JP6527033B2 - Crystal device - Google Patents

Description

  The present invention relates to a quartz crystal device used, for example, in an electronic device.

  The quartz crystal device generates thickness-slip vibration so that both sides of the quartz plate are mutually offset by using the piezoelectric effect of the quartz crystal element, and generates a specific frequency. There has been proposed a quartz crystal device provided with a quartz crystal element mounted on an electrode pad provided on a substrate via a conductive adhesive (see, for example, Patent Document 1 below). In such a crystal device, a wiring pattern electrically connected to an electrode pad provided on the upper surface of the substrate is provided on the upper surface of the substrate.

Japanese Patent Application Laid-Open No. 2002-111435

  Although the above-described quartz crystal device is significantly miniaturized, the quartz crystal element mounted on the substrate is also miniaturized. In such a quartz crystal device, the area of the electrode pad is also small, and there is a possibility that the applied conductive adhesive overflows along the wiring pattern. In addition, when the conductive adhesive overflows onto the wiring pattern, the connection strength between the quartz crystal element and the conductive adhesive may be reduced, and the quartz crystal element may be peeled off from the electrode pad.

  This invention is made in view of the said subject, and it aims at providing the quartz crystal device which can maintain the connection intensity | strength of a quartz crystal element and a conductive adhesive.

A piezoelectric device according to one aspect of the present invention comprises a rectangular substrate, a frame provided along the outer peripheral edge of the upper surface of the substrate, a substantially rectangular electrode pad provided on the upper surface of the substrate, and an electrode pad And a wiring element provided on the upper surface of the substrate, a quartz crystal element mounted on the electrode pad, and a lid for hermetically sealing the quartz crystal element; The thickness is set to be thicker than the thickness in the vertical direction of the wiring pattern, and a part of the wiring pattern is directed from the side facing the long side of the frame of the electrode pad toward the long side of the frame A length of the wiring pattern which is provided to be extended and exposed and is exposed is shorter than one side facing the long side direction of the electrode pad, and a part of the exposed wiring pattern is the center of the substrate For a straight line passing a point and parallel to the long side of the substrate , And has a line of symmetry.

A quartz crystal device according to one aspect of the present invention comprises a rectangular substrate, a frame provided along the outer peripheral edge of the upper surface of the substrate, a substantially rectangular electrode pad provided on the upper surface of the substrate, and an electrode pad And a wiring element provided on the upper surface of the substrate, a quartz crystal element mounted on the electrode pad, and a lid for hermetically sealing the quartz crystal element; The thickness is set to be thicker than the thickness in the vertical direction of the wiring pattern, and a part of the wiring pattern is directed from the side facing the long side of the frame of the electrode pad toward the long side of the frame A length of the wiring pattern which is provided to be extended and exposed and is exposed is shorter than one side facing the long side direction of the electrode pad, and a part of the exposed wiring pattern is the center of the substrate For a straight line passing a point and parallel to the long side of the substrate , And has a line of symmetry. By doing this, since the conductive adhesive does not easily leak and spread on the upper surface of the wiring pattern, it is possible to stably mount the quartz crystal element on the electrode pad through the conductive adhesive. Become. Further, since the quartz crystal device can stably mount the quartz crystal element on the electrode pad, it becomes possible to stably output the oscillation frequency of the quartz crystal element.

It is a disassembled perspective view which shows the quartz crystal device in this embodiment. (A) A sectional view in the A-A of the quartz crystal device shown in FIG. 1, (b) A sectional view in the B-B of the quartz crystal device shown in FIG. 1, (c) FIG. 2 (b) X is a partially enlarged view of FIG. It is a top view which shows the state which removed the cover body of the crystal device in this embodiment. (A) It is the top view which looked at the package which comprises the quartz crystal device in this embodiment from the top, (b) It is the top view which looked at the package which comprises the quartz crystal device in this embodiment from the bottom. (A) It is the top view which looked at the package which comprises the quartz crystal device in the 1st modification of this embodiment from the top, (b) seeing from the bottom the package which comprises the quartz crystal device in the 1st modification of this embodiment It is a plan view.

  The crystal device according to the present embodiment includes a package 110, a crystal element 120 bonded to the upper surface of the package 110, and a lid 130 bonded to the upper surface of the package 110, as shown in FIGS. Contains. In the package 110, a recess K surrounded by the upper surface of the substrate 110a and the inner side surface of the frame 110b is formed. Such a quartz crystal device is used to output a reference signal used in an electronic device or the like.

