The present invention relates to a push switch including an operation body to be pushed along a direction parallel to a surface of a circuit board the push switch is mounted onto.
Various types of push switches are used for input sections of electronic devices. A push switch which is activated by pushing an operation body of the switch in parallel to a surface of a board the push switch is mounted onto is often used.
Case 1 made of resin material has a recess opening upward. Inner fixed contact 2A and an outer fixed contact are located in the recess and are fixed unitarily within case 1. Terminals 5 connected with inner fixed contact 2A and the outer fixed contact protrude from side surfaces of case 1 opposite to each other, respectively. Terminals 5 have ends which are bent up, and have shapes suitable for being mounted onto the surface of a board.
Movable contact 7 is made of a thin metal plate. Movable contact 7 is accommodated in the recess of case 1, and has its outer circumference placed on the outer fixed contact. The recess of case 1 is covered with protection film 8 adhered onto on an upper surface of case 1. Movable contact 7 has a square shape, or circular shape.
Operation body 10 made of resin material includes operation portion 10A protruding to the front and driving portion 10B located behind operation portion 10A. Operation body 10 is placed on protection film 8 such that the operation body is movable in front and back directions on the upper surface of case 1.
Metal cover 15 covers case 1 with operation body 10 between the cover and the case. Slope portion 15A is formed at the central part of metal cover 15 and inclines towards case 1. Slope portion 15A is positioned behind driving portion 10B. An end of driving portion 10B contacts a front surface of slope portion 15A which inclines. Metal cover 15 has leg 15B which can be soldered and which protrudes downward at the side surface of case 1.
If an operating force is applied to operation portion 10A for pushing operation portion 10A in a direction parallel to surface 501C, operation body 10 moves along the parallel direction by sliding on protection film 8 covering the upper surface of case 1. Then, the end of driving portion 10B is guided downward along slope portion 15A to apply a downward force to movable contact 7 located beneath slope portion 15A.
When the downward force exceeds a predetermined level, movable contact 7 is inverted at the central part and has its central bottom contact inner fixed contact 2A. Thereby, terminals 5 are connected via movable contact 7, thus turning on push switch 501.
Upon the force applied to operation portion 10A being released, movable contact 7 returns to have its original shape by its restoring force and pushes driving portion 10B upward. Driving portion 10B which is pushed up is guided along slope portion 15A and causes operation body 10 to be pushed back to the front, thereby turning off push switch 501, as shown in
In the conventional push switch 501, soldered portions of terminals 5 and leg 15B of metal cover 15 receive the operating force applied to operation portion 10A. Even if push switch 501 is small in size, a certain clearance between leg 15B and terminals 5 are necessary to avoid possible mutual contact of solder applied to terminals 5 and leg 15B. This structure accordingly prevents push switch 501 from having a small size.
If the number of constituent members, such as terminal 5 and leg 15B, which are connected with board 501A, is decreased in order to reduce the size of push switch 501 and to allow the push switch to be suitable for a portable device, board 501A may be removed when the portable device is dropped.
A push switch is arranged to be mounted on a board. The push switch includes a case, a plurality of contacts provided in the case, an operation body for activating the plurality of contacts upon being pushed in an operation direction parallel to the surface of the board, first and second terminals protruding from the case. The case has first and second side surfaces opposite to each other. The first terminal includes a first base portion protruding from the first side surface of the case, and a first end portion extending from the first base portion in a direction non-parallel to perpendicular to the operation direction. The second terminal includes a second base portion protruding from the second side surface of the case and a second end portion extending from the second base portion in a direction non-parallel to perpendicular to the operation direction.
The push switch has a small size and is mounted securely onto a board.
