1. Field of the Invention
The present invention relates to a liquid-discharging head that discharges a liquid and a method of producing the same. More specifically, the present invention relates to an ink-jet recording head that performs recording by discharging ink onto a recording medium, and a method of producing the same.
2. Description of the Related Art
A liquid-discharging head, such as an ink-jet head, includes discharge ports, liquid passages communicating with the discharge ports, energy-generating units for discharging a liquid, the units being disposed in the liquid passages, a liquid chamber communicating with the liquid passages, and a supply port for supplying ink from an ink tank or the like to the liquid chamber. Ink droplets are discharged from the discharge ports by providing energy generated by the energy-generating units to the ink filling the liquid passages. These discharged ink droplets land on a recording material to form pixels, and thus recording is performed.
Among these liquid-discharging heads, liquid-discharging heads that utilize thermal energy for discharging a liquid can perform recording with a high resolution because a plurality of discharging ports can be arranged in a high density. Furthermore, such liquid-discharging heads are advantageous in that the size of the heads can be easily reduced as a whole.
In general, in such a known liquid-discharging head that utilizes thermal energy, a high-density arrangement is realized by arranging a plurality of exothermic resistive elements in line on a substrate made of, for example, silicon, and a substrate having a heat storage layer and an electrical insulating layer that are used in common for the plurality of exothermic resistive elements is used.
U.S. Pat. No. 6,984,024 discloses a back-shooting-type head, which is an example of an ink-jet head. In a thermally driven ink-jet head, air bubbles are formed in ink by heat generated by an exothermic resistive element (heater) disposed in a liquid passage, and the ink in the liquid passage is discharged from a discharge port by the pressure generated by the growth of the air bubbles. An ink-droplet discharge system in which an ink droplet is discharged in a direction opposite to the direction in which a heater surface on which the air bubbles expand faces is referred to as “back-shooting type”.
The back-shooting type head described in U.S. Pat. No. 6,984,024 is produced using a silicon-on-insulator (SOI) wafer. For example, a silicon surface layer and an insulating layer that constitute the SOI wafer have a thickness of 40 μm and 1 μm, respectively. In a production process of the head, first, an ink chamber and a wall of an ink channel are formed. More specifically, a trench is formed, and the trench is then embedded by thermal oxidization. The oxidizing film functions as a stop layer of final isotropic etching using XeF2. After the thermal oxidization, the thermally oxidized film formed on the surface of the substrate is removed by chemical mechanical polishing (CMP).
Subsequently, a heater lower layer, a heater layer and a wiring layer (heater upper layer), and a metal protective film are formed and patterned. Next, a metal seed layer for electroplating is formed, and a positive resist used as a pattern of discharge ports is patterned. A nickel film is formed as a discharge port plate by electroforming so as to have a thickness of 30 μm. Subsequently, a manifold is formed by etching silicon of the lower layer, the insulating layer is then etched. Parylene is then deposited in order to protect exposed silicon portions. Subsequently, a part of the parylene disposed parallel to the substrate surface is etched in order to remove silicon located on positions corresponding to the discharge ports. Finally, the ink chamber and the ink channel communicate with the discharge ports by performing isotropic etching with XeF2.
Nowadays, a large number of recording apparatuses are used, and, for example, high-speed recording, high resolution, high image quality, and low noise have been required for these recording apparatuses. An example of a recording head of a recording apparatus that meets such requirements is an ink-jet head. In an ink-jet head that discharges ink by utilizing thermal energy, stabilization of ink discharge, i.e., stabilization of the amount of ink discharge required for meeting the above needs are significantly affected by the temperature of ink in discharge portions. Specifically, if the temperature of the ink is excessively low, the viscosity of the ink excessively increases. As a result, the ink cannot be discharged by normal thermal energy. On the other hand, if the temperature is excessively high, the amount of discharge increases, and for example, ink may be spilled onto a recording sheet, resulting in a degradation of image quality. Furthermore, in order to realize high-speed recording, a drive frequency (drive frequency for which the time ranging from a discharge of a droplet to the next discharge is defined as one cycle) must be increased by efficiently dissipating heat generated from a heater without storing the heat in a substrate.
