The present invention relates to Japanese Patent Application No. 2006-264600, filed Sep. 28, 2006, which is incorporated herein in its entirety and which forms a basis for a priority filing date.
The present invention relates generally to the field of keyboard devices and, more particularly, to keyboard devices that are able to reduce the occurrence of undesired sounds when pressing keys along with being able to provide a secure attachment of a cover plate to a base.
Japanese Examined Patent 1974-35209 discloses use of a hard material to increase the strength of the keys. When pressed by a musical performer, if coarse material was used to increase the absorbency, there was a problem in that the keys were weak.
The surface material (plate) submerged into absorption fluid is affixed to the key (base) surface using an adhesive. The key affixes the surface material with a different characteristic than the key surface, as described in Japanese Unexamined Patent 1995-44156.
However, the key affixed to both the base and the plate was pressed excessively by performers, and if it continued for a long period of time after being affixed, the strength of the adhesive could wear off, and the plate could become loose.
Also, because the adhesive is applied between the base surface and the plate surface, if the adhesive is not evenly distributed, one area can become loose, leaving an empty space between the base and the plate. When this empty space occurs, an undesired noise can occur when the performer touches the keys, and this may confuse the performer.
Embodiments of the present invention provide a keyboard device that can reduce the occurrence of undesired noises when the keys are pressed, strengthen the bond between the base and the plate, and/or solve other problems mentioned above.
In one aspect, a keyboard device has a plurality of keys, wherein each key has a support base where one end of each key is supported and is arranged to allow for movement. The keyboard also has a plate that hides the surface of the base. The keys are formed with ultrasonic welding of the merged base and plate. It is possible to weld while merging the base and the plate together, because the base and the plate are connected by ultrasonic welding. Compared to gluing the base and plate together using traditional adhesives, it is possible to have the base securely bound to the plate. It is then possible to have performers use the device for an extended period of time. The result is the ability to reduce the chances of the base and the plate becoming loose.
In one embodiment, the base is created with a wood-coloured resin, while the plate is created with a white-coloured resin. Because the plate is created with a white-coloured resin, the result is the ability to have a keyboard device that has an elegant sense of charm with simple composition.
In one embodiment, the base and the plate may have different kinds of materials added to them. Thus, the base and the plate may be composed of a primary ingredient with a similar resin. Because different ingredients are added, the result is that it is possible to demonstrate special qualities on these objects. For example, by adding an ingredient which hardens the plate, it is possible to increase the strength of the plate. In addition, it is possible to increase the hygroscopic characteristics of a plate by adding a material which increases the water absorption characteristics of the plate. In addition, it is possible to securely fix the objects together with ultrasonic welding because the base and the plate may use the same primary ingredient.
In one embodiment, the plate has a surface on the front that hides the front side of the base. Thus, the plate is affixed from top and front surfaces. The top surface is welded by ultrasonic energy on the top surface of the base, and the front surface serves to conceal the front surface of the base. In general, because the keyboard device is aligned with and attached to the keys, the areas regularly seen by performers are the top and front surfaces. When using this keyboard device, the result is that it is possible to minimize any loss of elegance with a simple design, because the plate conceals the top and front surfaces. Also, after the base and plate are welded, the result is that it is possible to minimize the amount of manufacturing work required with the presence of the top and front surface, because only the top surface is welded by ultrasonic welding.
In one embodiment, the plate has an area or projection that protrudes from the top surface to the base for melting by ultrasonic welding.
More specifically, the plate has a surface facing the base and the surface has a first area extending from the front surface of the base to a predefined distance from the front surface. The ratio of the at least one protrusion area in the first area to the overall first area is greater than the ratio of the at least one protrusion area located outside of the first area to the overall area located outside of the first area. The edge of the keys sometimes makes undesired noises when touched if there are many cracks between the base and the plate from being pressed by performers. However, with the above ratios of welding protrusion areas relative to the areas of the plate or base, it is possible to lessen these noises and reduce the cracks between the base and the plate due to the fact that it is possible to securely weld the portion of the keys pressed by performers.