Case 21 made of insulating resin has an upper surface having recess 21D provided therein, and has a substantially rectangular shape viewed from upper surface 21C. Inner fixed contact 24A and outer fixed contact 24B are exposed from bottom 21E of recess 21D, and are fixed by insert-molding. Terminals 30 connected to inner fixed contact 24A and outer fixed contact 24B protrude from side surfaces 21F and 21G of case 21 opposite to each other, respectively. Bottom surface 30P of terminal 30 is on the same plane as bottom surface 21H of case 21. Bottom surface 21H is arranged to be parallel with surface 60B when the switch is mounted on board 60.
Recess 21D of case 21 accommodates movable contact 25 made of a thin metal plate. Outer circumferential edge 25A of movable contact 25 is placed on outer fixed contact 24B. Recess 21D of case 21 is covered with protection film 28 adhered onto upper surface 21C of case 21.
Operation body 40 is placed on upper surface 28A of protection film 28, and is covered with metal cover 50 assembled to case 21. Operation body 40 has operation portion 40A protruding from cover 50 in direction 1001A. When operation portion 40A is pushed in direction 1001B opposite to direction 1001A, operation body 40 moves in direction 1001A. Operation body 40 includes operation portion 40A, frame portion 40B, and driving portion 40C which are molded unitarily with resin. Frame portion 40B is located from operation portion 40A in direction 1001B, and has a flat plate shape having through-hole 40D provided therein. Driving portion 40C has substantially a rod shape extending from operation portion 40A in direction 1001B to through-hole 40D of frame portion 40B. Frame portion 40B is placed on upper surface 28A of protection film 28 and has both side portions 40E guided by inner surfaces of case 21, thus allowing operation body 40 to move in directions 1001A and 1001B. Operation portion 40A has operation end 40G protruding downward to be lower than lower surface 40F of frame portion 40B, thus having substantially an L-shape. The operation end 40G is arranged to be pushed by a user.
Cover 50 includes slope portion 52 protruding downward into through-hole 40D of frame portion 40B of operation body 40. Slope portion 52 extends and inclines towards recess 21D and in direction 1001B. When operation portion 40A is not pushed or is not activated, end 40H of driving portion 40C of operation body 40 contacts lower surface 52B of slope portion 52 of cover 50.
Case 21 includes lower protrusion 21A protruding downward from bottom surface 21H, and two bumps 21B protruding from lower protrusion in direction 1001B. Width W1 of lower protrusion 21A in direction 1001C perpendicular to direction 1001B in which lower protrusion protrudes is about ⅓ to ¾ of width W2 of case 21 in direction 1001C. Width W3 of lower protrusion 21A in direction 1001B is large.
The center of case 21 in direction 1001C and the center of lower protrusion 21A in direction 1001C coincide on center line 1001D. Two bumps 21B are arranged symmetrically about center line 1001D and located away from center line 1001D by the same distances.
Terminals 30 connected with inner fixed contact 24A and outer fixed contact 24B protrude from side surfaces 21F and 21G of case 21, respectively. Terminals 30 include front terminals 30A and back terminals 30B located away from front terminal 30A in direction 1001B. A pair of front terminal 30A and back terminal 30B protrudes from side surface 21F of case 21, while another pair of front terminal 30A and back terminal 30B protrude from side surface 21G.
Terminals 30A and 30B are made of plate, such as brass plate having a thickness of 0.15 mm or phosphor bronze plate having a thickness ranging from 0.10 mm to 0.12 mm. Although the thickness is different depending on the materials, their soldering strength is the same. Namely, a phosphor bronze plate contains tin, and accordingly, has a soldering strength approximately 10% greater than that of a brass plate. Terminals 30 made of phosphor bronze allow switch 1001 to be thinner than terminals 30 made of brass. Terminals 30 (30A, 30B) have shapes suitable for being mounted on the surface. Namely, terminal 30 has bottom surface 30P flush with bottom surface 21H of case 21.
