Field of the Invention
The aspects of the present invention relate to an element substrate for a liquid ejecting head and a wafer including a plurality of element substrates, and particularly to a configuration that prevents electro-static discharge (ESD) damage (hereinafter, may be referred to as ESD damage) to the element substrate.
Description of the Related Art
A liquid ejecting apparatus such as an inkjet printer is known as an example of information output apparatuses configured to record information such as a character and an image on a recording medium such as a sheet and film. The liquid ejecting apparatus includes a liquid ejecting head that applies liquid droplets onto a recoding medium for recording. A thermal inkjet process is known as an example of liquid ejecting processes performed by the liquid ejecting head. In the thermal inkjet process, a current is passed through the heating resistor, which is in contact with the ink, for about a few μ seconds to generate a thermal energy. The bubbling of the ink caused by the thermal energy is used to eject the ink droplets. The liquid ejecting head for the thermal inkjet process generally includes an element substrate including a heating resistor used for ejection of the ink droplets. The element substrate includes a silicon substrate, an element forming member including the heating resistor, on the silicon substrate, and a discharge port forming member including a discharge port, on the element forming member.
In a production step of the element substrate or in a recording operation by the liquid ejecting head, the element substrate may have ESD damage. Japanese Patent Laid-Open No. 2004-050636 describes that a dummy MOS (Metal-Oxide-Semiconductor) is connected in parallel with the heating resistor so as to prevent the ESD damage to the heating resistor (heater). A current flowing from the pad flows to the dummy MOS, preventing a large current from flowing into the heating resistor.
U.S. Pat. No. 7,267,430 describes that an anticavitation layer is connected to a grounded-gate MOS. The ESD current flowed into the anticavitation layer flows to the substrate through the grounded-gate MOS. Thus, the protective film between the anticavitation layer and the electrode for the heating resistor is unlikely to have the ESD damage.
The aspects of the present invention provide an element substrate for a liquid ejecting head including: a substrate; an element forming layer on the substrate, the element forming layer including an energy generating element configured to provide energy to a liquid for ejection; a discharge port forming member formed of an insulating member on the element forming layer, the discharge port forming member including a discharge port forming surface having discharge ports through which the liquid is ejected and an exterior side surface positioned between the discharge port forming surface and the element forming layer, the exterior side surface having a first edge facing the element forming layer; and a conductive layer disposed between the first edge and the element forming layer and arounded.
Further features of the aspects of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
An ESD occurs at various positions in an element substrate. An ESD current, which is caused by the ESD, on a surface of a discharge port forming member travels along the surface of the discharge port forming member. This is called surface discharge. In the configuration disclosed in Japanese Patent Laid-Open No. 2004-050636, the ESD current generated at a position closer than the pad to the discharge port, for example, may flow into the element substrate through the discharge port due to the surface discharge, resulting in the ESD damage to the protective film. The pad is generally disposed at an end portion of the element substrate, and thus most of the ESD current may flow into the element substrate, not into the pad.
In the configuration disclosed in U.S. Pat. No. 7,267,430, if a distance between the grounded-gate MOS and the heating resistor is large, the ESD damage may occur at a low-insulating portion of the protective film between the grounded-gate MOS and the heating resistor. In particular, the ESD damage readily occurs in a long liquid ejecting head, which tends to have a large distance between the grounded-gate MOS and the heating resistor.
The ESD damage readily occurs in the configurations disclosed in Japanese Patent Laid-Open. No. 2004-050636 and U.S. Pat. No. 7,267,430 when the ESD occurs at a position away from the pad or the grounded-gate MOS, which is a grounding component. The likelihood of occurrence of the ESD damage also depends on the internal configuration of the liquid ejecting head.
The aspects of the present invention provide an element substrate for a liquid ejecting head in which ESD damage is unlikely to occur regardless of the internal configuration of the liquid ejecting head and the occurrence position of the ESD.
Embodiments of the aspects of the present invention are described with reference to the drawings.