In one embodiment, the base has a convex shape in the location of the welding space once the plate has merged. Thus, it is possible to house the melted resin within the gap in case the protruding component used for welding melted, because the gap is formed at a location which corresponds to the welding space. Therefore, the result is that the melted resin remains between the top surface of the base and the plate, and it is possible to prevent the plate from slanting when being welded against the base.
In one embodiment, the welded area has an incline from front to back, and the plate has an opening connected to an inclined welding space after the plate merges. The incline may be curved, or the incline may be flat. A circular cone may be formed at the center of the path linking the front and back sides to be welded with the base. The plate will be urged toward the back side of the base as the incline is moved through the opening while welding. The result of this can create a crack between the front side of the plate and the front side of the base. The plate also cannot stay in position because it will move along the incline to the center from the edge of the opening while welding. Thus, the incline with one welding space is located at the end of the top surface of the plate. This inclined weld has a slant from the edge side to the end side. The incline is attached to an opening set up on the base. Generally, if using ultrasonic energy to weld, the incline will melt and be welded while sliding the opening to the end side, because the plate is welded by ultrasonic energy waves when held down from the top. Therefore, the result is that it is possible to improve the quality of the keys' outer surface, and also possible to prevent cracks from forming between the front ends of the base and the plate.
In one embodiment, the plate has a protuberance that penetrates through the top surface of the base. The base has enough empty space to house the front end of the protuberance and the area connected to the front side of the protuberance. The distance between the front side of the base to the linked area and the distance between the front side and the end side is substantially identical. On the base is a receptacle area with enough empty space to house the end edge on the protuberance and the linking component which links with the edge side of the protuberance. Also, in the event the plate merges with the base, the protuberance is housed while linking the receptacle area linking component and the edge end of the protuberance together, because the distance made between the edge end of the base and the linking component as well as the distance between the front surface and the edge end of the protuberance are identical. Therefore, when placing the plate on the base, the plate may be prevented from moving or sliding away from its proper position, because it is possible to select a location where movement to the edge end is restricted. Also, the yield rate may be improved and the possibility of having a defective product may be reduced, because the plate is placed in its proper position.
In one embodiment, the plate supports the protrusion area from the top portion to the base. The protrusion area is arranged in a second dimension orthogonal to the first dimension and joined with the front side and the back side. The base provides a receptacle with enough empty space to house the length of the front end of the protruding area by linking each linking space with the space outside the protrusion area in the second dimension. The distance from the outer edge of the base area to the linking space in the second dimension is the same as the distance between the outer surface on the top and the outer side of the protruding area. As in the receptacle, it may be composed of a linking component that links with the end side of the protuberance. There may also be receptacle space for housing every protuberance as there should be a component that links with the outer surface on the second path of the protuberance. Furthermore, the protuberance may hold the welded material melted by ultrasonic welding. On the edge of the protruding area linked to the linking component and the linking component for the housing space is a curved surface, or similarly, a plane or a protruding surface, or other suitable shapes. The linking component and the protrusion area are more ideal for protruding shapes from the top surface to a perpendicular path. This will make it impossible to choose a location that is easy for the protrusion area to detach from the housing space if the end of the protrusion area is obtuse on the top surface. On the other hand, if it is acute, the protrusion area may become a problem if the plate merges with the base. As used herein, “roughly equal distance” also includes identical distant. It should also be separate from ranges where it is possible to choose a location for the plate in respect to the base. This separation is ideally set by the largeness of the plate and the base. Thus, on the plate, a protuberance sits in the second dimension running orthogonally to the first dimension linking the edge with the rear end. For the base, it is equipped with a receptacle which has enough empty space to house the edge of the protuberance with the linking component linking with the edge outside the protuberance along the second dimension. Also, in the event the plate merges with the base, the protuberance is housed while linking the housing device linking component and the edge end of the protuberance together, because the distance made between the edge end of the base and the linking component as well as the distance between the front surface and the edge end of the protuberance are substantially identical. Therefore, when placing the plate on the base, the result is being able to prevent the plate from moving from its proper position to a position the plate slides to, because it is possible to select a location where movement to the second path of the plate is restricted. Also, another result is being able to improve the yield rate and reduce the possibility of having a defective product because the plate is placed in its proper position.
