| Patent application number | Description | Published |
|---|
| 20090167118 | PIEZOELECTRIC VIBRATING PIECES, PIEZOELECTRIC DEVICES, AND METHODS FOR MANUFACTURING SAME - Piezoelectric vibrating pieces are disclosed made of a piezoelectric material to be mounted in a package. A representative piece includes a base formed of a piezoelectric material, having first and second ends, extending between the ends in a length direction, and having a designated width. The piece includes at least a pair of vibrating arms extending in the length direction from one end of the base, and a pair of supporting arms extending partially in a width direction from between the first and second ends of the base. The supporting arms further extend in the length direction outboard of the base and vibrating arms, and include an adhesive region at the tips of the supporting arms. The adhesive regions are used for mounting the piece to a package. Whereas the tips of the supporting arms do not extend beyond the tips of the vibrating arms, the axial length of supporting arms is greater than the length of the vibrating arms. | 07-02-2009 |
| 20100079036 | PIEZOELECTRIC VIBRATING PIECES AND PIEZOELECTRIC DEVICES COMPRISING SAME - An exemplary tuning-fork type piezoelectric vibrating piece has at least a pair of vibrating arms extending from one end of a base portion in a certain longitudinal direction (e.g., Y-direction). Supporting arms extend from respective side edges of the base, outboard of the vibrating arms in the certain direction. The supporting arms have respective mounting regions near their distal tips. Each supporting arm progressively narrows from its proximal end, coupled to the respective side edge of the base, to its respective mounting region. The progressive narrowing can be via one or more constrictions along the length of the supporting arm. | 04-01-2010 |
| 20100079040 | PIEZOELECTRIC DEVICES HAVING IMPROVED IMPACT RESISTANCE - An exemplary piezoelectric vibrating device has a lid plate, a chip plate including a tuning-fork type vibrating piece surrounded by an outer frame, and a package base arranged where the chip plate is sandwiched between the lid plate and package base, and the three layers are bonded together. The tuning-fork type piezoelectric vibrating piece is connected to the outer frame by supporting arms. A base-movement buffer having a predetermined height in the X-direction extends from the inner edge surface of the outer frame toward a side edge of the base. The base-movement buffer has a height in the X-direction that is proportional to the length from the base-movement buffer to a point at which the tuning-fork type piezoelectric vibrating piece is coupled to the outer frame. | 04-01-2010 |
| 20100156237 | Tuning-Fork Type Piezoelectric Vibrating Piece and Piezoelectric Device - A tuning-fork type piezoelectric vibrating piece ( | 06-24-2010 |
| 20100156246 | Piezoelectric frames and piezoelectric devices comprising same - Piezoelectric frames are disclosed that include a tuning-fork type piezoelectric vibrating portion having a pair of vibrating arms extending from a base portion in a first direction (Y-direction). The vibrating arms have a first width W | 06-24-2010 |
| 20100164328 | Piezoelectric frames and piezoelectric devices comprising same - Piezoelectric frames are disclosed that include a tuning-fork type piezoelectric vibrating piece. The vibrating piece has at least a pair of vibrating arms that extend in a longitudinal direction (e.g., Y-direction) from a first end edge of a piezoelectric base, and at least one excitation electrode on the pair of vibrating arms. Respective supporting arms extend in the longitudinal direction, outboard of each vibrating arm. The vibrating piece is surrounded by and attached to a frame portion also made of piezoelectric material. A pair of connecting portions connects the supporting arms to the frame portion. The connecting portions extend from respective supporting arms to the frame portion in a direction that intersects the longitudinal direction. The connecting portions are connected to the frame portion at designated locations that are more than 50% of the designated length of the vibrating piece from the second end edge of the base. | 07-01-2010 |
| 20110156529 | Surface mounted crystal resonator - An object of the invention is to provide a surface mounted resonator that improves impact resistance by the shape of a mounting terminal provided on an outside bottom face of a stacked resonator. A surface mounted crystal resonator is provided with a plurality of mounting terminals electrically connected to a hermetically sealed crystal piece at both ends of an outside bottom face having a rectangular shape long in the lengthwise direction, the mounting terminals having the same external dimensions with a total dimension of the mounting terminals in a lengthwise direction of the outside bottom face being 70% or more [but less than 100%] of a dimension in the lengthwise direction of the outside bottom face. Respective facing sides of the mounting terminals facing each other in a central area of the outside bottom face are formed curved in a convex shape such that a curvature thereof decreases gradually. | 06-30-2011 |
| 20110221311 | PIEZOELECTRIC VIBRATING PIECES AND PIEZOELECTRIC DEVICES COMPRISING SAME - An exemplary tuning-fork type piezoelectric vibrating piece has a rectangular base having upper and lower main surfaces and a pair of vibrating arms extending longitudinally from the base. The vibrating arms also have the upper and lower main surfaces. Each main surface of each vibrating arm defines a respective vibrating-arm groove extending longitudinally into the base. Each main surface of the base has at least one respective step-side surface situated outboard, in an X-axis direction, of each vibrating-arm groove. Each step-side surface is parallel with the respective vibrating-arm groove. A first electrode is situated on the vibrating-arm grooves of the first vibrating arm and on the at least one respective step-side surface on each main surface. A second electrode is situated on the vibrating-arm grooves of the second vibrating arm and on the at least one respective step-side surface on each main surface. The first and second electrodes are energized with different electrical polarities. | 09-15-2011 |