An element substrate 1 for the liquid ejecting head includes a substrate 100, an element forming layer 110 on the substrate 100, and a discharge port forming member 200 on the element forming layer 110. The substrate 100 is formed of silicon and includes an ink supply channel 101 through which the ink is supplied. Energy generating elements 111, which are configured to provide energy to the liquid for ejection, are disposed on the element forming layer 110. In this embodiment, the energy generating element is a heating resistor (heater) 111. The discharge port forming member 200 is formed of an insulating member such as an epoxy resin material and includes a ceiling member 200a and a side surface member 200b. The side surface member 200b defines bubbling chambers 202 provided for corresponding heating resistors 111, a liquid chamber 204 common to the bubbling chambers 202, and a communication channel 203 positioned between the liquid chamber 204 and the bubbling chambers 202 and through which the ink is introduced to the bubbling chambers 202. The ceiling member 200a includes a plurality of discharge ports 201 through which the ink is elected. The discharge ports 201 are provided for corresponding heating resistors 111. The discharge ports 201 are arranged lineally to form a discharge port array 205. In this embodiment, one discharge array 205 is disposed on each side of the ink supply channel 101, but may be disposed on one side of the ink supply channel 101. A surface of the ceiling member 200a away from the side surface member 200b is a discharge port forming surface 206 including the discharge ports 201. Terminals 160 are disposed on the substrate 100 so as to supply a voltage or a signal from an external device to the heating resistors 111 of the liquid ejection head. The ink is supplied from an ink tank, which is not illustrated, to the bubbling chamber 202 through the ink supply channel 101, the liquid chamber 204, and the communication channel 203. The ink is heated by the heating resistor 111 adjacent to the bubbling chamber 202 and a bubble is formed, and then the ink in the form of liquid droplet is ejected through the discharge port 201.
As illustrated in
As illustrated in
Hereinafter, embodiments of the aspects of the present invention, are described in detail. The above-described configuration is common to all embodiments.
The discharge port forming surface 206 of the discharge port forming member 200 includes a groove 210 surrounding the discharge ports 201 (two discharge port arrays 205 in this embodiment) to reduce the stress applied to the discharge port forming member 200, which is connected to the substrate 100. The groove 210 is formed by removing a portion of the discharge port forming member 200. The groove 210 extends through the ceiling member 200a and the side surface member 200b such that the element forming layer 110 is exposed. Bridge portions 210a across the groove 210 in the width direction are disposed to protect the element forming layer 110. The bridge portions 210a are formed of the same material as the discharge port forming member 200. In this embodiment, the bridge portions 210a having a width of 100 μm is arranged at an interval of 200 μm. In addition, a protective film. 130c, which is formed of the same material as the anticaviation layer 130, covers the surface of the element forming layer 110 exposed by the groove 210 to protect the element forming layer 110.
The element forming layer 110 includes a second surface 110b facing the substrate 100 and a first surface 110a opposite the second surface 110b. The discharge port forming member 200 is disposed on the first surface 110a. The first surface 110a includes an interior portion 110c and an exterior portion 110d located outwardly from the interior portion 110c. The interior portion 110c is a surface of the element forming layer 110 under the discharge port forming member 200. The exterior portion 110d is a portion of the surface of the element forming layer 110 on which the discharge port forming member 200 is not disposed. The discharge port forming member 200 includes an exterior side surface 200c positioned between the discharge port forming surface 206 and the element forming layer 110. In other words, a border between the interior portion 110c and the exterior portion 110d corresponds to the exterior side surface 200c of the discharge port forming member 200 when viewed in a direction perpendicular to the substrate 100. The exterior side surface 200c has a first edge 200d adjacent to the element forming layer 110 and a second edge 200e adjacent to the discharge port forming surface 206 (i.e., the second edge 200e forms a border between the exterior side surface 200c and the discharge port forming surface 206).
