The present application is based on, and claims priority from JP Application Serial Number 2020-014627, filed Jan. 31, 2020, the disclosure of which is hereby incorporated by reference herein in its entirety.
Embodiments of the present disclosure relate to a liquid ejecting head and a liquid ejecting apparatus.
A technique regarding a liquid ejecting head that ejects liquid in pressure compartments from nozzles is known in the art as disclosed in JP-A-2017-013390.
However, in the art, there is a risk that ejection abnormality, a phenomenon of having difficulty in ejecting liquid from a nozzle, might occur due to the presence of an air bubble staying in a flow passage leading from a pressure compartment to a nozzle.
A liquid ejecting head according to a certain aspect of the present disclosure includes: a first pressure compartment that extends in a first direction and applies pressure to liquid; a second pressure compartment that extends in the first direction and applies pressure to liquid; a nozzle flow passage that extends in the first direction and is in communication with a nozzle from which liquid is ejected; a first communication flow passage that extends in a second direction intersecting with the first direction and provides communication between the first pressure compartment and the nozzle flow passage; a second communication flow passage that extends in the second direction and provides communication between the second pressure compartment and the nozzle flow passage; a supply flow passage from which liquid is supplied to the first pressure compartment; and a discharge flow passage to which liquid is discharged from the second pressure compartment; wherein wall surfaces of the second pressure compartment include a first wall surface that extends in the first direction and is most distant from the nozzle in the second direction, wall surfaces of the second communication flow passage include a second wall surface that extends in the second direction and is most distant from the nozzle in the first direction and a third wall surface that is opposite of the second wall surface in the first direction, a first sloped portion is provided between the first wall surface and the third wall surface, and the first sloped portion includes a first constituting surface that extends in a third direction between the first direction and the second direction.
A liquid ejecting apparatus according to a certain aspect of the present disclosure includes: a first pressure compartment that extends in a first direction and applies pressure to liquid; a second pressure compartment that extends in the first direction and applies pressure to liquid; a nozzle flow passage that extends in the first direction and is in communication with a nozzle from which liquid is ejected; a first communication flow passage that extends in a second direction intersecting with the first direction and provides communication between the first pressure compartment and the nozzle flow passage; a second communication flow passage that extends in the second direction and provides communication between the second pressure compartment and the nozzle flow passage; a supply flow passage from which liquid is supplied to the first pressure compartment; and a discharge flow passage to which liquid is discharged from the second pressure compartment; wherein wall surfaces of the second pressure compartment include a first wall surface that extends in the first direction and is most distant from the nozzle in the second direction, wall surfaces of the second communication flow passage include a second wall surface that extends in the second direction and is most distant from the nozzle in the first direction and a third wall surface that is opposite of the second wall surface in the first direction, a first sloped portion is provided between the first wall surface and the third wall surface, and the first sloped portion includes a first constituting surface that extends in a third direction between the first direction and the second direction.
With reference to the accompanying drawings, an exemplary embodiment of the present disclosure will now be explained. In the drawings, however, the dimensions and scales of components may be made different as needed from those in actual implementation. Since the embodiment described below shows some preferred examples of the present disclosure, they contain various technically-preferred limitations. However, the scope of the present disclosure is not limited to the examples described below unless any intention of restriction is mentioned explicitly.
With reference to
As illustrated in
As illustrated in
With reference to
As illustrated in
As illustrated in
As illustrated in
As illustrated in
In the description below, an ink flow passage providing communication between the supply flow passage RA1 and the discharge flow passage RA2 is referred to as a circulation flow passage RJ. As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
In the present embodiment, ink supplied to the feed inlet 51 from the liquid container 93 flows through the supply flow passage RB1 into the supply flow passage RA1. Then, a part of the ink that has flowed into the supply flow passage RA1 flows through the communication flow passage RX1 and the communication flow passage RK1 into the pressure compartment CB1. A part of the ink that has flowed into the pressure compartment CB1 flows through the communication flow passage RR1, the nozzle flow passage RN, and the communication flow passage RR2 into the pressure compartment CB2. Then, a part of the ink that has flowed into the pressure compartment CB2 flows through the communication flow passage RK2, the communication flow passage RX2, the discharge flow passage RA2, and the discharge flow passage RB2 to be discharged through the discharge outlet 52. When the piezoelectric element PZ1 is driven by the drive signal Coml, a part of ink with which the inside of the pressure compartment CB1 is filled flows through the communication flow passage RR1 and the nozzle flow passage RN to be ejected from the nozzle N. When the piezoelectric element PZ2 is driven by the drive signal Com2, a part of ink with which the inside of the pressure compartment CB2 is filled flows through the communication flow passage RR2 and the nozzle flow passage RN to be ejected from the nozzle N.