On the other hand, in a back-shooting-type ink-jet head, heaters are provided in a discharge port plate having a thickness of about 30 μm. In this structure, the temperature of ink is easily increased because portions having the heaters have a low heat capacity, as compared with a head in which a discharge port plate including liquid passages having heaters therein is stacked on a silicon substrate on which the heaters are formed. Therefore, such a back-shooting-type head is disadvantageous in that the temperature of ink is easily increased, and it is difficult to stabilize the amount of discharge.
The present invention provides a back-shooting-type liquid-discharging head in which a temperature increase of a recording liquid to be discharged can be suppressed to stabilize the amount of discharge. According to the present invention, even in a back-shooting-type liquid-discharging head, an increase in the temperature of a discharge port plate can be suppressed, and the temperature of ink in a liquid chamber is also not increased easily. As a result, the amount of discharge can be further stabilized.
According to an aspect of the present invention, a liquid-discharging head includes a substrate; a flow passage wall-forming layer bonded to the substrate so as to form a flow passage for liquid between the substrate and the flow passage wall-forming layer, the flow passage communicating with a discharge port configured to discharge the liquid; an element configured to generate energy used for discharging the liquid from the discharge port and provided on the flow passage wall-forming layer; a metal layer provided with the discharge port so as to correspond to the element; and a projecting portion made of a metal and extending from the metal layer through the flow passage wall-forming layer and projecting in the direction of the substrate.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Embodiments of the present invention will now be described with reference to the drawings. Here, descriptions will be made using ink-jet recording heads as examples of liquid-discharging heads of the present invention.
The ink-jet recording head of this embodiment shown in
The ink channels 103 are provided on the top surface of the substrate 101 and formed so as to extend from the manifold 102 having a long rectangular opening. The discharge ports 116 communicating with the ink chambers 104 disposed at the most downstream side of each of the ink channels 103 are arranged in one direction.
Furthermore, portions of the metal layer 115 included in the discharge port plate 111 penetrate through the protective layers 112 and 113 and project (stick out) into the ink channels 103, which are areas disposed near the substrate 101 side relative to the protective layer 112. Thus, these portions can be in contact with ink. Hereinafter, these projecting columns are referred to as projecting portions 120.
The projecting portions 120 are formed such that the heat capacity and the surface area thereof can be maximized. In addition, for example, the shape, the dimensions (the width, and the length, and the thickness), and the arrangement are determined so that blocking of inflow of ink from the manifold 102 to the ink channels 103 can be minimized.
Furthermore, the projecting portions 120 also function as a backward flow resistive element that suppresses the propagation of ink flow generated in discharging ink to adjacent ink chambers 104. In addition, the projecting portions 120 also function as a filter that prevents impurities contained in the ink from reaching the ink chambers 104.
Next, an example of a method of producing the above ink-jet recording head will be described with reference to process drawings separately shown in
In this embodiment, a single-crystal silicon wafer whose surface has a crystal orientation plane of (100) is prepared as a substrate 101.
Subsequently, a sacrificial layer 131, a first protective layer 112, heaters 114, a conductor (not shown), and a second protective layer 113 are sequentially stacked on the substrate 101 (
The first protective layer 112 functions as an insulating layer between the heaters 114 and the substrate 101 and has chemical resistance against a removing agent of the sacrificial layer and the like. The first protective layer 112 is made of, for example, silicon nitride or silicon oxide.
The second protective layer 113 functions as an insulating layer between a metal layer 115 to be formed in a subsequent step and the heaters 114, and protects the heaters 114 and the conductor (not shown) that transmits driving signals to the heaters 114. The second protective layer 113 is made of, for example, silicon nitride or silicon oxide.
The sacrificial layer 131 of this embodiment is etched at a speed sufficiently higher than the speeds at which the substrate 101 and the first protective layer 112 are etched. When silicon nitride is used as the first protective layer 112, silicon oxide can be used as a specific material of the sacrificial layer 131. When hydrogen fluoride gas is used as a removing agent of the sacrificial layer 131, a selection ratio for achieving a sufficiently high etching rate relative to the etching rates of single-crystal silicon constituting the substrate 101 and silicon nitride constituting the first protective layer 112 can be realized.
