and one flow path RC elongated in the Y-axis direction. The flow path RX1 provided in correspondence with one nozzle N1 links the flow path 324 corresponding to the one nozzle N1 and the flow path RC together. The flow path RX2 provided in correspondence with one nozzle N2 links the flow path 324 corresponding to the one nozzle N2 and the flow path RC together. The flow path RX1, flow path RX2, and flow path RC are each an example of an exhausting flow path.
The holding chamber forming substrate 40D differs from the holding chamber forming substrate 40 in the above embodiment in that the holding chamber forming substrate 40D is a member that is elongated in the Y-axis direction and has two heat dissipation openings 48, one of which corresponds to the row L1 and the other of which corresponds to the row L2, instead of one heat dissipation opening 48, one flow path RD elongated in the Y-axis direction is provided, the flow path RD communicating with the flow path RC, and an introduction port 433 communicating with the flow path RD is provided. The flow path RD is an example of an exhausting chamber.
One of the two pressure chamber substrates 34D provided in the head unit 26D is a pressure chamber substrate 34D that is elongated in the Y-axis direction and has M openings 342 corresponding to the M nozzles N1, and the other is a pressure chamber substrate 34D that is elongated in the Y-axis direction and has M openings 342 corresponding to the M nozzles N2. That is, each pressure chamber substrate 34D differs from the pressure chamber substrate 34 in the above embodiment in that, of the 2M pressure chambers provided in the head unit, only the M pressure chambers corresponding to either the row L1 or row L2, whichever is applicable, are formed.
One of the two vibrating sections 36D provided in the head unit 26D is a vibrating section 36D that is elongated in the Y-axis direction and constitutes the wall surfaces of the M openings 342 corresponding to the M nozzles N1, and the other is a vibrating section 36D that is elongated in the Y-axis direction and constitutes the wall surfaces of the M openings 342 corresponding to the M nozzles N2. That is, each vibrating section 36D differs from the vibrating section 36 in the above embodiment in that the vibrating section 36D forms the wall surfaces of only the M pressure chambers, included in the 2M pressure chambers provided in the head unit, that correspond to the row L1 or row L2, whichever is applicable.
One of the two rigid wiring substrates 38D provided in the head unit 26D is a rigid wiring substrate 38D that is elongated in the Y-axis direction and protects the M piezoelectric elements 37 corresponding to the M nozzles N1, and the other is a rigid wiring substrate 38D that is elongated in the Y-axis direction and protects the M piezoelectric elements 37 corresponding to the M nozzles N2. That is, each rigid wiring substrate 38D differs from the rigid wiring substrate 38 in the above embodiment in that the rigid wiring substrate 38D can accommodate only the M piezoelectric elements 37, included in the 2M piezoelectric elements 37 provided in the head unit, that correspond to either the row L1 or row L2, whichever is applicable.
One of the two integrated circuits 62D provided in the head unit 26D is an integrated circuit 62D that supplies a driving signal Com to the M piezoelectric elements 37 corresponding to the M nozzles N1, and the other is an integrated circuit 62D that supplies a driving signal Com to the M piezoelectric elements 37 corresponding to the M nozzles N2. That is, each integrated circuit 62D differs from the integrated circuit 62 in the above embodiment in that the integrated circuit 62D can supply a driving signal Com only to the M piezoelectric elements 37, included in the 2M piezoelectric elements 37 provided in the head unit, that correspond to either the row L1 or row L2, whichever is applicable.
The external case 80D differs from the external case 80 in the above embodiment in that the external case 80D is a member that is elongated in the Y-axis direction and has two convex portions 810, one of which corresponds to the row L1 and the other of which corresponds to the row L2, instead of one convex portion 810, and an introduction port 833 communicating with the introduction port 433 is provided.
In the head unit 26D illustrated in
As described above, in the head unit 26D, the ink in the pressure chamber not only can be discharged from the nozzle N but also can be exhausted from the flow path RC and flow path RD to the outside of the head unit 26D through the flow path RX1 or flow path RX2. Thus, with the head unit 26D, it is possible to activate the circulation of the ink in the pressure chamber when compared with an aspect in which the neither flow path RC nor the flow path RD is provided in the head unit. This makes it possible to lower the possibility that the ink in the pressure chamber becomes more viscous and to lower the possibility that the ink in the pressure chamber becomes hotter.