Front terminal 30A protruding from side surface 21G of case 21 includes base portion 130A and end portion 230A. Base portion 130A extends from side surface 21G by predetermined distance D1 in direction 1001F perpendicular to operation direction 1001B. End portion 230A extends from base portion 130A in direction 1001G approaching operation direction 1001B by an angle of 45°, and has a width identical to that of base portion 130A. Ascent portion 37A is provided at end 330A of front terminal 30A, i.e., at end 330A of end portion 230A. Ascent portion 37A protrudes in direction 1001L perpendicular to and away from bottom surface 30P, and is formed by bending the end portion. Ascent portion 37A has surface 137A perpendicular to bottom surface 30P. Surface 137A faces towards direction 1001G and is perpendicular to direction 1001G. Surface 137A is connected with end portion 230A at straight line 237A.
Back terminal 30B protruding from side surface 21G of case 21 includes base portion 130B and end portion 230B. Base portion 130B extends from side surface 21G by predetermined distance D2 in direction 1001F perpendicular to operation direction 1001B. End portion 230B extends from base portion 130B in direction 1001H approaching operation direction 1001A by an angle of 45°, and has a width identical to that of base portion 130B. Ascent portion 37B is provided at end 330B of back terminal 30B, i.e., at end 330B of end portion 230B. Ascent portion 37B protrudes in direction 1001L perpendicular to and away from bottom surface 30P, and is formed by bending the end portion. Ascent portion 37B has surface 137B perpendicular to bottom surface 30P. Surface 137B faces towards direction 1001H and is perpendicular to direction 1001H. Surface 137B is connected with end portion 230B at straight line 237B.
Front terminal 30A protruding from side surface 21F of case 21 includes base portion 130A and end portion 230A. Base portion 130A extends from side surface 21F by predetermined distance D1 in direction 1001E perpendicular to operation direction 1001B. End portion 230A extends from base portion 130A in direction 1001J approaching operation direction 1001B by an angle of 45°, and has a width identical to that of base portion 130A. Ascent portion 37A is provided at end 330A of front terminal 30A, i.e., at end 330A of end portion 230A. Ascent portion 37A protrudes in direction 1001L perpendicular to and away from bottom surface 30P, and is formed by bending the end portion. Ascent portion 37A has surface 137A perpendicular to bottom surface 30P. Surface 137A faces towards direction 1001J and is perpendicular to direction 1001J. Surface 137A is connected with end portion 230A at straight line 237A.
Back terminal 30B protruding from side surface 21F of case 21 includes base portion 130B and end portion 230B. Base portion 130B extends from side surface 21F by predetermined distance D2 in direction 1001E perpendicular to operation direction 1001B. End portion 230B extends from base portion 130B in direction 1001K approaching operation direction 1001A by an angle of 45°, and has a width identical to that of base portion 130B. Ascent portion 37B is provided at end 330B of back terminal 30B, i.e., at end 330B of end portion 230B. Ascent portion 37B protrudes in direction 1001L perpendicular to and away from bottom surface 30P, and is formed by bending the end portion. Ascent portion 37B has surface 137B perpendicular to bottom surface 30P. Surface 137B faces towards direction 1001K and is perpendicular to direction 1001K. Surface 137B is connected with end portion 230B at straight line 237B.
The angle between the directions in which the end portion and the base portion extend may be an angle other than 45°.