  The substrate 110a has a rectangular shape and functions as a mounting member for mounting the crystal element 120 mounted on the upper surface. A pair of electrode pads 111 for bonding the quartz crystal element 120 is provided on the upper surface of the substrate 110 a. The substrate 110a is made of an insulating layer which is a ceramic material such as alumina ceramics or glass-ceramics. The substrate 110a may be formed by using a single insulating layer or by stacking a plurality of insulating layers. A wiring pattern 113 and a conductor portion 114 for electrically connecting the electrode pad 111 provided on the upper surface and the external terminal 112 provided on the lower surface of the substrate 110a are provided on the surface and the inside of the substrate 110a. There is.

  The frame 110 b is disposed on the upper surface of the substrate 110 a and is for forming the recess K on the upper surface of the substrate 110 a. The frame 110 b is made of, for example, a ceramic material such as alumina ceramic or glass-ceramics, and is integrally formed with the substrate 110 a.

  Here, when the dimension of one side when the package 110 is viewed in plan is 1.0 to 3.0 mm and the dimension of the package 110 in the vertical direction is 0.2 to 1.5 mm as an example, the recess is Explain the size of K. The length of the long side of the recess K is 0.7 to 2.0. The length of the short side is 0.5 to 1.5 mm. Moreover, the length of the up-down direction of the recessed part K is 0.1-0.5 mm.

  In addition, external terminals 112 are provided at the four corners of the lower surface of the substrate 110a. Two of the external terminals 112 are electrically connected to the electrode pads 111 provided on the top surface of the substrate 110a. Further, external terminals 112 electrically connected to the electrode pads 111 are provided so as to be located diagonally on the lower surface of the substrate 110a.

  The electrode pad 111 is for mounting the crystal element 120. The electrode pads 111 are provided in a pair on the upper surface of the substrate 110a, and are provided adjacent to each other along one side of the substrate 110a. The electrode pad 111 is configured of a first electrode pad 111a and a second electrode pad 111b. The electrode pad 111 is electrically connected to the external terminal 112 provided on the lower surface of the substrate 110 a via the wiring pattern 113 provided on the substrate 110 a, the conductor portion 114 and the via conductor 115.

  The external terminals 112 are used to bond to mounting pads (not shown) on an external mounting substrate of an electric device or the like. The external terminals 112 are provided at the four corners of the lower surface of the substrate 110a. At least one of the external terminals 112 is electrically connected to the sealing conductor pattern 117 via the via conductor 115. In addition, at least one of the external terminals 112 is connected to a mounting pad connected to a ground potential which is a reference potential on a mounting substrate of an electronic device or the like. Thus, the lid 130 joined to the sealing conductor pattern 117 is connected to the third external terminal 112 c which is at the ground potential. Thus, the shieldability in the recess K by the lid 130 is improved.

  The wiring pattern 113 is for electrically connecting the electrode pad 111 to the conductor portion 114 and the via conductor 115. One end of the wiring pattern 113 is electrically connected to the electrode pad 111, and the other end of the wiring pattern 113 is electrically connected to the conductor portion 114 and the via conductor 115. The wiring pattern 113 is composed of a first wiring pattern 113a, a second wiring pattern 113b, and a third wiring pattern 113c.

  The wiring pattern 113 is provided so as to overlap with the frame 110b in plan view. By doing this, since the crystal device suppresses generation of stray capacitance between the wiring pattern 113 and the quartz crystal element 120, this stray capacitance is not applied to the quartz crystal element 120. Can be suppressed. Also, even if an external force is applied to the quartz crystal device and a bending moment is generated in the direction of the long side of the frame 110b, the frame 110b is provided by being provided in addition to the substrate 110a. Is less likely to deform. Therefore, the wiring pattern 113 provided at a position overlapping with the frame 110b in plan view is unlikely to be disconnected, and it can be suppressed that the oscillation frequency is not output.

  The first wiring pattern 113a is electrically connected to the first electrode pad 111a, the first conductor portion 114a, and the first via conductor 115a. The first wiring pattern 113a is extended in the direction of the long side of the frame 110b close to the first electrode pad 111a, and a part of the first wiring pattern 113a is exposed. The second wiring pattern 113b is electrically connected to the second electrode pad 111b, the second conductor portion 114b, and the second via conductor 115b. The second wiring pattern 113b is extended in the direction of the long side of the frame 110b which is close to the second electrode pad 111b, and a part of the second wiring pattern 113b is exposed.