As illustrated in
As explained above, in the liquid ejecting head 1 according to the present embodiment, ink is circulated from the supply flow passage RA1 to the discharge flow passage RA2 through the circulation flow passage RJ. For this reason, in the present embodiment, even if there is a period during which no ink inside the pressure compartment CBq is ejected from the nozzle N, it is possible to prevent the ink from remaining stayed inside the pressure compartment CBq, the nozzle flow passage RN, etc. Therefore, in the present embodiment, even if there is a period during which no ink inside the pressure compartment CBq is ejected from the nozzle N, it is possible to prevent the viscosity of the ink inside the pressure compartment CBq from increasing. This makes it possible to prevent the occurrence of ejection abnormality in which it is impossible to perform ejection from the nozzle N properly due to the increased viscosity of the ink.
The liquid ejecting head 1 according to the present embodiment is able to eject ink contained inside the pressure compartment CB1 and is able to eject ink contained inside the pressure compartment CB2, from the nozzle N. For this reason, for example, as compared with an embodiment in which ink contained inside a single pressure compartment CBq only is ejected from the nozzle N, it is possible to increase the amount of ink ejected from the nozzle N.
With reference to
As illustrated in
As illustrated in
As illustrated in
As illustrated in
In the present embodiment, the nozzle N is provided substantially at the center of the nozzle flow passage RN. For example, the distance from the nozzle N to the wall surface HRb1 in the X-axis direction may be substantially the same as the distance from the nozzle N to the wall surface HRb 2 in the X-axis direction. The concept of “substantially at the center” herein includes not only a case of being exactly at the center but also a case of being able to be deemed as being at the center, with a margin of error taken into consideration.
For the purpose of making the effects of the present embodiment clear, with reference to
When ink flows from the supply flow passage RA1 to the discharge flow passage RA2 through the circulation flow passage RJZ in the liquid ejecting head 1Z according to the referential example, the speed of the flow of the ink decreases at a boundary area An where the wall surface HC2 and the wall surface HC21 meet with each other and at a boundary area Ar2 where the wall surface HC2 and the wall surface HC22 meet with each other, and the stagnation of the ink occurs. This increases the possibility that an air bubble formed inside the circulation flow passage RJZ will stay at the area Ar1/Ar2. In the liquid ejecting head 1Z according to the referential example, when the piezoelectric element PZ2 is driven by the drive signal Com2 in an attempt to eject ink inside the pressure compartment CB2Z from the nozzle N, pressure for forcing the ink out by the piezoelectric element PZ2 might be absorbed by an air bubble staying at the area An or at the area Ar2 of the pressure compartment CB2Z, and so-called ejection abnormality, a phenomenon of having difficulty in ejecting the ink from the nozzle N, might occur. If such ejection abnormality occurs, the quality of an image that is formed on the medium PP becomes lower. Similarly, in the liquid ejecting head 1Z according to the referential example, pressure for forcing ink out by the piezoelectric element PZ1 might be absorbed by an air bubble staying inside the pressure compartment CB1Z, resulting in having difficulty in ejecting the ink from the nozzle N.