Circuit board 60 has cutout 60A having a rectangular shape provided in edge 60C. Edge surface 60D is located on cutout 60A of circuit board 60. Lower protrusion 21A is placed in cutout 60A. Tip 121B of bump 21B contacts edge surface 60D of cutout 60A. When circuit board 60 is manufactured, cutout 60A may be formed, thereby not increasing its manufacturing time or cost. While terminals 30A and 30B are placed on lands 61A and 61B to be connected with terminals 30A and 30B, respectively, lands 61A and 61B have portions 261A and 261B located in direction 1001B from terminals 30A and 30B, respectively, and has portions 161A and 161B located in direction 1001A from terminals 30A and 30B, respectively. The areas of portions 261A and 261B of land 61A and 61B are determined to be larger than those of portions 161A and 161B, respectively. This arrangement causes solder fillet 62A and 62B to pull switch 1001 in operation direction 1001B when terminals 30A and 30B are soldered on land 61A and 61B, respectively. Thus, push switch 1001 is mounted easily, as shown in
As shown in
Ascent portions 37A and 37B provided at ends 330A and 330B of terminals 30A and 30B have surfaces 137A and 137B which are non-parallel with, i.e., deviate from operation direction 1001B, respectively. This arrangement allows surfaces 137A and 137B to have large areas projecting in direction 1001B on solder fillet 62A and 62B which connect terminals 30A and 30B with lands 61A and 61B, respectively. Terminals 30A and 30B have large resistance to forces in direction 1001B and direction 1001A opposite to direction 1001B, accordingly mounting push switch 1001 on board 60 securely against an operation force applied to operation body 40.
When solder fillets 62A and 62B are formed, excessive solder and flux appeared between each of bottom surfaces 30P of terminals 30A (30) and 30B (30) and each of lands 61A and 61B concentrate at ascent portions 37A and 37B extending perpendicularly to bottom surfaces 30P, and form solder fillets 62A and 62B. This operation prevents the excessive solder and flux from causing push switch 1001 to float from board 60. Edges of ascent portions 37A and 37B provided at ends 330A and 330B of terminals 30A and 30B are located close to side surfaces 21F and 21G of case 21. This structure causes excessive flux to be retained on side surface 21F and 21G, and accordingly allows recess 21D accommodating movable contact 25 and fixed contacts 24A and 24B therein to have a small wall thickness, accordingly allowing push switch 1001 to have a small size.
An operation of push switch 1001 will be described below.
An operating force in operation direction 1001B parallel to surface 60B of board 60 is applied to operation portion 40A of operation body 40 to push operation body 40, thereby causing operation body 40 to move along an axis 40J in direction 1001B while guided with case 21. Driving portion 40C contacting lower surface 52B of slope portion 52 moves accordingly downward while guided on lower surface 52B in direction 1001M towards movable contact 25. Upon moving, driving portion 40C applies a force pressing down the center of movable contact 25 via protection film 28. When the pressing force exceeds a predetermined level, movable contact 25 is elastically inverted at its center, and has its bottom surface contact inner fixed contact 24A. Thereby, inner fixed contact 24A and outer fixed contact 24B are connected electrically with each other via movable contact 25, thus turning on push switch 1001.
When the operating force applied to operation portion 40A is released, movable contact 25 returns to have its original shape by its restoring force and is removed from inner fixed contact 24A. Accordingly, inner fixed contact 24A is electrically disconnected from outer fixed contact 24B, thus turning off push switch 1001. Then, movable contact 25 pushes driving portion 40C upward via protection film 28. Driving portion 40C accordingly moves while being guided on lower surface 52B of slope portion 52 in direction 1001A opposite to operation direction 1001B, and operation body 40 is pushed back in direction 1001A, as shown in
As described below, push switch 1001 is mounted securely on circuit board 60 even being activated, thus being prevented from being removed.
Operation portion 40A includes operation end 40G protruding downward in direction 1001M towards a plane flush with surface 60B of board 60, i.e., with bottom surface 21H of case 21. Thus, operation portion 40A as a whole has an L-shape as viewed from its side. This shape allows the operating force to be applied to operation portion 40A at a height close to surface 60B of board 60. This structure prevents the operation force from producing a less moment than a push switch including an operation body to be pushed at a level higher than the surface of a board. Push switch 1001 reduces a force for removing terminal 30, especially front terminal 30A, perpendicular from board 60, accordingly being prevented from being peeled off from board 60 even being activated.
Operation end 40G of operation portion 40A may extend beyond lower surface 21H of case 21, i.e., beyond surface 60B of board 60. This structure allows the operating force to be applied to operation portion 40A at a level within the thickness of board 60. However, this structure causes the base portion of operation end 40G to receive a large stress when operation body 40 is activated. Therefore, if operation body 40 is made of only resin, the length of operation end 40G is determined according to durability of operation portion 40A. Operation end 40G of operation portion 40A preferably has a length substantially reaching the same level as surface 60B of board 60, or just above surface 60B.