  As described above, the quartz crystal element 120 is mounted by providing a part of the wiring pattern 113 extending from the electrode pad 111 in the long side direction of the frame 110 b and exposing the concave part K. In this case, even if the conductive adhesive 140 overflows from above the electrode pad 111, the conductive adhesive 140 flows out along the wiring pattern 113 with good wettability with the conductive adhesive 140, so it flows out toward the center of the package 110. Therefore, the conductive adhesive 140 can be prevented from adhering to the excitation electrode 122.

  Further, a part of the exposed wiring pattern 113 is provided so as to be line symmetrical with respect to a straight line L which passes through the center point P of the substrate 110a and is parallel to the long side of the substrate 110a. The positions where the first wiring pattern 113a thus exposed and the exposed second wiring pattern 113b are line symmetrical with respect to a straight line L passing through the center point P of the substrate 110a and parallel to the long side of the substrate 110a. Even when the conductive adhesive 140 overflows from above the electrode pad 111 when the quartz crystal element 120 is mounted, the amount of the conductive adhesive 140 which overflows is likely to be even. Tilting of the crystal element 120 can be suppressed.

  Further, as shown in FIG. 2C, the thickness of the electrode pad 111 in the vertical direction is larger than the thickness of the wiring pattern 113 in the vertical direction. By this, a step is provided at the boundary between the electrode pad 111 and the wiring pattern 113, the curvature radius of the interface of the conductive adhesive 140 at the step becomes smaller, and the interface free energy becomes larger. The conductive adhesive 140 applied on the upper surface of the wiring pattern 113 is less likely to leak over the wiring pattern 113 over the level difference. Therefore, the crystal element 120 can be stably mounted on the electrode pad 111 through the conductive adhesive 140, so that fluctuation of the oscillation frequency of the crystal element 120 can be reduced.

  The conductor portion 114 is for electrically connecting the wiring pattern 113 and the external terminal 112. The conductor portion 114 is provided inside the notch provided at the corner of the substrate 110a. Both ends of the conductor portion 114 are connected to the wiring pattern 113 and the external terminal 112. By doing this, the electrode pad 111 is electrically connected to the external terminal 112 through the wiring pattern 113, the conductor portion 114 and the via conductor 115.

  The via conductor 115 is for electrically connecting the external terminal 112 and the wiring pattern 113 or the sealing conductor pattern 117. Both ends of the via conductor 115 are connected to the external terminal 112 and the wiring pattern 113 or the sealing conductor pattern 117. By doing this, the external terminal 112 is electrically connected to the wiring pattern 113 or the sealing conductor pattern 117 via the via conductor 115.

  The protrusion 116 has a rectangular shape in plan view and is provided at a position opposite to the free end of the quartz crystal element 120, and prevents the free end of the quartz crystal element 120 from contacting the substrate 110a. It is. The protrusion 116 is provided on the substrate 110 a in the recess K such that the long side of the protrusion 116 and the long side of the substrate 110 a are substantially parallel. In this way, it is possible to suppress chipping or the like due to the free end side of the crystal element 120 coming into contact with the substrate 110 a when an impact such as a drop is applied to the crystal device.

  Here, the dimension of one side when the package 110 is viewed in plan is 1.0 to 3.0 mm, and the dimension of the package 110 in the vertical direction is 0.7 to 1.5 mm as an example. The sizes of the pad 111 and the protrusion 116 will be described. The side length of the electrode pad 111 is 250 to 400 μm. The length of the thickness in the vertical direction of the electrode pad 111 is 10 to 50 μm. The length of the protrusion 116 parallel to the long side direction of the substrate 110 a is 500 to 800 μm, and the length of the protrusion 116 parallel to the short side direction of the substrate 110 a is 150 to 300 μm. Moreover, the length in the vertical direction of the protrusion 116 is about 30 to 100 μm. Further, the length of the thickness in the vertical direction of the wiring pattern 113 is 5 to 25 μm.

  The arithmetic mean surface roughness of the electrode pad 111 is 0.02 to 0.10 μm, and the arithmetic mean surface roughness of the surface of the substrate 110 a is 0.5 to 1.5 μm. Thus, the conductive adhesive 140 is less likely to spread from the electrode pad 111 toward the substrate 110a.

  The sealing conductor pattern 117 plays a role of improving the wettability of the sealing member 131 when the sealing conductor pattern 117 is joined to the lid 130 via the sealing member 131. The sealing conductor pattern 117 is formed to have a thickness of, for example, 10 to 25 μm by applying nickel plating and gold plating sequentially on the surface of a conductor pattern made of, for example, tungsten or molybdenum in the form of annularly surrounding the upper surface of the frame 110b. It is done.

