1. Field of the Invention
The present invention relates to a method of manufacturing a fluid path structure to be used for conveying liquid, which may typically be a fluid path structure to be used in an inkjet head.
2. Description of the Related Art
Structures having fluid paths for conveying fluid such as liquid or gas in the inside of the three-dimensional body thereof by covering a resin plate having grooves formed on the surface thereof by means of a flat resin plate bonded thereto are known. For example, a holder unit that is a component of a liquid ejection head such as a tank-mounted inkjet head is one of such structures.
Such a holder unit includes a resin-made holder and a fluid path forming member and is produced by welding them together at the opposite surfaces thereof. Grooves that become ink path and ribs to be welded that run along the grooves are arranged on the surface to be welded of the fluid path forming member. On the other hand, grooves are arranged at the positions opposite to the respective ribs on the surface to be welded of the holder. Ink paths are completed as the holder and the fluid path forming member are joined together typically by means of an ultrasonic welding method.
Generally, alignment means are arranged on a pair of resin members of the above-described type that are to be welded together in order to weld them properly. Japanese Patent Application Laid-Open No. 2007-007968 discloses an alignment structure for suitably aligning two members without interfering with the operation of welding the two members.
With an ultrasonic welding method, the resin members that have welding zones are brought into contact with each other and then fused at the welding zones and joined together by means of the frictional heat that is generated due to the vibrations and pressure applied to them. Particularly, in the case of welding a fluid path forming member to be used for conveying fluid, the member needs to be reliably fused and joined with the partner member at the welding zones thereof in order to achieve airtightness for the fluid paths.
Conventionally, a fluid path forming member to be used for an inkjet head having a holder unit is aligned in the above-described manner and welded to the partner member typically by ultrasonic welding to produce fluid paths in it. In such welding operations, the conventional welding technique has been acceptable even if the members to be welded contact with each other at areas other than the welding zones such as the alignment areas and/or one or more than one outer peripheral parts of the fluid path forming member.
However, if the number of color inks is increased and/or if larger fluid path forming members and/or more complicated ink paths are employed in the future, the vibration energy that is applied to the welding zones will be lost, if partly, than ever at the contact area or areas while the welding operation is proceeding to consequently degrade the performance of the welding operation particularly at parts located near the contact area or areas, which results in liquid leakage.
According to the present invention, the above-identified problem is dissolved by providing a method of manufacturing a fluid path structure including: an aligning step of aligning a first resin part with a second resin part by inserting a projection formed on the first resin part into a corresponding hole formed on the second resin part; and a welding step of welding joint surfaces of the first resin part and the second resin part that have been aligned, thereby forming a fluid path; the aligning step being executed so as to narrow the gap between the projection and the hole to a minimum at a base side of the projection relative to a half of the height of the hole; the welding step being executed only at the base side of the projection relative to the half of the height of the hole so as to make the lateral surface of the projection only partially contact with the lateral surface of the hole.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Now, the present invention will be described in greater detail below by referring to the drawings that illustrate preferred embodiments of the invention.
On the other hand, a plurality of ribs 21 are arranged on the surface (joint surface) of the second weld member 2 that is to be joined with the first weld member 1. The ribs 21 are arranged at positions located vis-à-vis the corresponding welding grooves. Note that a welding groove that is to operate as part of the ink path may be formed between the ribs 21.
Ribs 21 to be used for the purpose of the present invention generally are triangular in cross section (see the cross-sectional view of
The profile of the hole 22 is not limited to the one illustrated in
The description of the first embodiment will now be resumed by referring back to
Additionally, as the weld member 1 and the weld member 2 are joined together, the projection 13 is put into the holes 22 and the lateral surface of the projection 13 is made to partially contact with the lateral surface of the hole 22 at the base side of the projection relative to a half of the height of the hole 22. In other words, a portion of the lateral surface of the projection 13 and a corresponding portion of the lateral surface of the hole 22 that are located at the base side at positions lower in height than a half of the height of the hole become their contact portions.
Now, the welding method for assembling the weld members to produce a fluid path structure as illustrated in
The gap between the two members at the above-described contact portions is required to represent a degree of accuracy within the allowable welding position accuracy limit. For this reason, according to the present invention, the gap between the projection 13 and the hole is narrowed and minimized at the base side of the projection relative to a half of the height of the hole 22.
Besides, the projection 13 comes to represent slight lateral deflection, staring from the base thereof, when it is subjected to ultrasonic vibrations. Therefore, the projection 13 is preferably welded to the lateral wall of the hole 22 at a position located close to the base of the projection 13 where the deflection is relatively small in order to weld them and the contact area of the contact portions is desirably made as small as possible so that the welding operation may represent a degree of accuracy within the allowable welding position accuracy limit.
The tendency illustrated in
As described above, the aligning means (at the aligning position) for the two weld members 1 and 2 is characterized in that it consists in only partial contact of the lateral surface of the projection 13 and the lateral surface of the hole 22 and the partial contact area is located at the base side of the projection relative to a half of the height of the hole 22.
Known ultrasonic welding techniques include one to be executed by arbitrarily specifying the penetration amount (mm) that defines the amount by which the ultrasonic welding horn is moved during ultrasonic oscillation, one to be executed by arbitrarily specifying the length of time (second) for which ultrasonic energy is transmitted to the object to be welded and one to be executed by arbitrarily specifying the amount per unit time of energy (joule: the number of watts per second) to be transmitted to the object to be welded.