The heaters 114 and the conductor (not shown) that transmits driving signals to the heaters 114 are formed on the first protective layer 112. Each of the heaters 114 is composed of an exothermic resistive element made of, for example, polysilicon, a tantalum-aluminum alloy, tantalum nitride, titanium nitride, or tungsten silicide doped with an impurity. The conductor that transmits electrical signals to the heaters 114 is made of a metal having good conductivity such as aluminum, an aluminum alloy, gold, or silver.
Also, a reverse surface protective film 132 is formed on the reverse surface of the substrate 101.
Each of the above stacking materials can be deposited by a method such as chemical vapor deposition (CVD) using a plasma. The sacrificial layer 131, the heaters 114, the conductor, and the like are patterned by etching using a photoresist mask.
Subsequently, a resist pattern 133 is formed on the second protective layer 113 (
The sacrificial layer 131, the first protective layer 112, and the second protective layer 113 are etched using the resist pattern 133 as a mask (
Furthermore, silicon of the substrate 101 is dry-etched using the resist pattern 133 to form trenches 134 (
The resist pattern 133 is then removed (
Furthermore, a plating seed layer 135 is deposited on the inner surface of the openings reaching the trenches 134 and the surface of the second protective layer 113 (
Furthermore, a resist 136 is patterned on the plating seed layer 135 so as to correspond to portions to be formed into discharge ports 116 in a subsequent step (
Next, a metal layer 115 is formed on the second protective layer 113 so that a metal material sufficiently fills inside the trenches 134 (
The formed metal layer 115 is affected by the presence of the openings in the second protective layer 113 and has irregularities on the surface thereof. Accordingly, in order to remove the irregularities, the surface of the metal layer 115 may be planarized by surface polishing.
The resist 136 is then removed (
Next, a reverse-face protective film pattern 137 is formed on the reverse face of the substrate 101 (
A surface protective resist 138 for protecting the discharge port plate 111 during crystal anisotropic etching in a subsequent step is applied on the top surface of the substrate 101 (
Next, the manifold 102 is formed in the substrate 101 by crystal anisotropic etching (
Next, the sacrificial layer 131 is removed through the opening of the manifold 102 (
Furthermore, an etchant is introduced into the space formed by removing the sacrificial layer 131 through the manifold 102 to etch the single-crystal silicon substrate 101 from the space. Accordingly, flow passages corresponding to ink chambers 104 and ink channels 103 are formed (
Subsequently, the surface protective resist 138 is removed (
Next, prior to dry etching performed for communicating the discharge ports 116 with portions to be formed into the ink chambers 104, a dry film 139 is patterned as a mask for protecting the discharge port plate 111 (
Subsequently, the first protective layer 112 and the second protective layer 113 are etched by dry etching (
Subsequently, the dry film 139 used for protecting the discharge port plate 111 is removed (
Finally, the resulting silicon wafer is separated into desired chip units using a dicer, as needed. Thus, the ink-jet recording head can be produced.
By providing the projecting portions 120 that contact ink in the flow passages on the discharge port plate 111 including the heaters 114, heat storage in bubble-generating portions can be suppressed even in a successive printing. Consequently, an effect of stabilizing the amount of discharge can be achieved.
In this embodiment, as shown in
In this embodiment, as shown in
It is believed that, by bringing a portion of the metal layer 115 into directly contact with the substrate 101, heat generated from heaters 114 can be more effectively dissipated, and thus, the drive frequency can be improved, as compared with the first and second embodiments.
First, prior to the deposition of the second protective layer 113, which is shown in
Next, a second protective layer 113 is formed on a first protective layer 112, heaters 114, and a conductor (not shown) that transmits electrical signals to the heaters 114.
A part of the sacrificial layer 131 and the protective layers 112 and 113, the part capable of being formed into a part of the wall surface of an ink chamber 104 and an ink channel 103, is removed. In this step, the positive resist or the like was patterned by a lithography process, and the part was removed by reactive ion etching.
Subsequently, a trench 141 is formed on single-crystal silicon constituting the substrate 101 by etching to a depth substantially the same height of the wall surface of the ink chamber and the ink channel to be formed (
Next, the metal layer 115 is formed so as to sufficiently fill the trench 141 formed on the second protective layer 113 and the single-crystal silicon.