To provide a solution to this issue, in the liquid ejecting head 1 according to the present embodiment, the sloped portion TP2A and the sloped portion TP2B are provided in the pressure compartment CB2. Therefore, in the liquid ejecting head 1 according to the present embodiment, as compared with the liquid ejecting head 1Z, it is possible to decrease the possibility that an air bubble will stay inside the pressure compartment CB2. In addition, in the liquid ejecting head 1 according to the present embodiment, unlike the liquid ejecting head 1Z, the sloped portion TP1A and the sloped portion TP1B are provided in the pressure compartment CB1. Therefore, in the liquid ejecting head 1 according to the present embodiment, as compared with the liquid ejecting head 1Z, it is possible to decrease the possibility that an air bubble will stay inside the pressure compartment CB1. Therefore, in the liquid ejecting head 1 according to the present embodiment, as compared with the liquid ejecting head 1Z, it is possible to decrease the possibility of occurrence of ejection abnormality due to an air bubble. For this reason, in the liquid ejecting head 1 according to the present embodiment, as compared with the liquid ejecting head 1Z, it is possible to form an image with higher quality on the medium PP.
As explained above, the liquid ejecting head 1 according to the present embodiment includes: the pressure compartment CB1 that extends in the −X direction and applies pressure to ink; the pressure compartment CB2 that extends in the −X direction and applies pressure to ink; the nozzle flow passage RN that extends in the −X direction and is in communication with the nozzle N from which ink is ejected; the communication flow passage RR1 that extends in the −Z direction intersecting with the −X direction and provides communication between the pressure compartment CB1 and the nozzle flow passage RN; the communication flow passage RR2 that extends in the −Z direction and provides communication between the pressure compartment CB2 and the nozzle flow passage RN; the supply flow passage RA1 from which ink is supplied to the pressure compartment CB1; and the discharge flow passage RA2 to which ink is discharged from the pressure compartment CB2; wherein wall surfaces of the pressure compartment CB2 include the wall surface HC2 that extends in the −X direction and is most distant from the nozzle N in the −Z direction, wall surfaces of the communication flow passage RR2 include the wall surface HRa 2 that extends in the −Z direction and is most distant from the nozzle N in the −X direction and the wall surface HRb 2 that is opposite of the wall surface HRa 2 in the −X direction, the sloped portion TP2A is provided between the wall surface HC2 and the wall surface HRb 2, and the sloped portion TP2A includes the wall surface HP21 that extends in the W21 direction between the −X direction and the −Z direction. That is, in the liquid ejecting head 1 according to the present embodiment, since the sloped portion TP2A is provided in the pressure compartment CB2, as compared with an embodiment in which the sloped portion TP2A is not provided in the pressure compartment CB2, it is possible to make the flow of ink from the communication flow passage RR2 toward the pressure compartment CB2 and the flow of ink from the pressure compartment CB2 toward the communication flow passage RR2 more smooth. Therefore, in the liquid ejecting head 1 according to the present embodiment, as compared with an embodiment in which the sloped portion TP2A is not provided in the pressure compartment CB2, it is possible to decrease the possibility that an air bubble will stay inside the communication flow passage RR2 and the possibility that an air bubble will stay inside the pressure compartment CB2. For this reason, in the liquid ejecting head 1 according to the present embodiment, as compared with an embodiment in which the sloped portion TP2A is not provided in the pressure compartment CB2, it is possible to decrease the possibility of occurrence of ejection abnormality due to an air bubble. Moreover, in the liquid ejecting head 1 according to the present embodiment, since the pressure compartment CB1 and the pressure compartment CB2 are in communication with each other through the communication flow passage RR1, the nozzle flow passage RN, and the communication flow passage RR2, it is possible to produce the flow of ink between the pressure compartment CB1 and the pressure compartment CB2. Therefore, in the liquid ejecting head 1 according to the present embodiment, as compared with an embodiment in which the pressure compartment CB1 and the pressure compartment CB2 are not in communication with each other, it is possible to decrease the possibility that an air bubble will stay inside the nozzle flow passage RN, etc. For this reason, in the liquid ejecting head 1 according to the present embodiment, as compared with an embodiment in which the pressure compartment CB1 and the pressure compartment CB2 are not in communication with each other, it is possible to decrease the possibility of occurrence of ejection abnormality due to an air bubble. In the present embodiment, the pressure compartment CB1 is an example of a “first pressure compartment”, the pressure compartment CB2 is an example of a “second pressure compartment”, the communication flow passage RR1 is an example of a “first communication flow passage”, the communication flow passage RR2 is an example of a “second communication flow passage”, the wall surface HC2 is an example of a “first wall surface”, the wall surface HRa 2 is an example of a “second wall surface”, the wall surface HRb 2 is an example of a “third wall surface”, the sloped portion TP2A is an example of a “first sloped portion”, the wall surface HP21 is an example of a “first constituting surface”, ink is an example of “liquid”, the −X direction is an example of a “first direction”, the −Z direction is an example of a “second direction”, and the W21 direction is an example of a “third direction”.