In the head unit 26D, the ink that has been exhausted from the introduction port 833 to the outside of the head unit 26D may be introduced into the head unit 26D again from the introduction port 831 and introduction port 832.
The flow path substrate 32E differs from the flow path substrate 32 in the above embodiment in that the flow path substrate 32E is a member that is elongated in the Y-axis direction and has M flow paths RZ in one-to-one correspondence with the M nozzles N1 and M flow paths 328 in one-to-one correspondence with the M nozzles N1. The flow path RZ provided in correspondence with one nozzle N1 links the flow path 324 corresponding to the one nozzle N1 and the flow path 328 corresponding to the one nozzle N1 together. The flow path 328 provided in correspondence with one nozzle N1 links the flow path RZ corresponding to the one nozzle N1 and the RA2 together.
The pressure chamber substrate 34E differs from the pressure chamber substrate 34 in the above embodiment in that the pressure chamber substrate 34E is a member that is elongated in the Y-axis direction and has only the M pressure chambers corresponding to the row L1 instead of the 2M pressure chambers.
The nozzle plate 52E differs from the nozzle plate 52 in the above embodiment in that the nozzle plate 52E is a member that is elongated in the Y-axis direction and has only the M nozzles N1 corresponding to the row L1 instead of the 2M nozzles N.
In the head unit 26E illustrated in
As described above, in the head unit 26E, the ink in the pressure chamber not only can be discharged from the nozzle N but also can be exhausted from the introduction port 832 to the outside of the head unit 26E through the flow path RZ and flow path 328. Thus, with the head unit 26E, it is possible to activate the circulation of the ink in the pressure chamber when compared with an aspect in which the neither flow path RZ nor the flow path 328 is provided in the head unit. This makes it possible to lower the possibility that the ink in the pressure chamber becomes more viscous and to lower the possibility that the ink in the pressure chamber becomes hotter.
In the head unit 26E, the ink that has been exhausted from the introduction port 832 to the outside of the head unit 26E may be introduced into the head unit 26E again from the introduction port 831.
In this variation, the sealing space 382, in the embodiment and the first to fifth variations described above, between the vibrating section 36 or vibrating section 36D and the rigid wiring substrate 38 or rigid wiring substrate 38D will be described in detail.
In the flow path substrate 32, a wall 321 is formed between the flow path 324 corresponding to one nozzle N and the flow path 324 corresponding to another nozzle N adjacent to the one nozzle N in the Y-axis direction, as illustrated in
Thus, in the example illustrated in
The example in
In the example in
In the example in
In the example in
Thus, in the example in
Although, in the example in
In the example in
The example in
In the example in
In this variation, the head modules 260, 260A, and 260B in the embodiment and the first to sixth variations described above will be described in detail.
As illustrated in
The support 71 is, for example, a plate-like member that extends in substantially parallel to an XY plane. The support 71 may be formed from, for example, a metal material such as stainless steel. The nozzle substrate 50 for each head unit 26 is fixed to the surface of the support 71 on the −Z side. Although not illustrated, the nozzle substrate 50 may have a fixture that fixes the vibration absorbing body 54 to the flow path substrate 32. In this case, the fixture provided for each head unit 26 may be fixed to the support 71.
In the support 71, an opening Op is formed on the +Z side of each nozzle N included in each head unit 26 fixed to the support 71. Specifically, the opening Op is formed in, for example, an area, on the support 71, in which the opening Op overlaps the nozzle plate 52 included in the head unit 26 when viewed from the +Z side. Therefore, the head unit 26 can land ink discharged from each nozzle N onto the medium 12 without being impeded by the support 71.