The formed metal layer 115 is affected by the presence of the trench 141 and has irregularities on the surface thereof. Accordingly, in order to remove the irregularities, the surface of the metal layer 115 may be planarized by surface polishing (
Next, in order to protect portions to be formed into the discharge ports 116, a protective material such as a cyclized rubber 142 is applied on the top surface side of the substrate (on the discharge port plate 111).
Furthermore, a resist is formed on the reverse face of the substrate 101 and patterned so as to have an opening at a predetermined position at which a manifold 102 is to be formed. The manifold 102 is formed using this resist as a mask (reverse-face protective film pattern 137) (
In forming the manifold 102, the substrate 101 is immersed in an alkaline aqueous solution such as an aqueous solution of potassium hydroxide (KOH) or tetramethylammonium hydroxide (TMAH) to perform crystal anisotropic etching from the opening of the reverse-face protective film pattern 137. The etching is finished when the single-crystal silicon substrate 101 is penetrated to communicate with the sacrificial layer 131. Thus, the manifold 102 is formed.
Next, the sacrificial layer 131 is removed through the manifold 102 (
Furthermore, an etchant is introduced into the space formed by removing the sacrificial layer 131 through the manifold 102 to etch the single-crystal silicon substrate 101 from the space. Accordingly, a flow passage corresponding to the ink chamber 104 and the ink channel 103 is formed (
After the formation of the manifold 102, the ink channel 103, and the ink chamber 104, the cyclized rubber 142, which is a protective material formed on the discharge port plate 111, is removed using, for example, xylene (
The positive resist or the photosensitive polymer used as the discharge port pattern 140 is then removed to form the upper part of the discharge port 116. Thus, the outside and the first protective layer 112 communicate with each other through the upper part of the discharge port 116 (
Next, the first protective layer 112 communicating with the outside is removed from the discharge port plate 111 side by, for example, reactive ion etching, chemical dry etching, or sand blasting via an appropriate mask so as to form the lower part of the discharge port 116 (
Finally, the resulting silicon wafer is separated into desired chip units using a dicer, as needed. Thus, the ink-jet recording head can be produced.
The ink-jet recording head and the method of producing the head described above have the following advantages.
Since the portion 115a of the metal layer 115 having good thermal conductivity included in the discharge port plate 111 is directly in contact with the substrate 101, heat remaining in the heaters 114 and the periphery thereof can be effectively dissipated to the substrate 101. Accordingly, this structure can suppress an increase in the temperature at the discharge ports. As a result, the drive frequency can be improved.
Furthermore, since the portion 115a of the metal layer 115 functions as a part of a wall surface of the ink channel 103 and the ink chamber 104, the portion 115a of the metal layer 115 effectively functions as an etching stop layer during the formation of the ink channel 103 and the ink chamber 104. Accordingly, the dimensional accuracy during processing of the ink channel 103 and the ink chamber 104 can be improved. As a result, the discharge ports 116 can be arranged at a high density.
In this embodiment, as shown in
In addition, the metal layer 115 dissipates heat generated in heaters 114 and the periphery thereof to the outside (heat-dissipating member 121). Examples of the material of the metal layer 115 include metals having good thermal conductivity, such as nickel (Ni), copper (Cu), aluminum (Al), and gold (Au). However, gold (Au) can be used as the metal layer 115 because not only thermal conductivity but also ink resistance (corrosion resistance) is required for the metal layer 115 functioning as a top surface layer of the discharge port plate 111.
More specifically, a barrier layer made of, for example, titanium tungsten (TiW), and a seed layer made of, for example, copper (Cu), chromium (Cr), titanium (Ti), gold (Au), or nickel (Ni) may be provided under the metal layer 115.
The heat-dissipating member 121 has a low thermal resistance and a large heat capacity in order to diffuse heat transmitted from the metal layer 115. In order to reduce the thermal resistance with the metal layer 115, a metal layer having an area larger than the area of an end of the metal layer 115 may be formed on the heat-dissipating member 121 by, for example, gold plating. In such a case, by increasing the contact area or increasing the volume in order to increase the heat capacity, a higher heat dissipation efficiency can be achieved.