The liquid ejecting head 1 according to the present embodiment further includes: the communication flow passage RK2 that extends in the −Z direction and provides communication between the pressure compartment CB2 and the discharge flow passage RA2; wherein wall surfaces of the communication flow passage RK2 include the wall surface HKb2 that extends in the −Z direction and is most distant from the nozzle N in the −X direction, the sloped portion TP2B is provided between the wall surface HC2 and the wall surface HKb2, and the sloped portion TP2B includes the wall surface HP24 that extends in the W23 direction between the +X direction and the −Z direction. That is, in the liquid ejecting head 1 according to the present embodiment, since the sloped portion TP2B is provided in the pressure compartment CB2, as compared with an embodiment in which the sloped portion TP2B is not provided in the pressure compartment CB2, it is possible to make the flow of ink from the communication flow passage RK2 toward the pressure compartment CB2 and the flow of ink from the pressure compartment CB2 toward the communication flow passage RK2 more smooth. Therefore, in the liquid ejecting head 1 according to the present embodiment, as compared with an embodiment in which the sloped portion TP2B is not provided in the pressure compartment CB2, it is possible to decrease the possibility that an air bubble will stay inside the communication flow passage RK2 and the possibility that an air bubble will stay inside the pressure compartment CB2. For this reason, in the liquid ejecting head 1 according to the present embodiment, as compared with an embodiment in which the sloped portion TP2B is not provided in the pressure compartment CB2, it is possible to decrease the possibility of occurrence of ejection abnormality due to an air bubble. In the present embodiment, the communication flow passage RK2 is an example of a “third communication flow passage”, the wall surface HKb2 is an example of a “fourth wall surface”, the sloped portion TP2B is an example of a “second sloped portion”, the wall surface HP24 is an example of a “second constituting surface”, the +X direction is an example of a “fourth direction”, and the W23 direction is an example of a “fifth direction”.
In the liquid ejecting head 1 according to the present embodiment, the angle θ21 formed by the −X direction and the W21 direction may be substantially the same as the angle θ23 formed by the +X direction and the W23 direction. As compared with a structure in which the angle θ21 and the angle θ23 are different from each other, the present embodiment makes it easier to manufacture the liquid ejecting head 1.
In the liquid ejecting head 1 according to the present embodiment, the sloped portion TP2A includes the wall surface HP22 that extends in the W22 direction between the −X direction and the W21 direction. In this case, the wall surface HP22 may be provided between the wall surface HP21 and the wall surface HRb 2. In addition, in this case, the wall surface HP23 extending in the W21 direction may be provided between the wall surface HP22 and the wall surface HRb 2. That is, in the liquid ejecting head 1 according to the present embodiment, since the sloped portion TP2A has the wall surface HP22, as compared with an embodiment in which the sloped portion TP2A does not have the wall surface HP22, it is possible to make the flow of ink from the communication flow passage RR2 toward the pressure compartment CB2 and the flow of ink from the pressure compartment CB2 toward the communication flow passage RR2 more smooth. Therefore, in the liquid ejecting head 1 according to the present embodiment, as compared with an embodiment in which the sloped portion TP2A does not have the wall surface HP22, it is possible to decrease the possibility that an air bubble will stay inside the communication flow passage RR2 and the possibility that an air bubble will stay inside the pressure compartment CB2. In particular, the sloped portion TP2A is a structure element that changes the direction of the flow of ink from the +X direction to the +Z direction when ink is ejected from the nozzle N and changes the direction of the flow of ink from the −Z direction to the −X direction when ink is circulated through the circulation flow passage RJ without ejecting the ink from the nozzle N. In the present embodiment, since the sloped portion TP2A has the wall surface HP22 extending in the W22 direction, the angle of the slope of which with respect to the X-axis direction is comparatively small, it is possible to change the direction of the flow of ink from the +X direction to the +Z direction smoothly when ink is ejected from the nozzle N. Moreover, in the present embodiment, since the sloped portion TP2A has the wall surface HP23 extending in the W21 direction, the angle of the slope of which with respect to the X-axis direction is comparatively large, it is possible to change the direction of the flow of ink from the −Z direction to the −X direction smoothly when ink is circulated through the circulation flow passage RJ without ejecting the ink from the nozzle N. In the present embodiment, the wall surface HP22 is an example of a “third constituting surface”, and the W22 direction is an example of a “sixth direction”.