The accommodating body 72 has: a flat plate 720 positioned on the −Z side of the plurality of head units 26; a side wall 721 positioned closer to the +X side than are the plurality of head units 26, the side wall 721 coupling the flat plate 720 and support 71 together; a side wall 722 positioned closer to the −X side than are the plurality of head units 26, the side wall 722 coupling the flat plate 720 and support 71 together; and a plurality of partition plates 723 positioned between the side wall 721 and side wall 722, each partition plate 723 separating two of the plurality of head units 26, the two head units 26 being mutually adjacent in the X-axis direction, from each other. The accommodating body 72 may be formed from, for example, a metal material, such as aluminum or copper, that has higher thermal conductivity than the support 71. It is preferable for the accommodating body 72 to have thermal conductivity equal to or higher than the thermal conductivity of the external case 80.
In this variation, the external case 80 of each head unit 26 is fixed to the surface of the flat plate 720 on the +Z side with an adhesive BD. A through flow path RK1, through which ink is supplied from the liquid vessel 14 to the introduction port 831, and a through flow path RK2, through which ink is supplied from the liquid vessel 14 to the introduction port 832, are formed in the flat plate 720 and adhesive BD.
As described above, in this variation, the head module 260 has the support 71 that supports head units 26 and also has the accommodating body 72 fixed to the head units 26 and support 71. Accordingly, heat generated in the integrated circuit 62 is transferred to the accommodating body 72 through the external case 80, nozzle substrate 50, and support 71, and is also transferred to the accommodating body 72 through the external case 80 and adhesive BD. Since the accommodating body 72 is disposed so as to cover the plurality of head units 26, the accommodating body 72 has a larger surface area than each head unit 26. That is, the accommodating body 72 functions as a heat sink for the head unit 26. According to this variation, therefore, heat generated in the integrated circuit 62 can be more efficiently dissipated to the outside of the head module 260 than when the head module 260 lacks the support 71 and accommodating body 72.
When a head unit 26K that discharges black ink is included as one of the four head units 26, the head unit 26K is disposed between the side wall 721 and the partition plate 723 nearest to it or between the side wall 722 and the partition plate 723 nearest to it. That is, the head unit 26K is disposed at the end of the head module 260 on the +X side or −X side.
In print processing to form an image on the medium 12, black ink is generally more consumed than inks in other colors. Therefore, a change in the temperature or viscosity of black ink more greatly affects image quality than a change in the temperature or viscosity of inks in other colors.
Since, in this variation, the head unit 26K is disposed at an end of the head module 260, however, it is possible to reduce the extent to which image quality is lowered in print processing when compared with an aspect in which the head unit 26K is disposed at the center of the head module 260.
Although, a case in which the accommodating body 72 has a plurality of partition plates 723 has been exemplified in
Although a structure in which the nozzle substrate 50 has the vibration absorbing body 54 has been exemplified in the embodiment and the first to seventh variations described above, the present disclosure is not limited to this aspect. The nozzle substrate 50 may be structured without the vibration absorbing body 54.
Although the piezoelectric element 37 has been exemplified as a constituent element that applies pressure to the interior of the pressure chamber in the embodiment and the first to eighth variations described above, the present disclosure is not limited to this aspect. As a constituent element that applies pressure to the interior of the pressure chamber, a heat generating element may be used that heats the pressure chamber to generate bubbles in the pressure chamber and thereby to change pressure in it. A heat generating element is a constituent element in which a heat generating body generates heat when a driving signal Com is supplied. As understood from the above exemplary examples, the constituent element that applies pressure to the interior of the pressure chamber only needs to be an element that discharges the liquid in the pressure chamber from the nozzle N, that is, an element that applies pressure to the interior of the pressure chamber; there is no limitation on the operation method or a specific structure.
The liquid-discharging apparatus exemplified in the embodiment and the first to ninth variations described above can be used not only in units specific to printing but also in other various units such as facsimile machines and copiers. Of course, applications of the liquid-discharging apparatus in the present disclosure are not limited to printing. For example, a liquid-discharging apparatus that discharges a solution of a color material is used a manufacturing apparatus that forms a color filter for a liquid crystal display unit. In another example, a liquid-discharging apparatus that discharges a solution of a conductive material is used as a manufacturing apparatus that forms wires and electrodes on a wiring board.
Number | Date | Country | Kind |
---|---|---|---|
2018-134267 | Jul 2018 | JP | national |
2019-052210 | Mar 2019 | JP | national |
2019-052211 | Mar 2019 | JP | national |
2019-052212 | Mar 2019 | JP | national |