Even in the case that operation end 40G of operation portion 40A extends in direction 1001M, push switch 1001 receives the moment causing the switch to float from the front according to the operating force. This moment influences the connection of terminals 30A and 30B. In order to reduce this influence, push switch 1001 is mounted on board 60 such that tips 121B of bump 21B protruding from lower protrusion 21A of case 21 contact edge surface 60D of cutout 60A of board 60.
The operating force applied to operation portion 40A during the activating of the push switch may cause case 21 to move in operation direction 1001B. In this case, bump 21B provided between edge surface 60D of cutout 60A of board 60 and lower protrusion 21A is compressed to alleviate the force pushing case 21 in direction 1001B. If the pushing force is excessively large, bump 21B may crush. Then, the pushing force is further alleviated. The crushing of bump 21B displaces case 21 in direction 1001B by distance L1, i.e., height L1 of bump 21B. Height L1 is determined so that the displacement of case 21 may not influence the connection between terminals 30A and 30B and lands 61A and 61B even if case 21 is displaced by distance L1 in direction 1001B.
If bump 21B crushes, lower protrusion 21A moves to contact edge surface 60D of cutout 60A, and stops. Since edge surface 60D which stops lower protrusion 21A is located at a height lower than the operating force, the moment produced by the operating force is small. Edge surface 60D at cutout 60A receives the pushing force in direction 1001B. Terminals 30A and 30B do not receive large load, accordingly providing push switch 1001 with a large resistance against the pushing force in direction 1001B. The diameter of bump 21B may be determined, such that bump 21B is compressed and does not crush when an ordinary operating force is applied to operating portion 40A, and bump 21B crushes when an excessive operating force larger than the ordinary force is applied.
Two front terminals 30A extending from side surfaces 21F and 21G, respectively, are arranged symmetrically to each other about moving axis 40J, and have shapes symmetrical to each other about moving axis 40J. Two back terminals 30B extending from side surfaces 21F and 21F, respectively, are arranged symmetrically to each other about moving axis 40J, and have shapes symmetrical to each other about moving axis 40J.
Front terminal 1030A protruding from side surface 21G of case 21 includes base portion 1130A and end portion 1230A. Base portion 1130A extends from side surface 21G by predetermined distance D1 in direction 1001F perpendicular to operation direction 1001B. End portion 1230A extends from base portion 1130A in direction 1001H approaching operation direction 1001A by an angle of 45°, and has a width identical to that of base portion 1130A. Ascent portion 1037A is provided at end 1330A of front terminal 1030A, i.e., at end 1330A of end portion 1230A. Ascent portion 1037A protrudes in direction 1001L perpendicular to and away from bottom surface 1030P, and is formed by bending the end portion. Ascent portion 1037A has surface 1137A perpendicular to bottom surface 1030P. Surface 1137A faces towards direction 1001H and is perpendicular to direction 1001H. Surface 1137A is connected with end portion 1230A at straight line 1237A.
Back terminal 1030B protruding from side surface 21G of case 21 includes base portion 1130B and end portion 1230B. Base portion 1130B extends from side surface 21G by predetermined distance D2 in direction 1001F perpendicular to operation direction 101B. End portion 1230B extends from base portion 1130B in direction 1001G approaching operation direction 1001B by an angle of 45°, and has a width identical to that of base portion 1130B. Ascent portion 1037B is provided at end 1330B of back terminal 1130B, i.e., at end 1330B of end portion 1230B. Ascent portion 1037B protrudes in direction 1001L perpendicular to and away from bottom surface 1030P, and is formed by bending the end portion. Ascent portion 1037B has surface 1137B perpendicular to bottom surface 1030P. Surface 1137B faces towards direction 1001G and is perpendicular to direction 1001G. Surface 1137B is connected with end portion 1230B at straight line 1237B.