A conductive layer 130a formed of Ta and having a thickness of 200 nm and a width of 20 μm is disposed between the first edge 200d of the exterior side surface 200c of the discharge port forming member 200 and the element forming layer 110. The conductive layer 130a may be formed of any other material having conductivity and ink resistivity than Ta. The conductive layer 130a is conductive wiring configured to attract an ESD current. The conductive layer 130a has a portion in contact with the protective film 131 at a position outside the discharge port forming member 200. Since the conductive layer 130a is formed of the same material as the anticavitation layer 130, those layers are formed in one process at the same time. The conductive layer 130a is electrically connected to a conductive pad, which is electrically grounded to the substrate 100 through an electrical connection layer 130b disposed on the exterior portion 110d of the first surface 110a of the element forming layer 110. The electrical connection layer 130b may be formed of the same material as the conductive layer 130a and the anticavitation layer 130. The pad is one of a plurality of external connection pads 160, and is a arounded-GND pad 160a electrically connected to the substrate 100. Thus, the conductive layer 130a is electrically connected to the substrate 100. The conductive layer 130a is not electrically connected to the anticavitation layer 130 on the heating resistors 111 and the protective film 130c in the groove 210. In other words, the conductive layer 130a is electrically separated from the anticavitation layer 130 on the heating resistors 111 and the protective film 130c. Other components than the pad may be used to connect the conductive layer 130a to the substrate 100. In addition, the conductive layer 130a may be electrically connected to a member outside the substrate 100 through an external connection pad, for example, and grounded instead of electrically connected to the substrate 100. This enables the ESD current to be introduced to the exterior side surface 200c of the discharge port forming member 200 and to be readily released to the outside of the discharge port forming member 200.
The exterior side surface 200c of the discharge port forming member 200 may be in contact with or away from the conductive layer 130a. When the exterior side surface 200c is away from the conductive layer 130a, a layer between the first edge 200d of the exterior side surface 200c of the discharge port forming member 200 and the conductive layer 130a can be an insulating layer such as an adhesive layer. This configuration reliably causes the surface discharge between the exterior side surface 200c of the discharge port forming member 200 and the conductive layer 130a. The conductive layer 130a extends over a border between the interior portion 110c and the exterior portion 110d of the element forming layer 110 with the exterior side surface 200c of the discharge port forming member 200 therebetween. In other words, the inner peripheral portion of the conductive layer 130a is positioned between the element forming layer 110 and the discharge port forming member 200, and the outer peripheral portion of the conductive layer 130a, which extends along the entire circumference of the discharge port forming member 200, is exposed at a position outside the discharge port forming member 200. The inner peripheral portion of the conductive layer 130a may be eliminated. The conductive layer 130a extends continuously along the entire circumference of the discharge port forming member 200, but may extend partially or discontinuously along the entire circumference of the discharge port forming member 200.
A wafer of a comparative example 1 is provided which has the configuration identical to that of the wafer in the first embodiment except that the comparative example 1 does not include the conductive layer 130a. After the wafer of the comparative example 1 was subjected to the cleaning step, it was found that the ESD damage occurred at 30 places in the entire wafer. The ESD damage was found at positions close to the electrodes 150a and 150b for the heating resistor 111 and to the groove 210. The ESD damage at the position close to the groove 210 was found at the wiring layer connected to the electrodes 150a and 150b. The ESD damage was particularly concentrated on the edge of the wiring. The ESD damage to the side surface of the wiring may be readily caused due to the fact that the insulating properties of the protective film 131c is deteriorated by increasing the thickness of the wiring layer to reduce the resistance of the wiring layer.
The following describes the possible mechanism of the ESD damage at the electrodes 150a and 150b for the heating resistor 111.
Compared to the comparative example 1, in the first embodiment, the ESD damage occurrences after the cleaning step was found at five places, which is less than in the comparative example 1. As illustrated in
The occurrence rate of the ESD damage is lower at some of the heating resistors 111 that are positioned adjacent to the pad 160a. The reduction may be achieved due to the fact that the ESD current partly flowed through the bridge portions 210a and flowed along the discharge port forming surface 206 to an exterior side of the groove 210.