In the liquid ejecting head 1 according to the present embodiment, wall surfaces of the pressure compartment CB1 include the wall surface HC1 that extends in the −X direction and is most distant from the nozzle N in the −Z direction, wall surfaces of the communication flow passage RR1 include the wall surface HRa1 that extends in the −Z direction and is most distant from the nozzle N in the +X direction and the wall surface HRb1 that is opposite of the wall surface HRa1 in the −X direction, the sloped portion TP1A is provided between the wall surface HC1 and the wall surface HRb1, and the sloped portion TP1A includes the wall surface HP11 that extends in the W11 direction between the −Z direction and the +X direction. That is, in the liquid ejecting head 1 according to the present embodiment, since the sloped portion TP1A is provided in the pressure compartment CB1, as compared with an embodiment in which the sloped portion TP1A is not provided in the pressure compartment CB1, it is possible to make the flow of ink from the communication flow passage RR1 toward the pressure compartment CB1 and the flow of ink from the pressure compartment CB1 toward the communication flow passage RR1 more smooth. Therefore, in the liquid ejecting head 1 according to the present embodiment, as compared with an embodiment in which the sloped portion TP1A is not provided in the pressure compartment CB1, it is possible to decrease the possibility that an air bubble will stay inside the communication flow passage RR1 and the possibility that an air bubble will stay inside the pressure compartment CB1. For this reason, in the liquid ejecting head 1 according to the present embodiment, as compared with an embodiment in which the sloped portion TP1A is not provided in the pressure compartment CB1, it is possible to decrease the possibility of occurrence of ejection abnormality due to an air bubble. In the present embodiment, the wall surface HC1 is an example of a “fifth wall surface”, the wall surface HRal is an example of a “sixth wall surface”, the wall surface HRbl is an example of a “seventh wall surface”, the sloped portion TP1A is an example of a “third sloped portion”, the wall surface HP11 is an example of a “fourth constituting surface”, and the W11 direction is another example of a “fifth direction”.
In the liquid ejecting head 1 according to the present embodiment, the sloped portion TP2A and the sloped portion TP1A may have substantially the same shape. In the present embodiment, if the sloped portion TP2A and the sloped portion TP1A have substantially the same shape, it becomes easier to manufacture the liquid ejecting head 1, as compared with a structure in which the shape of the sloped portion TP2A is different from the shape of the sloped portion TP1A. Moreover, in the present embodiment, if the sloped portion TP2A and the sloped portion TP1A have substantially the same shape, it is possible to make the shape of the ink flow passage leading from the pressure compartment CB1 to the nozzle N through the communication flow passage RR1 and the nozzle flow passage RN substantially the same as the shape of the ink flow passage leading from the pressure compartment CB2 to the nozzle N through the communication flow passage RR2 and the nozzle flow passage RN. Therefore, in the present embodiment, if the sloped portion TP2A and the sloped portion TP1A have substantially the same shape, it is possible to make the control for ejecting ink contained inside the pressure compartment CB1 from the nozzle N and the control for ejecting ink contained inside the pressure compartment CB2 from the nozzle N more simple, as compared with a structure in which the shape of the sloped portion TP2A is different from the shape of the sloped portion TP1A.