First, prior to the deposition of a third protective layer 117, which corresponds to the second protective layer 113 shown in
Next, the third protective layer 117 is formed on a second protective layer 113 and a conductor (not shown) that transmits electrical signals to heaters 114. A through-hole 143 penetrating through the protective layers 112, 113, and 117 and the substrate 101 is then formed (
The through-hole 143 is formed by sequentially etching the protective layers 112, 113, and 117 and the substrate 101 by reactive ion etching (RIE), which is a dry process. Alternatively, for example, an excimer laser process or sand blasting may also be used.
Next, a metal layer 115 is formed on the third protective layer 117 and inside the through-hole 143 (
Furthermore, the metal layer 115 must be formed so as to have a projecting shape projecting from the reverse face of the substrate 101 (i.e., the face opposite a discharge port plate 111). In this case, the metal layer 115 in the through-hole 143 may be formed so as to have a cylindrical shape or a bar shape. The metal layer 115 in the through-hole 143 may be formed so as to have a bar shape in order to increase the heat capacity.
Next, a manifold 102 is formed by performing a first isotropic etching (AE) process, which is a wet process, from the reverse face side of the substrate 101 (
Furthermore, the sacrificial layer 131 is removed through the manifold 102 by etching using anhydrous hydrofluoric acid. Subsequently, the substrate 101 is etched along the (111) plane of silicon by performing a second isotropic etching (AE) process to form an ink channel 103 and an ink chamber 104 (
Furthermore, a surface protective resist 138 is removed, and a pattern mask is then formed using a dry film. The protective layers 112 and 113 are removed by a dry etching process, thus allowing the discharge port 116 to communicate with the ink chamber 104 (
Subsequently, an end of the metal layer 115 is joined to a metal layer 144 that is formed on an alumina (Al2O3) heat-dissipating member 121 by plating (
Alternatively, as shown in
By providing the heat dissipation path penetrating through the substrate 101 on the discharge port plate 111 including the heaters 114, heat storage in bubble-generating portions can be suppressed even in a successive printing. Consequently, an effect of stabilizing the amount of discharge can be achieved.
More specifically, according to this embodiment, in a back-shooting-type ink-jet head, a portion of the metal layer 115 included in the discharge port plate 111 penetrates through the substrate 101 and is joined to the heat-dissipating member 121. Accordingly, heat generated from the heaters 114 can be dissipated to the heat-dissipating member 121 through the metal layer 115 to suppress an increase in the temperature of the discharge port plate 111. As a result, an increase in the temperature of ink can also be suppressed, and thus, the amount of ink discharge can be further stabilized. Furthermore, with an improvement in the heat dissipation efficiency, the drive frequency can be increased. Accordingly, an ink-jet head having an improved discharge performance and high reliability can be provided.
The liquid-discharging heads of the present invention that have been described in the above embodiments can be installed in apparatuses such as a printer, a copying machine, a facsimile having a communication system, and a word processor having a printer unit; and industrial recording apparatus combining various processing apparatuses. Consequently, recording can be performed on various types of recording media such as paper, threads, fabrics, cloths, leathers, metals, plastics, glass, wood, and ceramics using these liquid-discharging heads.
The term “recording” used in this specification means not only that an image having meaning, such as a letter or a figure, may be deposited on a recording medium but also that an image having no meaning, such as a pattern, may be deposited on a recording medium. Furthermore, the term “ink” or “liquid” should be given a wide interpretation and means a liquid to be supplied to the formation of an image, a figure, a pattern, or the like; a processing of a recording medium; or a processing of ink or a recording medium by being deposited on the recording medium. Herein, the term “processing of ink or a recording medium” means, for example, improving the fixing property caused by coagulation or insolubilization of a coloring material contained in ink to be deposited on the recording medium, improving the recording quality or color developability, and improving image durability.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is 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 modifications and equivalent structures and functions.
This application claims the benefit of Japanese Application No. 2007-206520 filed Aug. 8, 2007, which is hereby incorporated by reference herein in its entirety.
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2007-206520 | Aug 2007 | JP | national |
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Number | Date | Country | |
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