In one embodiment, the base has multiple support areas to support the bottom surface of the plate once the plate has merged. The plate has a space where it fits between the supports and is arranged on the bottom surface. Thus, when the plate is placed on top of the base, the lower front surface on the plate will be supported by the supports. Furthermore, the fitting space for the plate is housed between the supports. Therefore, when the plate is merged with the base, the plate is prevented from sliding away from its proper position, because of the ability to choose a location along the second dimension running orthogonally to the dimension linking the rear side with the edge using the supports and the fitting space. Also, the occurrence of undesired noises is reduced by preventing the front surface from loosely flapping from vibrations when stroking the keys, yet making it so that the front surface need not be welded because the lower section of the front surface of the plate is supporter by the support device.
In one embodiment, the front surface of the plate area forms a groove extending from the lower surface toward the top surface on the surface of the base area. The base area forms a notch area located in the place which corresponds to the grooved area at the front end of the lower surface. Thus, on the front surface of the plate, a grooved area extended from the edge of the lower section on the front surface toward the top surface is formed at the surface of the base. On the base, it is possible to apply an adhesive to this groove from the notch component with ease, because the notch component is formed at the location targeted for the groove area at the lower edge. Therefore, after the plate and the base are welded using ultrasonic energy, if a gap exists between the area on the front surface and the entire surface, it is possible to conjoin the entire front surface with the front surface portion and apply an adhesive from the notch. Thus, the result is being able to reduce the likelihood of defective products through simple manufacturing.
In one embodiment, the base has a set empty space formed between the rear end of the plate area once the plate has merged. Thus, on the base, it is possible to house the remains of a gate remaining on the rear side of the plate at a fixed space. Generally, the rear end of the keys do not affect the aesthetics of the keys and, thus, the aesthetics of the keys are not impacted by the gate on the rear end of the plate. Therefore, the result is being able to omit from the manufacturing process, a procedure for removing or otherwise processing a gate by creating this space, and in turn, being able to design a cost-efficient device.
a) is a top view of a keyboard device according to an embodiment of the present invention;
b) is a side view of the keyboard device of
a) is a perspective view of a white key according to an embodiment of the present invention prior to welding;
b) is a perspective view of the white key of
a)-(d) are various views illustrating the structure of an exemplary white key according to an embodiment of the present invention, wherein
a)-(d) are various views illustrating the exterior and the cross-section of an exemplary white key according to an embodiment of the invention, wherein
a)-(c) are various cross-sectional views illustrating the composition of the protuberance area and the housing space according to an embodiment of the invention, wherein
a)-(d) are various cross-sectional views illustrating the structure of the protrusion area and the hole according to an embodiment of the invention, wherein
a) and (b) illustrate the front end of the exemplary white key, wherein
a) and (b) illustrate detailed cross-sectional views of a lower section of the front end of the exemplary white key, wherein
a)-(c) illustrate the composition of the lower front ends of the base and the plate according to an embodiment of the invention, wherein
Below are examples of certain embodiments and uses for certain embodiments of the present invention, with figures for reference and elaboration.
As shown in
Also, when a white key 2 or a black key 3 is pressed and pivoted about the axle 5, a corresponding hammer 6 in the chassis 4 is swung about its center and activates a switch 9 on a printed board 8, which is secured by an actuator 7 of the hammer 6 below the chassis 4. On the keyboard device 1, the key behaviour is determined by operating the switch 9, and sounds are emitted by a control unit (not shown in the figures).
a) and (b) are perspective illustrations of a white key 2 according to an embodiment of the present invention.