The liquid ejecting head 1 according to the present embodiment further includes: the communication flow passage RK1 that extends in the −Z direction and provides communication between the pressure compartment CB1 and the supply flow passage RA1; wherein wall surfaces of the communication flow passage RK1 include the wall surface HKbl that extends in the −Z direction and is most distant from the nozzle N in the +X direction, the sloped portion TP1B is provided between the wall surface HC1 and the wall surface HKbl, and the sloped portion TP1B includes the wall surface HP14 that extends in the W13 direction. That is, in the liquid ejecting head 1 according to the present embodiment, since the sloped portion TP1B is provided in the pressure compartment CB1, as compared with an embodiment in which the sloped portion TP1B is not provided in the pressure compartment CB1, it is possible to make the flow of ink from the communication flow passage RK1 toward the pressure compartment CB1 and the flow of ink from the pressure compartment CB1 toward the communication flow passage RK1 more smooth. Therefore, in the liquid ejecting head 1 according to the present embodiment, as compared with an embodiment in which the sloped portion TP1B is not provided in the pressure compartment CB1, it is possible to decrease the possibility that an air bubble will stay inside the communication flow passage RK1 and the possibility that an air bubble will stay inside the pressure compartment CB1. For this reason, in the liquid ejecting head 1 according to the present embodiment, as compared with an embodiment in which the sloped portion TP1B is not provided in the pressure compartment CB1, it is possible to decrease the possibility of occurrence of ejection abnormality due to an air bubble. In the present embodiment, the communication flow passage RK1 is an example of a “fourth communication flow passage”, the wall surface HKb1 is an example of an “eighth wall surface”, the sloped portion TP1B is an example of a “fourth sloped portion”, the wall surface HP14 is an example of a “fifth constituting surface”, and the W13 direction is another example of a “third direction”.
The liquid ejecting head 1 according to the present embodiment further includes: the pressure compartment substrate 3 in which the pressure compartment CB1 and the pressure compartment CB2 are provided; the communication plate 2 in which the nozzle flow passage RN, the communication flow passage RR1, the communication flow passage RR2, the supply flow passage RA1, and the discharge flow passage RA2 are provided; and the nozzle substrate 60 in which the nozzle N is provided. Therefore, the present embodiment makes it possible to manufacture the pressure compartment CB1, the pressure compartment CB2, the nozzle flow passage RN, the communication flow passage RR1, the communication flow passage RR2, the supply flow passage RA1, the discharge flow passage RA2, and the nozzle N by using a semiconductor manufacturing technology. For this reason, the present embodiment makes it possible to realize the microfabrication and high density of the pressure compartment CB1, the pressure compartment CB2, the nozzle flow passage RN, the communication flow passage RR1, the communication flow passage RR2, the supply flow passage RA1, the discharge flow passage RA2, and the nozzle N.
In the liquid ejecting head 1 according to the present embodiment, the sloped portion TP2A is provided in the pressure compartment substrate 3. Therefore, the present embodiment makes it possible to manufacture the sloped portion TP2A by using a semiconductor manufacturing technology. For this reason, the present embodiment makes it possible to realize the microfabrication and high density of the sloped portion TP2A.
In the liquid ejecting head 1 according to the present embodiment, the nozzle N is in communication with the nozzle flow passage RN substantially at the center of the nozzle flow passage RN. Therefore, the present embodiment makes it possible to make the shape of the ink flow passage leading from the pressure compartment CB1 to the nozzle N through the communication flow passage RR1 and the nozzle flow passage RN substantially the same as the shape of the ink flow passage leading from the pressure compartment CB2 to the nozzle N through the communication flow passage RR2 and the nozzle flow passage RN. For this reason, for example, the present embodiment makes it possible to make the control for ejecting ink contained inside the pressure compartment CB1 from the nozzle N and the control for ejecting ink contained inside the pressure compartment CB2 from the nozzle N more simple, as compared with an embodiment in which the nozzle N is in communication with the nozzle flow passage RN at a different position that is not substantially the center of the nozzle flow passage RN.