  The conductive adhesive 140 contains a conductive powder as a conductive filler in a binder such as silicone resin, and as the conductive powder, aluminum, molybdenum, tungsten, platinum, palladium, silver, titanium, Those containing either nickel or nickel-iron or combinations thereof are used. Moreover, as a binder, a silicone resin, an epoxy resin, a polyimide resin, or bis maleimide resin is used, for example.

  The conductive adhesive 140 is disposed between the excitation electrode 122 of the quartz crystal element 120 and the conductive adhesive 140. In the quartz crystal device, the conductive adhesive 140 and the excitation electrode 122 are spaced apart, so that the short circuit caused by the conductive adhesive 140 adhering to the excitation electrode 122 can be reduced. .

  In addition, when the conductive adhesive 140 is applied by using the adhesive having a viscosity of 35 to 45 Pa · s, the conductive adhesive 140 does not flow out onto the upper surface of the substrate 110 a from above the electrode pad 111. Since it remains on the pad 111, the thickness in the vertical direction of the conductive adhesive 140 can also be secured. The length of the thickness in the vertical direction of the conductive adhesive 140 is 10 to 25 μm. By thus securing the thickness of the conductive adhesive 140, the contact of the quartz crystal element 120 to the substrate 110a is suppressed, and the impact applied by the drop or the like is centered on the conductive adhesive 140 with respect to the quartz crystal element 120. Even when applied in the vertical direction, the conductive adhesive 140 can sufficiently absorb and reduce the impact.

  Here, a method of manufacturing the package 110 will be described. When the substrate 110a and the frame 110b are made of alumina ceramic, first, a plurality of ceramic green sheets obtained by adding and mixing an appropriate organic solvent or the like to a predetermined ceramic material powder are prepared. Further, a predetermined conductive paste is applied by screen printing or the like known in the prior art in the surface of the ceramic green sheet or in the through holes which are punched in advance by punching or the like. Furthermore, these green sheets are stacked and press-formed, and fired at a high temperature. Finally, nickel plating or gold plating or the like is performed on a predetermined portion of the conductor pattern, specifically, a portion to be the pair of electrode pads 111 or the external terminal 112 and the protrusion 116. The conductor paste is made of, for example, a sintered body of metal powder such as tungsten, molybdenum, copper, silver or silver palladium.

  The quartz crystal element 120 is bonded onto the electrode pad 111 via the conductive adhesive 140, as shown in FIG. 2 and FIG. 3 (a). The quartz crystal element 120 plays a role of oscillating a reference signal of an electronic device or the like by the stable mechanical vibration and the piezoelectric effect.

  In the quartz crystal element 120, as shown in FIG. 2, as shown in FIGS. 1 and 2, the excitation electrode 122 and the lead-out electrode 123 are attached to the upper surface and the lower surface of the quartz substrate 121 respectively. It has a structure that The excitation electrode 122 is formed by depositing and forming a metal on each of the upper surface and the lower surface of the quartz crystal substrate 121 in a predetermined pattern. The excitation electrode 122 includes a first excitation electrode 122 a on the upper surface and a second excitation electrode 122 b on the lower surface. The lead-out electrodes 123 extend from the excitation electrode 122 toward one side of the quartz substrate 121. The extraction electrode 123 includes a first extraction electrode 123a on the upper surface and a second extraction electrode 123b on the lower surface. The first lead-out electrode 123 a is drawn out from the first excitation electrode 122 a and provided so as to extend toward one side of the quartz crystal base plate 121. The second lead-out electrode 123 b is drawn out from the second excitation electrode 122 b and provided so as to extend toward one side of the quartz crystal base plate 121. That is, the extraction electrode 123 is provided in a shape along the long side or the short side of the quartz substrate 121. Further, in the present embodiment, one end of the crystal element 120 connected to the first electrode pad 111a and the second electrode pad 111b is a fixed end connected to the upper surface of the substrate 110a, and the other end is between the upper surface of the substrate 110a The quartz crystal element 120 is fixed on the substrate 110 a by a cantilevered support structure with free ends.

