Source: http://www.google.com/patents/US7528509?ie=ISO-8859-1
Timestamp: 2014-03-08 12:13:46
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Patent US7528509 - Multifunction-type vibration actuator and mobile terminal device - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign inAdvanced Patent SearchPatentsTo accurately tune the vibration frequency of a suspension during assembly. Secured positions 3 e where a magnetic circuit part 2 is secured to a suspension 3 are provided near to each other. From among the secured positions 3 e, secured positions 3 e suitable for the characteristics of a suspension...http://www.google.com/patents/US7528509?utm_source=gb-gplus-sharePatent US7528509 - Multifunction-type vibration actuator and mobile terminal deviceAdvanced Patent SearchPublication numberUS7528509 B2Publication typeGrantApplication numberUS 10/592,958Publication dateMay 5, 2009Filing dateMar 18, 2005Priority dateMar 22, 2004Fee statusPaidAlso published asCN1934901A, CN1934901B, DE602005021213D1, EP1742504A1, EP1742504A4, EP1742504B1, US20070194633, WO2005091674A1Publication number10592958, 592958, US 7528509 B2, US 7528509B2, US-B2-7528509, US7528509 B2, US7528509B2InventorsMinoru Ueda, Satoshi Takeuchi, Etuo OonoOriginal AssigneeNamiki Seimitsu Houseki Kabushiki KaishaExport CitationBiBTeX, EndNote, RefManPatent Citations (15), Non-Patent Citations (1), Referenced by (3), Classifications (18), Legal Events (2) External Links: USPTO, USPTO Assignment, EspacenetMultifunction-type vibration actuator and mobile terminal deviceUS 7528509 B2Abstract To accurately tune the vibration frequency of a suspension during assembly.
Secured positions 3 e where a magnetic circuit part 2 is secured to a suspension 3 are provided near to each other. From among the secured positions 3 e, secured positions 3 e suitable for the characteristics of a suspension 3 to be mounted and the weight of a magnetic circuit part 2 are selected and secured to each other. Thus, the distance between the securing position and the central position of vibration of a suspension 3 and a housing 1 can be changed to tune the frequency to the desired value.
1. A multifunction-type vibration actuator, having a housing accommodating a magnetic circuit part, a suspension elastically supporting said magnetic circuit part in said housing, a diaphragm facing said magnetic circuit part, and a voice coil provided to said diaphragm and inserted into a magnetic gap of said magnetic circuit part, an input of a signal with a vibration frequency to said voice coil to allow vibration of said suspension secured to said magnetic circuit part to be transmitted outward through said housing, the suspension comprising:
an outer circumferential portion,
a plurality of deflectable arms, each of the plurality of deflectable arms has a first end connected to the outer circumferential portion, and a second end,
an annular portion connected to the second end of each of the plurality of deflectable arms, the annular portion is nested within the outer circumferential portion and is connected with the outer circumferential portion via the plurality of deflectable arms.
and a plurality of secured positions disposed on the annular portion in the vicinity of the second end of each of the plurality of deflectable arms, the plurality of secured positions are configured to be bonded to said magnetic circuit part, wherein a central vibration position of said suspension and said housing is selectable by selecting one of the plurality of securing planned position and bonding the suspension to the magnetic circuit at the selected secured planned position according to a characteristic of said suspension and according to a weight of said magnetic circuit part.
3. A mobile terminal device incorporating a multifunction-type vibration actuator according to claim 1 or 2, wherein a call-out signal initiates vibration of said diaphragm and one or both mechanical vibration systems including a magnetic circuit part and a suspension in order to transmit vibration of said mechanical vibration systems throughout a device through a housing and reset of said call-out signal stops vibration of said diaphragm and said mechanical vibration systems. Description
TECHNICAL FIELD This invention relates to a multifunction-type vibration actuator mounted on a mobile terminal device, such as a mobile phone and a small information communication terminal, and alerts a user to an incoming call with sound or vibration by one device and a mobile terminal device mounted with that actuator. More specifically, this invention relates to a multifunction-type vibration actuator of which a housing accommodates a magnetic circuit part, a suspension for elastically supporting the magnetic circuit part in the housing, a diaphragm arranged facing the magnetic circuit part, and a voice coil provided to the diaphragm and inserted into a magnetic gap of the magnetic circuit part, wherein an input of a signal with a vibration frequency to the voice coil allows vibration of the suspension securing the magnetic circuit part to be transmitted outward through the housing.