The white key 2 is composed of a base 21 pivotably supported on the turning axle 5, and a plate 22 concealing at least one surface of the base 21. The base 21 has a top surface 23 and a front surface 24 on a front side (in the X dimension). The plate 22 is composed of a top surface area 25 welded by ultrasonic waves to the top surface 23 of the base 21, and a front surface area 26 hiding the front surface 24 of the base 21.
Also, because the white key 2 and black key 3 are adjoined and aligned in rows (see
In one embodiment, the base 21 is formed of a wood-coloured resin, and the plate 21 is formed of a white-coloured resin. Therefore, it is possible to manufacture a white key 2 with an aesthetically-pleasing appearance, while allowing assembly of the device with ease.
The base 21 and the plate 22 may be merged together by a mould made from the resin. Therefore, the base 21 and the plate 21 can be tightly bonded together by ultrasonic welding, because they may have a similar main ingredient. Also, a hard material can be added to the resin in the plate 22, thus strengthening the plate 22.
Next, with reference to
a)-(d) illustrate the structure of white key 2.
As shown in
Below is an explanation of features for merging the base 21 and the plate 22 and ultrasonic welding according to an embodiment of the invention.
As shown in
The welding protrusion areas 31a-f extend in a straight-line fashion along the X dimension on the plate 22. Protrusion areas 31a and 31b extend along substantially the total length of the plate 22. Protrusion areas 31c-e are at an area corresponding to and targeted for the key depression area 2a on the plate 22. Protrusion area 31f extends along the front edge of the plate 22 in the Y dimension. Protrusion area 32 is formed at the rear end of the plate 22. The pair of protuberances 33 are formed on each side of the protrusion area 31f.
As shown in
The protrusion areas 31a-31f occupy a portion of the depression area 2a, and a portion of the length of protrusion areas 31a and 31b also occupy the area 2b. The ratio of the area occupied by the protrusion areas 31a-31f within the depression area 2a relative to the overall depression area 2a is greater than the ratio of the area occupied by the portion of the length of protrusion areas 31a and 31b that occupy the area 2b relative to the overall area 2b. In the illustrated example, the key depression area 2a is welded in six places (along protrusion areas 31a, 31b, 31c, 31d, 31e, 31f), while the long, narrow area 2b is welded in two places (along protrusions 31a and 31b). As a result, when the base 21 and plate 22 are welded together, the weld density is greater in the key depression area 2a than in the long, narrow area 2b. As a result, the key depression area 2a is able to avoid a gap or empty space from forming between the base 21 and the plate 22, and, thus, limit the occurrence of undesired noises caused by such gap or empty space during key depression.
Next, with reference to
The protrusion area 31e is formed in a convex, generally triangular shape on the cross-sectional view. The groove 41e is formed in a generally rectangular gap on the cross-sectional view. Also, the width of the groove 41e is larger than the width of the protrusion area 31e.
Therefore, once the plate 22 is placed on top of the base 21, the tip of the protrusion area 31e is joined with the surface of the groove 41e. Then, if the base 21 and the plate 22 are welded together using ultrasonic waves, the equal distribution strengthens the bond on the groove 41e where the protrusion area 31e melts. Also, it is possible to prevent the resin melted by the ultrasonic welding from jutting out within the groove 41e, and it is possible to avoid inadvertent welding of the top surface area 25 of the plate 22 and in a manner in which melted resin flows between the top surface 23 of the base 21.
a)-(d) illustrate the exterior and cross-sectional views of the exemplary white key 2.
With reference to
As shown in
Therefore, when merging the plate 22 with the base 21, it is possible to properly position the plate 22, because the exterior surfaces 33a and the exterior surfaces 43a are aligned.