  In addition, the crystal device adjusts the oscillation frequency of the crystal element 120 by scraping the surface of the excitation electrode 122 of the crystal element 120 with, for example, an ion gun. Further, in the conventional quartz crystal device, since the wiring pattern provided on the upper surface of the substrate is exposed also in the vicinity of the excitation electrode of the quartz crystal element, the wiring pattern is scraped off when the excitation electrode is scraped by the ion gun. There is. Further, in the conventional quartz crystal device, the shavings of the wiring pattern may be attached to the excitation electrode of the quartz crystal element, and the oscillation frequency may be fluctuated. However, in the crystal device according to the present embodiment, as shown in FIG. 4, the wiring pattern 113 is not exposed in the recess K in the vicinity of the excitation electrode 122 of the crystal element 120, and viewed in plan Since they are provided at overlapping positions, it is possible to prevent the wiring pattern 113 from being scraped off when the excitation electrode 122 is scraped by the ion gun. In addition, since such a crystal device does not generate shavings of the wiring pattern 113, it is possible to stably output the oscillation frequency without attaching shavings to the excitation electrode 122 of the crystal element 120. Become.

  Here, the operation of the crystal element 120 will be described. In the quartz crystal element 120, when an alternating voltage from the outside is applied from the extraction electrode 123 to the quartz crystal base plate 121 via the excitation electrode 122, the quartz crystal base plate 121 is excited in a predetermined vibration mode and frequency. ing.

  Here, a method of manufacturing the crystal element 120 will be described. First, the quartz crystal element 120 is cut at a predetermined cut angle from the artificial crystalline lens to reduce the thickness of the outer periphery of the quartz crystal base plate 121, and the central portion of the quartz crystal base plate 121 becomes thicker than the outer periphery of the quartz crystal base plate 121. Perform bevel processing to be provided. The quartz crystal element 120 is manufactured by forming the excitation electrode 122 and the lead-out electrode 123 by depositing a metal film on both principal surfaces of the quartz crystal base plate 121 by photolithography, vapor deposition technology or sputtering technology. Be done.

  In addition, a manufacturing method for forming such a quartz crystal element 120 using photolithography technology and etching technology will be described. First, a quartz wafer having crystal axes consisting of X, Y, and Z axes orthogonal to one another is prepared. At this time, a plane in which the main surface of the quartz wafer is parallel to the X axis and the Z axis is counterclockwise rotated about the X axis as viewed in the negative direction of the X axis, for example, It is parallel to the plane rotated about 37 °. Next, a metal film is formed on both main surfaces of the quartz wafer using sputtering technology or evaporation technology, a photosensitive resist is coated on this metal film, exposed and developed in a predetermined pattern, and only a predetermined part is quartz Make the wafer exposed. Thus, the quartz wafer exposed only at the predetermined part is immersed in a predetermined etching solution to etch the quartz wafer. As a result, the plurality of quartz crystal elements 120 are formed in the quartz crystal wafer in a state of being partially connected.

  A method of bonding the crystal element 120 to the substrate 110 a will be described. First, the conductive adhesive 140 is applied by spreading, for example, on the electrode pad 111 by a dispenser. The quartz crystal element 120 is transported onto the conductive adhesive 140. Furthermore, the quartz crystal element 120 is placed on the conductive adhesive 140 so that the lead electrode 123 on the outer peripheral edge on the fixed end side of the quartz crystal element 120 overlaps with the vicinity of the center of the conductive adhesive 140 in plan view. Be placed. The conductive adhesive 140 is cured and shrunk by heat curing.

  The lid 130 has a rectangular shape, and serves to hermetically seal the recess K in a vacuum state or the recess K filled with nitrogen gas or the like. Specifically, the lid 130 is placed on the top surface of the bonding member 131 provided on the frame 110 b in a predetermined atmosphere. The heat is applied to the bonding member 131 provided on the upper surface of the frame 110b, whereby fusion bonding is performed. Also, the lid 130 is made of, for example, an alloy containing at least one of iron, nickel or cobalt.

  The bonding member 131 is provided at a position of the lid 130 opposite to the sealing conductor pattern 117 provided on the top surface of the frame 110 b of the package 110. The sealing member 131 is provided by, for example, silver solder or gold-tin. In the case of silver wax, the thickness is 10 to 20 μm. For example, the component ratio of silver of 72 to 85% and copper of 15 to 28% is used. In the case of gold-tin, its thickness is 10 to 40 μm. For example, a component ratio of 78 to 82% of gold and 18 to 22% of tin is used.