BACKGROUND ART Conventionally, this type of multifunction-type vibration actuator has a yoke (magnetic yoke) where a magnetic circuit part is fitted and secured in a central opening of a suspension, and a plurality of equally spaced tongues provided to an outer periphery of the suspension are fitted and bonded in stepped notches inside a frame of a housing (enclosure) in order to secure the outer periphery to the housing. (See, for example, Patent Reference 1). In this actuator, input of voice signal current to the voice coil initiates vibration of the diaphragm to generate a sound, such as an incoming call alert, melody, voice, or music, and input of a signal with a vibration frequency initiates vibration of mechanical vibration systems consisting of the magnetic circuit part and the suspension to transmit this vibration throughout a mobile terminal device mounted with this multifunction-type vibration actuator through the housing. Moreover, we find another multifunction-type vibration actuator in which a yoke (lower yoke) of a magnetic circuit part is fitted and secured in a central opening of a suspension (leaf spring) by laser welding and an outer periphery of the suspension is inserted and secured between a housing (case) and a spacer fitted inside the housing. (See, for example, Patent Reference 2.)
In the invention according to Claim 2 and the invention according to Claim 3, quoting Claim 2, laser welding is performed by changing the laser radiation positions toward the through-holes 3 e in order to enable rapid and accurate positioning while realizing simple tuning construction in addition to the effect of the invention according to Claim 1. Therefore, it is possible to perform rapid and accurate positioning while realizing a simple tuning construction. As a result, the manufacturing costs can be further reduced.
Now, an embodiment of the invention is described based on drawings. In a multifunction-type vibration actuator A according to the invention, a cylindrical housing 1 accommodates a magnetic circuit part 2, a suspension 3 for elastically supporting a magnetic circuit part 2 upward, a diaphragm 4 facing a magnetic circuit part 2, and a voice coil 5 bonded to a diaphragm 4 and inserted into an annular magnetic gap 2 a of a magnetic circuit part 2 as shown in FIGS. 1 through 5, and input of a voice signal to a voice coil 5 initiates low vibration of a diaphragm 4 to generate a sound, such as an incoming call alert, melody, voice, or music, and an input of signal current with a vibration frequency of 120-160 Hz initiates high vibration of heavy mechanical vibration systems consisting of a magnetic circuit part 2 and a suspension 3.
A housing 1 is a cylindrical enclosure for accommodating a magnetic circuit part 2, on an open end 1 a (the top in the drawing) of which an outer peripheral portion 4 a of a diaphragm 4 is bonded with adhesive, and another open end 1 b (the bottom in the drawing) is detachably provided with and covered by a bottom cover 6.
An outer circumferential portion 3 a of a suspension 3 bonded to a magnetic circuit part 2 and an elastically deformable annular member 7 are inserted between the other open end 1 b of a housing 1 and a cover 6 in order to press an outer circumferential portion 3 a of a suspension 3 onto the other open end 1 b of a housing 1.
This annular member 7 is an O-ring made of an elastic material, such as synthetic rubber, and arranged along an outer periphery at the bottom of a cover 6 facing an outer circumferential portion 3 a of a suspension 3 as shown in FIGS. 1, 3 and 5. Furthermore, it is preferable to select an optimum annular member 7 from those with different thicknesses and hardness numbers.
Fitting portions of a housing 1 and a cover 6 are provided with an engaging means 8 for securing the positioning. In this embodiment, a lower peripheral side wall 1 c is formed so as to be fitted in a side peripheral wall 6 a of a cylindrical cover 6 with a bottom and a plurality of engaging protrusions 8 a and engaging slits 8 b as the aforementioned engaging means 8 are provided to these fitting surfaces for each circumferentially and equally spaced location as shown in FIGS. 3 and 5.
Although an outer diameter of a lower peripheral side wall 1 c of a housing 1 is designed slightly smaller than an inner diameter of a side peripheral wall 6 a of a cover 6 to fit to each other, the engaging protrusions 8 a are provided to an outer surface of a lower peripheral side wall 1 c of a housing 1, and the engaging slits 8 b are penetratingly provided to an inner surface of a side peripheral wall 6 a of a cover 6 as shown in the drawing, the fitting construction and the shape of an engaging means 8 are not limited to those shown in the drawing, and other constructions and shapes, for example, arrangement of the engaging protrusions 8 a and the engaging slits 8 b opposite to that shown in the drawing, are acceptable if similar functions are available.