As shown in
Therefore, as shown in
The sides 33a, 33b, 43a and 43b are aligned along the Z dimension on the white key 2. Thus, the sides 33a, 33b start from the top surface area 25 along an approximately perpendicular path, and the sides 43a, 43b start from the top surface 23 along an approximately perpendicular path. For example, if the sides 33a, 33b, 43a, and 43b have a slant from the edges to the rear end, there will be difficulty in having the protrusion area 33 placed in a location that is easy to disconnect from. If the sides 33a, 33b, 43a and 43b have an incline from the rear end to the edge (in the X dimension from the right to the left), the protrusion area 33 becomes a hindrance when the plate 22 is planted on top of the base 21. If using this example, the protrusion area 33 can limit the possibility of being disconnected from the receptacle 43, and it is possible to prevent the protrusion 33 from becoming a strain on the receptacle 43, because the sides 33a and 33b protrude from the top surface area 25 along an approximately perpendicular path, and the sides 43a and 43b start from the top surface 23 along an approximately perpendicular path.
In this example, arranging the sides 33a, 33b, 43a, and 43b onto a plane makes a semicircle-shaped protuberance on the protuberance area 33, and a housing device may be provided with a corresponding semicircle-shaped crevice. In this case, the protuberance area 33 and the housing space 43 are merged at a location where the edge of the protuberance area 33 and the exterior, curved surface, and the edge of the receptacle 43 and the exterior, curved surface are conjoined. Alternatively, the shape of the edge of the protuberance area 33 and the exterior edge, and the edge of the receptacle 43 and the exterior edge conjoined to the edges of the protuberance area 33 and the receptacle 43, need not be flat but may be curved surfaces, or have pointed shapes, or other suitable shapes.
Furthermore, the protuberance area 33 has the sides 33a and 33b, while the housing space 43 may have the sides 43a and 43b that attach with the sides 33a and 33b. Also, for the protuberance area 33 and the receptacle 43, each pair may include one protuberance area 33 with one housing space 43, or may be two or more protuberance areas 33 for each one housing space 43.
The distance between the surface of an end 33a of the projection area 22 to the exterior surface of the plate 22 is the same distance (t2) as the distance between the surface of an end 43a of the housing space 43 to the exterior surface of the base 21. In addition, the distance between the surface of an end 33b of the projection area 33 to the interior of the front section 26 of the plate 22 is the same distance (t4) as the distance between the surface of an end 43b of housing space 43 to the surface of the front 24 of the base 21. However, in other embodiments, the distance between the surface of an end 33a of the projection area 22 to the exterior surface of the plate 22 can be made different from the distance between the surface of an end 43a of the housing space 43 to the exterior surface of the base 21. Similarly, the distance between the surface of an end 33b of the projection area 33 to the interior of the front section 26 of the plate 22 can also be made to be different from the distance between the surface of an end 43b of the housing space 43 to the surface of the front 24 of the base 21. In that regard, when putting plate 22 on base 21, the distances t2 and t4 need not be completely in agreement, but should be sufficiently accurate to set an attachment position. For example, the distance between the surface of an end 33a of the projection area 33 to the exterior surface of the plate 22 is the distance (t2), which may be slightly longer than the distance between the surface of an end 43a of the housing space 43 to the exterior surface of the base 21 (t2′), where:
t2-t2′>0 when t2>t2′. Similarly, the distance between the surface of an end 33b of the projection area 33 to the interior of the front section 26 of the plate 22 (t4) is a distance slightly longer than the distance between the surface of an end 43b of housing space 43 to the surface of the front 24 of the base 21 (t4′), where t4-t4′=about 0.1 mm.
Next, with reference to
As shown in
Additionally, as shown in
Also, the plate 22 moves from its place in
As shown in
Regarding the protrusion area 32, areas making up the lower tier 32a, the central tier 32b and the upper tier 32c may have a protrusion area on only one cylinder extending out from the middle surface of the upper surface area 25. If the shape contains an incline from one end to the other, the plate 22 would be extended to the end side when welding with ultrasonic waves.
Next, with reference to
As shown in
As shown in
Next, with reference to
As shown in
The groove 36 and the notch 46 allow for applying an adhesive with ease from the groove 36 to the notch 46 once the base 21 and the plate 22 have been welded together. If the plate 22 and the base 21 are welded together and a new gap or crack forms between the front surface 24 and the front surface area 26, the product can be defective. However, the product can be improved or made operable by applying an adhesive from the notch 46 to the groove 36 to affix the front surface 24 and the front surface area 26.