As can be understood from the above, the ESD current generated at a portion exterior from the groove 210 is likely to be introduced toward the conductive layer 130a, not toward the groove 210 and the discharge ports 201. This may reduce the ESD damage not only at the position around the groove 210, but also at the position around the heating resistors 111. In this embodiment, since the conductive layer 130a is disposed on the exterior portion 110d of the element forming layer 110, the ESD current is effectively introduced to the exterior side surface 200c of the discharge port forming member 200. With this configuration, the ESD damage is less likely to occur even if the insulating properties of the protective film 131 are deteriorated by increasing the thickness of the electrodes 150a and 150b or the wiring layer connected to the electrodes 150a and 150b. In addition, since the ESD current is introduced to the outside of the discharge port forming member 200 in the aspects of the present invention, the layout of wiring in the element substrate region 100a and the configuration of the discharge port forming member 200 do not need to be changed to reduce the occurrence of the ESD damage.
The ESD damage to the wafer of the second embodiment after the cleaning step was checked, and it was found that the ESD damage occurred at 10 places in the entire wafer. The reduction in the occurrence of the ESD damage may be achieved due to the fact that the openings 140b in the adhesion improving layer 140 through which the conductive layer 130a is exposed allowed the ESD current to be introduced to the conductive layer 130a by the surface discharge along the exterior side surface 200c of the discharge port forming member 200, as illustrated in
The ESD damage to the wafer of the third embodiment after the cleaning step was checked, and it was found that the ESD damage occurred at fire places. This reduction may be achieved due to the fact that the ESD current flowing along the exterior side surface 200c of the discharge port forming member 200 by the surface discharge was concentrated on the peak portions 207a, which enables the ESD current to be more readily introduced to the conductive layer 130a. In the third embodiment, the adhesion between the element forming layer 110 and the discharge port forming member 200 is maintained, and the occurrence of the ESD damage is reduced.
A wafer (see
In the fourth embodiment and the first modification, a distance between the middle of the discharge port forming member 200 and the edge of the discharge port forming member 200 on which the conductive layer 130a is disposed is large. Thus, the ESD current generated at the middle of the discharge port forming member 200 or the inter-groove regions 210b is readily introduced to the discharge ports 201 or the grooves 210.
Compared to the above, in the fourth embodiment, the number of occurrences of the ESD damage is reduced to 10. In particular, the occurrence of the ESD damage is reduced at the portions V, which are adjacent to the recess 208. This reduction may be achieved due to the fact that the recess 208 was provided such that the distance between the inter-groove region 210b and the conductive layer 130a becomes shorter as illustrated in
In the first modification, which does not have the recess 208, the conductive layer 130a, which is disposed between the first edge 200d and the element forming layer 110, reduces the occurrence of the ESD damage. Thus, the recess 208 is an optional component.
As illustrated in
In the above-described embodiments, the shape of the element substrate region 100a (or the element substrate 1) is not limited to oblong, and may be parallelogram, triangle, or any other polygon. The first and second heat storage layers 122 and 132 may be subjected to a planarization treatment. The liquid ejecting head having such a configuration obtains the same advantages.
The aspects of the present invention can be applied to a long liquid ejecting head. In the long liquid ejecting head, the resistance of the electrodes 150a and 150b for the heating resistor 111 tend to increase. The thickness of the electrodes 150a and 150b may be increased to reduce the resistance of the electrodes 150a and 150b without affecting the size of the substrate for the liquid ejecting head. In such a case, the covering properties of the protective film 131, which covers the electrodes 150a and 150b, are reduced, and thus the ESD damage readily occurs. In one aspect of the present invention, the ESD current caused in the discharge port forming member 200 is transferred to the conductive layer 130a along the exterior side surface 200c of the discharge port forming member 200 by the surface discharge. This reduces the occurrence of the ESD damage even in the liquid ejecting head including the electrodes 150a and 150b having a large thickness of 1000 nm or more.
While the aspects of the present invention have been described with reference to exemplary embodiments, it is to be understood that the aspects of the invention are not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2015-200916, filed Oct. 9, 2015, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2015-200916 | Oct 2015 | JP | national |
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20110310183 | Tamaru | Dec 2011 | A1 |
20140307028 | Omura | Oct 2014 | A1 |
Number | Date | Country |
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2002079672 | Mar 2002 | JP |
2004050636 | Feb 2004 | JP |
Number | Date | Country | |
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20170100930 A1 | Apr 2017 | US |