  The bonding member 131 is, for example, in the case of gold-tin, the thickness of the layer of the bonding member 131 is 10 to 40 μm, for example, 70 to 80% of gold and 20 to 30% of tin. You may use In the case of silver solder, for example, the thickness of the layer of the bonding member 131 is 10 to 40 μm. For example, the component ratio is 70 to 80% of silver and 20 to 30% of copper. You may use the one of

  The quartz crystal device according to the present embodiment includes a rectangular substrate 110a, a frame 110b provided along the outer peripheral edge of the upper surface of the substrate 110a, an electrode pad 111 provided on the upper surface of the substrate 110a, and an electrode pad 111. An electrode comprising: a wiring pattern 113 electrically connected and provided on the upper surface of the substrate 110a; a quartz crystal element 120 mounted on the electrode pad 111; and a lid 130 for hermetically sealing the quartz crystal element 120; The thickness of the pad 111 in the vertical direction is larger than the thickness of the wiring pattern 113 in the vertical direction. By this, a step is provided at the boundary between the electrode pad 111 and the wiring pattern 113, the curvature radius of the interface of the conductive adhesive 140 at the step becomes smaller, and the interface free energy becomes larger. The conductive adhesive 140 applied on the upper surface of the wiring pattern 113 is less likely to leak over the wiring pattern 113 over the level difference. Therefore, such a quartz crystal device can stably mount the quartz crystal element 120 on the electrode pad 111 via the conductive adhesive 140, so that fluctuation of the oscillation frequency of the quartz crystal element 120 can be reduced. Can.

  In the quartz crystal device in the present embodiment, the wiring pattern 113 is provided at a position overlapping with the frame 110 b in plan view. By doing this, the quartz crystal device can suppress the generation of stray capacitance between the wiring pattern 113 and the quartz crystal element 120. In addition, since such a crystal device does not have the floating capacitance applied to the crystal element 120, fluctuation of the oscillation frequency can be reduced. In the quartz crystal device according to the present embodiment, the frame 110b is provided in addition to the substrate 110a even if an external force is applied to the quartz crystal device and a bending moment is generated in the long side direction of the frame 110b. The portion where the body 110 b is provided is less likely to be deformed. Therefore, the wiring pattern 113 provided at a position overlapping with the frame 110b in plan view is unlikely to be disconnected, and it can be suppressed that the oscillation frequency of the crystal device is not output.

  Further, in the quartz crystal device in the present embodiment, a part of the wiring pattern 113 is provided so as to extend from the electrode pad 111 in the long side direction of the frame 110 b and to be exposed. As described above, a part of the wiring pattern 113 extends from the electrode pad 111 in the long side direction of the frame 110 b and is provided so as to be exposed in the recess K, thereby mounting the crystal element 120. At the same time, even if the conductive adhesive 140 overflows the electrode pad 111, the conductive adhesive 140 flows along the wiring pattern 113 having good wettability with the conductive adhesive 140. It is possible to prevent the conductive adhesive 140 from adhering to the excitation electrode 122 without flowing out.

  Further, in the crystal device in the present embodiment, a part of the wiring pattern 113 is line symmetrical with respect to a straight line L passing through the center point P of the substrate 110 a and parallel to the long side of the substrate 110 a. The positions where the first wiring pattern 113a thus exposed and the exposed second wiring pattern 113b are line symmetrical with respect to a straight line L passing through the center point P of the substrate 110a and parallel to the long side of the substrate 110a. Even when the conductive adhesive 140 overflows from above the electrode pad 111 when the quartz crystal element 120 is mounted, the amount of the conductive adhesive 140 which overflows is likely to be even. Tilting of the crystal element 120 can be suppressed.

  In addition, the crystal device in the present embodiment is provided with the protruding portion 117 provided along the side facing the one side of the substrate 110a. By doing this, when an impact such as a drop is applied to the quartz crystal device, the free end side of the quartz crystal element 120 contacts the projection 116, so that chipping due to direct contact with the substrate 110a can be suppressed. .

(First modification)
The quartz crystal device according to the first modification of the present embodiment differs from the quartz crystal device according to the present embodiment in that a convex portion 118 is provided on the electrode pad 111 as shown in FIG. On the pair of electrode pads 111, as shown in FIG. 5, a pair of convex portions 118 which are rectangular in plan view are provided. Further, the pair of convex portions 118 is provided along the outer peripheral edge of the electrode pad 111 whose one side faces the center side of the substrate 110 a in plan view, and the other side connected to the one side Are provided along the outer peripheral edge on the electrode pad 111 facing the outer peripheral edge side of the substrate 110a.