The liquid ejecting head 1 according to the present embodiment further includes: the piezoelectric element PZ1 that applies pressure to ink inside the pressure compartment CB1 in response to supply of the drive signal Coml; and the piezoelectric element PZ2 that applies pressure to ink inside the pressure compartment CB2 in response to supply of the drive signal Com2. For this reason, as compared with an embodiment in which the piezoelectric element PZq that applies pressure to ink inside a single pressure compartment CBq only is provided, it is possible to increase the amount of ink ejected from the nozzle N. In the present embodiment, the piezoelectric element PZ1 is an example of a “first element”, the piezoelectric element PZ2 is an example of a “second element”, the drive signal Coml is an example of a “first drive signal”, and the drive signal Com2 is an example of a “second drive signal”.
In the liquid ejecting head 1 according to the present embodiment, a waveform of the drive signal Com1 is substantially the same as a waveform of the drive signal Com2. Therefore, the present embodiment makes it possible to make the control for ejecting ink contained inside the pressure compartment CB1 from the nozzle N and the control for ejecting ink contained inside the pressure compartment CB2 from the nozzle N more simple, as compared with an embodiment in which the waveform of the drive signal Coml is different from the waveform of the drive signal Com2.
The embodiment described as examples above can be modified in various ways. Some specific examples of modification are described below. Two or more variation examples selected arbitrarily from the description below may be combined as long as they are not contradictory to each other or one another.
In the foregoing embodiment, as illustrated in
Since the Y-directional width dYqB of the pressure compartment CBq at a position near the communication flow passage RRq is less than the Y-directional width dYqA of the pressure compartment CBq at a position near the communication flow passage RKq, the present variation example makes it possible to make the speed of the flow of ink at the communication flow passage RRq higher than the speed of the flow of ink at the communication flow passage RKq. Because of the faster flow at the communication flow passage RRq, the present variation example makes it possible to decrease the possibility that an air bubble will stay inside the passage leading from the pressure compartment CBq to the nozzle N through the communication flow passage RRq and the nozzle flow passage RN. For this reason, the present variation example makes it possible to decrease the possibility of occurrence of ejection abnormality due to an air bubble.
In the foregoing embodiment and the first variation example, the serial-type liquid ejecting apparatus 100 that reciprocates the endless belt 922 with the liquid ejecting heads 1 in the Y-axis direction is explained as examples. However, the scope of the present disclosure is not limited to these examples. The liquid ejecting apparatus may be a so-called line-type liquid ejecting apparatus in which the plural nozzles N are arranged throughout the entire width of the medium PP.
In the foregoing embodiment and the first and second variation examples, the piezoelectric element PZq that converts electric energy into motion energy is described for showing some examples of an energy conversion element that applies pressure to the inside of the pressure compartment CB. However, the scope of the present disclosure is not limited to these examples. For example, a heat generation element that converts electric energy into thermal energy and generates air bubbles inside the pressure compartment CB by heating to cause changes in pressure inside the pressure compartment CB may be used as the energy conversion element that applies pressure to the inside of the pressure compartment CB. The heat generation element may be, for example, an element in which a heater generates heat by receiving a supply of the drive signal Com. Fourth Variation Example
The liquid ejecting apparatus disclosed as examples in the foregoing embodiment and the first, second, and third variation examples can be applied to various kinds of equipment such as facsimiles and copiers, etc. in addition to print-only machines. The scope of application and use of the liquid ejecting apparatus according to the present disclosure is not limited to printing. For example, a liquid ejecting apparatus that ejects a colorant solution can be used as an apparatus for manufacturing a color filter of a liquid crystal display device. A liquid ejecting apparatus that ejects a solution of a conductive material can be used as a manufacturing apparatus for forming wiring lines and electrodes of a wiring substrate.
Number | Date | Country | Kind |
---|---|---|---|
2020-014627 | Jan 2020 | JP | national |