The ultrasonic welding technique that is to be executed by specifying the penetration amount (mm) is selected for this embodiment so that ultrasonic waves may reliably penetrate into the contact area in order to avoid any liquid leakage from taking place after the welding.
With ultrasonic welding, vibrations are applied to the joint surfaces in the direction perpendicular to the joint surfaces. As illustrated in
Alternatively, a plurality of curved projections 221 as illustrated in
As for the number and the positions of curved projections 221, for example, four curved projections may be arranged on the lateral surface of the hole 22 at regular intervals in the circumferential direction that is perpendicular to the axial direction of the hole 22 as illustrated in
While means for narrowing the gap between the projection 13 and the hole 22 is arranged in the hole 22 with the arrangement of
Thus, with the above-described welding technique, the weld member 1 and the weld member 2 can easily and accurately be aligned with each other and welded to each other without allowing contact of any parts thereof other than the welding zones that can interfere with the welding operation.
For example, if a first weld member 100 has a wall as illustrated in area A in
As described above, the influence of deflection of the projection 13 during the ultrasonic welding process can be minimized by aligning the first weld member and the second weld member by bringing the projection 13 that is arranged on the first weld member 1 and the hole 22 that is arranged in the second weld member 2 into mutual engagement and making them contact with each other in a partial contact area that is located at the base side of the projection relative to a half of the height of the hole 22. Then, therefore, the two weld members can be welded to each other within the allowable positional accuracy without allowing contact of any parts thereof other than the welding zones 14. Furthermore, the vibration energy can be concentrated to the welding zones 14 for welding without any significant loss of energy.
Thus, the present invention provides a method of manufacturing a fluid path structure, in which the related parts thereof in the welding zones are excellently welded and which is made to be free from liquid leakage.
Now, the second embodiment of the present invention will be described below.
The recording element board 1100 is formed by using a silicon board having openings that operate as ink supply ports and a plurality of heat-generating resisters are arranged on the board in order to apply thermal energy to ink as thermal energy is required to eject liquid. Such a board on which heat-generating resisters are formed is referred to as heater board. A heater board is provided with wiring for supplying electric power to the heat-generating resisters and electrically connected to the electrode pads arranged at the opposite ends of the board by means of the wiring. A complete recording element board 1100 is formed by bonding an ejection port forming member having a plurality of ejection ports onto the heater board. Note, however, that the applicable scope of the present invention is by no means limited to liquid ejection heads that employ heat-generating resisters but includes those that includes a recording element board having an energy-generating means for generating energy (e.g., heat, vibrations, static electricity, etc.) to be used for causing ink to be ejected from ejection ports
Wiring for supplying electric power to the heat-generating resisters on the heater board is arranged on the electric wiring board 1300. The recording element board 1100 and the electric wiring board 1300 are highly accurately joined to holding member 1200 by adhesion and supported by the latter. Additionally, the recording element board 1100 and the electric wiring board 1300 are electrically joined to each other by means of a TAB mounting technique and the joint parts thereof are hermetically sealed by means of a sealing material.
The holder 1500 is a member that corresponds to the above-described first weld member 1 and includes welding grooves 1502 and projections 1503 that operate as so many alignment pins.
The fluid path forming member 1600 is a member that corresponds to the above-described second weld member and includes groove-shaped ink paths 1601 having a profile same as that of the welding grooves 1502, welding ribs 1602 extending along the peripheral edges of the ink paths 1601 and alignment holes 1603 into which the projections 1503 are to be inserted respectively.
The holder unit 1003 that is a fluid path structure according to the present invention is formed by joining the holder 1500 and the fluid path forming member 1600 by ultrasonic welding. With regard to alignment of the holder 1500 and the fluid path forming member 1600, the contact portions thereof are preferably found near the base of the projection 1503 and the contact area of the contact portions thereof is preferably as small as possible.
As described above, the present invention is applicable to holder units that operate as ink paths of popular inkjet heads. The present invention provides a method of welding and joining a holder and a fluid path forming member for a holder unit, aligning them by bringing the projections 1503 of the holder 1500 and the corresponding respective holes 1603 of the fluid path forming member 1600 into partial contact at the contact portions thereof, which operate as aligning means and are located at the base side relative to a half of the height of the projections 1503. With this method, since the base side of the projections 1503 is less influenced by deflection during the ultrasonic welding process so that the welding process can be executed within the allowable limit for welding accuracy.
Thus, the resin parts do not contact each other except the welding zones (the joining sections at the front ends of the welding ribs 1602 and the peripheral edges of the welding grooves 1502) so that vibration energy can be concentrated to the welding zones for welding without any significant loss of energy. In this way, the present invention provides a method of manufacturing a fluid path structure in which the related parts thereof are excellently welded and which is free from liquid leakage.
While the present invention is applied to an inkjet head in this embodiment, the present invention is by no means limited to inkjet heads and provides a method of highly accurately aligning resin members and welding them in an excellent manner.
Additionally, for aligning and welding two weld members, one or more than one projections (13, 1503) are arranged at one of the weld members, or the weld member (1, 1500), and one or more than one holes, whichever appropriate, are arranged at the other member (2, 1603) in the above-described embodiments, However, the present invention is by no means limited to such an arrangement and also applicable to instances where one or more than one holes are arranged at the former weld member and one or more than one projections, whichever appropriate, are arranged at the latter weld member.
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 such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2013-118856, filed Jun. 5, 2013, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2013-118856 | Jun 2013 | JP | national |