  The convex portion 118 is intended to suppress inclination of the short side of the quartz crystal element 120 in the vertical direction, and to prevent the long side end of the quartz crystal element 120 from coming into contact with the substrate 110 a or the lid 130. The convex portion 118 is for suppressing the free end of the quartz crystal element 120 from coming into contact with the substrate 110 a. The pair of convex portions 118 is configured by the first convex portion 118 a and the second convex portion 118 b. The first convex portion 118a is provided on the upper surface of the first electrode pad 111a, and the second convex portion 118b is provided on the upper surface of the second electrode pad 111b. Similarly to the electrode pad 111, the convex portion 118 is provided by performing gold plating or nickel plating on the upper surface of a sintered body of metal powder such as tungsten, molybdenum, copper, silver or silver palladium.

  Further, as shown in FIG. 5A, one side of the pair of convex portions 118 facing the center side of the substrate 110a is provided to be aligned on the same straight line. In this way, when the lead-out electrode 123 of the crystal element 120 is mounted on the electrode pad 111 while being in contact with the pair of convex portions 118, the crystal element 120 can be mounted in a stable state without tilting. Further, the length in the long side direction of the side of the convex portion 118 formed along the outer peripheral edge of the electrode pad 111 is 150 to 200 μm, and the length of the side in the short side direction of the convex portion 118 is 50 to 50 μm. It is 75 μm. The length of the thickness in the vertical direction of the convex portion 118 is 20 to 75 μm. The length in the long side direction of the convex portion 118 is 150 to 300 μm, and the length of the side in the short side direction of the convex portion 118 is 50 to 75 μm. The length of the thickness in the vertical direction of the convex portion 118 is 20 to 75 μm.

  In addition, the convex portion 118 is provided at a position facing the extraction electrode 123 on the outer peripheral edge of the crystal element 120. By doing this, when the crystal element 120 is mounted on the electrode pad 111 via the conductive adhesive, even if the crystal element 120 is inclined, the lead-out electrode 123 will be in contact with the convex portion 118. The crystal element 120 can be mounted in a stable state without being inclined in the lower direction than the convex portion 118. Further, the convex portion 118 is provided at a position overlapping with the lead-out electrode 123 on the outer peripheral edge on the fixed end side of the quartz crystal base plate 121 in plan view. By doing so, the contact of the fixed end of the quartz crystal element 120 with the upper surface of the substrate 110a can be reduced.

  In addition, when the conductive adhesive 140 cures and shrinks, the fixed end side of the quartz crystal element 120 is pulled downward, and the principle of the insulator with the convex portion 118 as a fulcrum works. It is joined to a pair of electrode pads 111 so that the free end side of 120 may float upward. In addition, when the fixed end side of the quartz crystal element 120 is pulled downward when the conductive adhesive 140 cures and shrinks, the electrode pad 111 is brought into contact with the convex portion 118 and the lead electrode 123 at the outer peripheral edge of the quartz crystal element 120. Bonded to

  The first lead electrode 123a of the crystal element 120 is in contact with the first convex portion 118a, and the second lead electrode 123b of the crystal element 120 is in contact with the second convex portion 118b, as shown in FIG. There is. By bringing the lead-out electrode 123 of the crystal element 120 into contact with the convex portion 118 in this manner, even in the process of mounting the crystal element 120 on the electrode pad 111, the mounting position of the crystal element 120 is shifted and the mounting angle is inclined. The long-side end of the quartz crystal element 120 is supported in contact with the convex portion 118, the inclination of the short side of the quartz-crystal element 120 is suppressed, and the long-side end of the quartz crystal element 120 corresponds to the substrate 110a or the lid 130. It can prevent contact. Therefore, the fluctuation of the oscillation frequency of the crystal element 120 can be prevented, and the productivity can be improved.

  In addition, since the lead-out electrode 123 of the crystal element 120 comes in contact with the convex portion 118, the contact of the outer peripheral edge on the fixed end side of the crystal element 120 with the upper surface of the substrate 110a can be reduced. Accordingly, the outer peripheral edge on the fixed end side of the crystal element 120 can prevent the chip of the crystal element 120 caused by the contact with the substrate 110 a. Further, even if the crystal element 120 is inclined at the time of mounting, the lead-out electrode 123 of the crystal element 120 contacts the convex portion 118 so that the fixed end side of the crystal element 120 has a distance corresponding to the thickness of the convex portion 118 Since the free end of the quartz crystal element 120 is not excessively floated, the free end of the quartz crystal element 120 can be prevented from contacting the lid 130.