A suspension 3 is an annular leaf spring to the central section of which a central opening 3 b to be fitted to a magnetic circuit part 2 to be described later, an annular portion 3 c surrounding this central opening 3 b in contact with a magnetic circuit part 2, and a deflectable arm 3 d communicating the annular portion 3 c and an outer circumferential portion 3 a are provided, wherein the annular portion 3 c is integrally bonded to a magnetic circuit part 2 by laser welding, and an outer circumferential portion 3 a is secured to the other open end 1 b of a housing 1 to elastically support a magnetic circuit part 2 at the position facing a diaphragm 4.
More specifically, a plurality of through-holes 3 e for allowing a laser for laser welding to pass through are opened at each equally spaced location in a plurality of places of the annular portion 3 c as secured positions in advance as shown in FIGS. 4 and 5, the through-holes 3 e suitable for the characteristics of a suspension 3 to be mounted and the weight of a magnetic circuit part 2 are selected from these plurality of through-holes 3 e, and laser welding is performed while changing laser radiation positions toward them to change the distance between these laser welding positions and an outer circumferential portion 3 a of a suspension 3 secured to the other open end 1 b of a housing 1, namely the central position of vibration, in order to accurately tune the vibration frequency of a suspension 3 to the desired value.
A diaphragm 4 is a vibration plate formed as a circular plate with an appropriate thickness made from an elastic plastic film material, such as polycarbonate, polyetherimide, polyimide, and polyethylene terephthalate. An annular rising portion 4 b is formed by bending a portion close to the outer periphery along the inner peripheral surface of a housing 1, and an outer peripheral portion 4 a extending from this rising portion 4 b is formed in parallel with a flat surface of the other open end 1 a of a housing 1.
An annular mounting portion 4 c is formed in a diaphragm 4 almost in the middle between the center and the outer periphery of a diaphragm 4, an end surface of a voice coil 5 is bonded to the back face of the mounting portion 4 c with adhesive and inserted into an annular magnetic gap 2 a, and concentric curved surfaces 4 d and 4 e swelling outward are formed by bending at the center section and the outer periphery section separated by the coil mounting portion 4 c. A voice coil 5 is cylindrically wound of which lead wires 5 a are bonded on the back face of the aforementioned diaphragm 4 with adhesive to avoid the effect of vibration as shown in FIG. 2. The distal ends of these lead wires 5 a are pulled out toward a terminal block 1 d provided to the outside of a housing 1 and are electrically connected to a terminal plate 1 e provided to the terminal block 1 d by soldering or bonding.
A yoke 9, made of a magnetic material, is formed as a cylinder with a bottom. The outer peripheral surface 9 a thereof is formed to provide a small gap (for example, 0.05-0.2 mm) with the inner peripheral surface of a housing 1. A contact surface 9 b facing the annular overhang wall 1 f formed in the inner peripheral surface of a housing 1 is in contact with the overhang wall 1 f during vibration of a magnetic circuit part 2 to restrict movement of a magnetic circuit part 2 caused by an external shock force.
Furthermore in this embodiment, the bottom of a yoke 9 is provided with a raised surface 9 c fitting into the central opening 3 b of a suspension 3, and the annular portion 3 c of a suspension 3 is in contact with and integrally bonded to a support surface 9 d formed around the raised surface 9 c with adhesive. A counter bore (not illustrated) with a diameter slightly larger than a magnet 10 can be provided in order to position a magnet 10 at the center of the bottom if necessary.
Now, the assembly procedures of a multifunction-type vibration actuator A are sequentially described. First, a diaphragm 4 and a voice coil 5 are integrally installed to a housing 1, a suspension 3 is bonded to a yoke 9 of a magnetic circuit part 2 so as to be integral with the whole magnetic circuit part 2, an annular member 7 is inserted into a cylindrical cover 6 with a bottom, and a member 7 is placed along a side peripheral wall 6 a as shown in FIG. 3 When a yoke 9 of a magnetic circuit part 2 is bonded to an annular portion 3 c of a suspension 3 by laser welding, it is necessary that the characteristics of a suspension 3 to be mounted and the weight of a magnetic circuit part 2 are examined, suitable through-holes 3 e are selected, laser welding is performed by changing the laser radiation positions toward these through-holes, and the distance between this laser welding position and the central position of vibration of a suspension 3 and the housing is appropriate in order to accurately tune the vibration frequency of a suspension 3 to the desired value. As a result, it is possible to accurately tune the vibration frequency of a suspension 3 to the desired value during assembly.
An outer circumferential portion 3 a of a suspension 3 integrally installed to a magnetic circuit part 2 is stacked on this annular member 7, a housing 1 mounted with a diaphragm 4 and a voice coil 5 is placed over them, and an outer circumferential portion 3 a of a suspension 3 and an annular member 7 are inserted between the other open end 1 b and the aforementioned cover 6.