Next, with reference to
Here, an explanation of the plate 22 as a moulded element is provided. In one embodiment, the plate 22 has a gate on the exterior surface, because it has been moulded. In this situation, however, if the gate is not removed, this will make the white key 2 less aesthetically pleasing, and because there is a possibility that it may get damaged during welding, the gate may be removed before placing the plate 22 on top of the base 21.
On the embodiment of the plate 22 shown in
The first free space 47a is an empty space for housing the gate remainder 37 on the plate 22 and is formed at a large empty space able to house the shape of the gate remainder 37 in a non-fixed, moveable state.
The size of the gate remainder 37 unsuitable for operator processing may vary in such cases during normal processing. Without this empty space, in order to avoid damage during welding, it may be necessary to carefully process the gate. In order to avoid this problem, the first free space 47a can be generally a sufficiently large space to accommodate various sizes of gate remainder 37.
The second free space 47b is also an empty space for housing a gate remainder 37, but the first free space 47a is formed to take in the side of the left side in the X dimension while the goal of the second free space 47b is to be able to house the lower section in the Z dimension while in a moveable, non-fixed state.
During normal processing, a divided protuberance is easily formed as seen in the Z dimension of the gate remainder 37. If there is no second free space 47b, these protuberances will be damaged during welding.
In this situation, by setting up the first free space 47a and the second free space 47b, it is possible to plan an increase in the operating efficiency because of the possibility of removing the irrelevant gate procession operation once the gate has been formed on this part of the plate 22.
Thus, as explained above, the keyboard device 1, traditionally using an adhesive, is capable of being securely fastened if the base 21 and the plate 22 are conjoined, because the base 21 and the plate 22 are welded together using ultrasonic waves. Therefore, it is possible to prevent the base 21 and the plate 22 from loosening after long term use even if, for example, operators firmly depress the keys.
Also, the plate 22 has the protrusion area 32, the protuberance 33, and the fitting space 35, while the base 21 has the hole 42, the housing space 43, and a pair of supporters 44. Each of these is capable of preventing the base 21 and the plate 22 from being welded at a position other than their proper position because they set the location for the plate 22. Therefore, it is possible to increase production efficiency.
The present invention is not limited to the above examples, and it is possible to easily surmise possible alteration without departing from the aim of this invention.
For example, in the above example, the protuberances 31a-31f being made up of a convex shape on a straight line, the convex shape could have curved lines, several convex shapes could be made, and straight lines, curved lines, and the scattered shapes could be combined. Also, protuberances 31a-31f may be formed on the base 21 (instead of the plate 22), while corresponding grooves and indentations may be provided on the plate 22 (instead of the base 21). Alternatively, each of the base 21 and plate 22 may include both protuberances and grooves or indentations that mate with corresponding indentations and grooves on the other of the base 21 and plate 22.
Also, the above examples explain the special characteristics of an exemplary white key 2, but these are also applicable to a black key 3.
While particular embodiments of the present invention have been disclosed, it is to be understood that various different modifications and combinations are possible and are contemplated within the true spirit and scope of the appended claims. There is no intention, therefore, of limitations to the specific disclosure herein presented.
Number | Date | Country | Kind |
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2006-264600 | Sep 2006 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
3965791 | Thomas et al. | Jun 1976 | A |
4043244 | Schrecongost et al. | Aug 1977 | A |
4059737 | Gergaud | Nov 1977 | A |
20060219085 | Kamijima et al. | Oct 2006 | A1 |
Number | Date | Country |
---|---|---|
49-35209 | Mar 1974 | JP |
07-44156 | Feb 1995 | JP |
2003249146 | Sep 2003 | JP |
2005190743 | Jul 2005 | JP |
Number | Date | Country | |
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20080174457 A1 | Jul 2008 | US |