  Further, in the quartz crystal device in the present embodiment, the electrode pad 111 is provided along one side of the substrate 110 a, and includes the convex portion 118 provided on the upper surface of the electrode pad 111. When the crystal element 120 is mounted on the electrode pad 111 via the conductive adhesive 140, even if the crystal element 120 is inclined, the lead-out electrode 123 will be in contact with the convex portion 118 and the convex portion 118 The crystal element 120 can be mounted in a stable state without being inclined downward. Further, the convex portion 118 is provided at a position overlapping with the lead-out electrode 123 on the outer peripheral edge on the fixed end side of the quartz crystal base plate 121 in plan view. By doing so, the contact of the fixed end of the quartz crystal element 120 with the upper surface of the substrate 110a can be reduced.

  The present invention is not limited to the present embodiment, and various changes, improvements, and the like can be made without departing from the scope of the present invention. In the above embodiment, the case where the frame 110b is provided on the upper surface of the substrate 110a has been described, but after mounting the crystal element on the substrate, the lid having the sealing frame portion provided on the lower surface of the sealing base is used. The structure may be such that the crystal element is hermetically sealed by using it. The lid includes a rectangular sealing base and a sealing frame provided along the outer periphery of the lower surface of the sealing base, and the lower surface of the sealing base and the inner side of the sealing frame A housing space is formed by the side surface. The sealing frame portion is for forming an accommodation space on the lower surface of the sealing base. The sealing frame is provided along the outer edge of the lower surface of the sealing base.

  Although the case where the frame 110b is provided on the upper surface of the substrate 110a has been described in the above embodiment, after the quartz crystal element is mounted on the substrate, the crystal device is mounted using a lid having a wall provided on the lower surface. It may be a hermetically sealed structure.

  In the above embodiment, the quartz crystal element has been described for the case where the quartz crystal element for AT is used, but a tuning fork type curved quartz crystal having a base and two flat vibrating arms extending in the same direction from the side surface of the base An element may be used. The quartz crystal element is constituted of a quartz crystal piece, an excitation electrode provided on the surface of the quartz crystal piece, an extraction electrode, and a metal film for frequency adjustment. The quartz crystal piece comprises a quartz crystal base and a quartz crystal vibrating portion, and the quartz crystal vibrating portion comprises a first quartz crystal vibrating portion and a second quartz crystal vibrating portion. The quartz crystal base is an orthogonal coordinate system in which the electrical axis is X axis, the mechanical axis is Y axis, and the optical axis is Z axis as the crystal axis direction, within the range of -5 ° to + 5 ° around the X axis It is a flat plate having a substantially rectangular shape in plan view, in which the direction of the rotated Z 'axis is the thickness direction. The first quartz-crystal vibrating portion and the second quartz-crystal vibrating portion extend from one side of the quartz crystal base in parallel to the direction of the Y ′ axis. Such a quartz crystal piece has a crystal base and crystal vibrating portions integrally formed in a tuning fork shape, and is manufactured by photolithography technology and chemical etching technology.

DESCRIPTION OF SYMBOLS 110 ... Package 110a ... Substrate 110b ... Frame 111 ... Electrode pad 112 ... External terminal 113 ... Wiring pattern 114 ... Conductor part 115 ... Via conductor 116 ... Convex part 117: Protrusive part 118: Conducting pattern for sealing 120: Crystal element 121: Crystal base plate 122: Excitation electrode 123: Extraction electrode 130: Lid 131 ... Bonding member 140 ... conductive adhesive K ... recess

Claims (4)

A rectangular substrate,
A frame provided along the outer peripheral edge of the upper surface of the substrate;
A substantially rectangular electrode pad provided on the upper surface of the substrate;
A wiring pattern electrically connected to the electrode pad and provided on the upper surface of the substrate;
A crystal element mounted on the electrode pad;
And a lid for hermetically sealing the crystal element,
The thickness of the electrode pad in the vertical direction is larger than the thickness of the wiring pattern in the vertical direction , and
A part of the wiring pattern is provided so as to extend from one side of the electrode pad facing the long side of the frame toward the long side of the frame and to be exposed.
The length of the exposed wiring pattern in the long side direction is shorter than the side facing the long side direction of the electrode pad,
The crystal device in which a part of the exposed wiring pattern is line symmetrical with respect to a straight line passing through the center point of the substrate and parallel to the long side of the substrate . The crystal device according to claim 1, wherein
A quartz crystal device characterized in that the wiring pattern is provided so as to overlap with the frame in a plan view. The crystal device according to claim 1 or 2 , wherein
The electrode pad is provided along one side of the substrate,
A crystal device comprising a convex portion provided on the upper surface of the electrode pad. The crystal device according to any one of claims 1 to 3 , wherein
A quartz crystal device comprising a protrusion provided along a side facing one side of the substrate.

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