Thus, the lower peripheral side wall 1 c of a housing 1 is positioned close to the side peripheral wall 6 a of a cover 6 to be fitted with each other, the engaging protrusions 6 a and the engaging slits 6 b of an engaging means 8 provided to these walls are fitted and engaged with each other, and all the parts consisting of a housing 1, magnetic circuit part 2, suspension 3, diaphragm 4, voice coil 5, cover 6, and annular member 7 are integrally assembled to complete the assembly.
Therefore, a suspension 3 can be secured to a housing 1 without using adhesion, molding, or welding, and a shock force from the outside of a housing 1 can be absorbed by compressive deformation of an annular member 7. As a result, fluctuation of characteristics caused by a shock force from dropping can be prevented, and the characteristics of the vibration frequency can be flattened while reducing man-hours and costs. Moreover, changing the size or hardness of an annular member 7 results in the change in the pressure acting on an outer circumferential portion 3 a of a suspension 3, leading to easy tuning of the resonant frequency.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional front view of a multifunction-type vibration actuator showing one embodiment according to the invention.
DESCRIPTION OF REFERENCE CHARACTERS A Multifunction-type vibration actuator
3 e Securing planned position (through-hole for laser welding)
Patent CitationsCited PatentFiling datePublication dateApplicantTitleUS6208237 *Nov 26, 1997Mar 27, 2001Matsushita Electric Industrial Co. Ltd.Electro-mechanical and acoustic transducer for portable terminal unitUS7212647 *Sep 5, 2003May 1, 2007Namiki Seimitsu Houseki Kabushiki KaishaVibration actuator device of portable terminalUS7436088 *Jan 24, 2006Oct 14, 2008Citizen Electronics Co., Ltd.Electromagnetic exciterUS20030081807Oct 15, 2002May 1, 2003Citizen Electronics, Co., Ltd.Speaker and method for manufacturing the speakerUS20040075351Dec 27, 2002Apr 22, 2004Minoru UedaMulti-functional vibrating actuatorUS20040081331 *Oct 24, 2002Apr 29, 2004Kimihiro AndoElectro-acoustic transducer having vibrating function and method of manufacturing the sameUS20040146175 *Jan 29, 2003Jul 29, 2004Samsung Electro-Mechanics Co., Ltd.Resonance frequency correction method and vibration speakerUS20060165249 *Jul 4, 2003Jul 27, 2006Nec Tokin CorporationElectroacoustic transducerEP1315400A2Oct 18, 2002May 28, 2003Citizen Electronics Co., Ltd.Speaker and method for manufacturing the speakerEP1459811A1Dec 27, 2002Sep 22, 2004Namiki Seimitsu Houseki Kabushiki KaishaMulti-functional vibrating actuatorJP2002191092A Title not availableJP2003143676A Title not availableJP2004040612A Title not availableJPH117286A Title not availableWO2003057375A1Dec 27, 2002Jul 17, 2003Takayuki KumagaiMulti-functional vibrating actuator* Cited by examinerNon-Patent CitationsReference1International Search Report Application PCT JP 2005 004910 dated Jun. 28, 2005.Referenced byCiting PatentFiling datePublication dateApplicantTitleUS8035906 *Dec 20, 2007Oct 11, 2011Nikon CorporationVibration actuator, lens barrel and cameraUS8094863 *Nov 13, 2006Jan 10, 2012Yi DingSeparate support structure for loudspeaker diaphragmUS20120177244 *Dec 13, 2011Jul 12, 2012American Audio Components Inc.Speaker* Cited by examinerClassifications U.S. Classification310/15, 310/36, 381/386, 310/14, 310/13, 381/398International ClassificationH01F7/08, H04R31/00, H02K35/00, H04R9/02, H04R9/10, H02K41/00, G10K9/00Cooperative ClassificationH04R2400/03, H04R2400/07, H04R2499/11, H04R9/025European ClassificationH04R9/02DLegal EventsDateCodeEventDescriptionOct 17, 2012FPAYFee paymentYear of fee payment: 4Sep 15, 2006ASAssignmentOwner name: NAMIKI SEIMITU HOUSEKI KABUSHIKI KAISHA, JAPANFree format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:UEDA, MINORU;TAKEUCHI, SATOSHI;OONO, ETUO;REEL/FRAME:018318/0667;SIGNING DATES FROM 20060829 TO 20060831RotateOriginal ImageGoogle Home - Sitemap - USPTO Bulk Downloads - Privacy Policy - Terms of Service - About Google Patents - Send FeedbackData provided by IFI CLAIMS Patent Services©2012 Google