Front terminal 1030A protruding from side surface 21F of case 21 includes base portion 1130A and end portion 1230A. Base portion 1130A extends from side surface 21F by predetermined distance D1 in direction 1001E perpendicular to operation direction 1001B. End portion 1230A extends from base portion 1130A in direction 1001K approaching operation direction 1001A by an angle of 45°, and has a width identical to that of base portion 1130A. Ascent portion 1037A is provided at end 1330A of front terminal 1030A, i.e., at end 1330A of end portion 1230A. Ascent portion 1037A protrudes in direction 1001L perpendicular to and away from bottom surface 1030P, and is formed by bending the end portion. Ascent portion 1037A has surface 1137A perpendicular to bottom surface 1030P. Surface 1137A faces towards direction 1001K and is perpendicular to direction 1001K. Surface 1137A is connected with end portion 1230A at straight line 1237A.
Back terminal 1030B protruding from side surface 21F of case 21 includes base portion 1130B and end portion 1230B. Base portion 1130B extends from side surface 21F by predetermined distance D2 in direction 1001E perpendicular to operation direction 1001B. End portion 1230B extends from base portion 1130B in direction 1001J approaching operation direction 1001B by an angle of 45°, and has a width identical to that of base portion 1130B. Ascent portion 1037B is provided at end 1330B of back terminal 1030B, i.e., at end 1330B of end portion 1230B. Ascent portion 1037B protrudes in direction 1001L perpendicular to and away from bottom surface 1030P, and is formed by bending the end portion. Ascent portion 1037B has surface 1137B perpendicular to bottom surface 1030P. Surface 1137B faces towards direction 1001J and is perpendicular to direction 1001J. Surface 1137B is connected with end portion 1230B at straight line 1237B.
Two front terminals 1030A extending from side surfaces 21F and 21G, respectively, are arranged symmetrically to each other about moving axis 40J, and have shapes symmetrical to each other about moving axis 40J. Two back terminals 1030B extending from side surfaces 21F and 21G, respectively, are arranged symmetrically to each other about moving axis 40J, and have shapes symmetrical to each other about moving axis 40J.
Push switch 1002 shown in
Front terminal 2030A protruding from side surface 21G of case 21 includes base portion 2130A and end portion 2230A. Base portion 2130A extends from side surface 21G by predetermined distance D1 in direction 1001F perpendicular to operation direction 1001B. End portion 2230A extends from base portion 2130A in direction 1001H approaching operation direction 1001A by an angle of 45°, and has a width identical to that of base portion 2130A. Ascent portion 2037A is provided at end 2330A of front terminal 2030A, i.e., at end 2330A of end portion 2230A. Ascent portion 2037A protrudes in direction 1001L perpendicular to and away from bottom surface 2030P, and is formed by bending the end portion. Ascent portion 2037A has surface 2137A perpendicular to bottom surface 2030P. Surface 2137A faces towards direction 1001H and is perpendicular to direction 1001H. Surface 2137A is connected with end portion 2230A at straight line 2237A.
Back terminal 2030B protruding from side surface 21G of case 21 includes base portion 2130B and end portion 2230B. Base portion 2130B extends from side surface 21G by predetermined distance D2 in direction 1001F perpendicular to operation direction 1001B. End portion 2230B extends from base portion 2130B in direction 1001H approaching operation direction 1001A by an angle of 45°, and has a width identical to that of base portion 2130B. Ascent portion 2037B is provided at end 2330B of back terminal 2130B, i.e., at end 2330B of end portion 2230B. Ascent portion 2037B protrudes in direction 1001L perpendicular to and away from bottom surface 2030P, and is formed by bending the end portion. Ascent portion 2037B has surface 2137B perpendicular to bottom surface 2030P. Surface 2137B faces towards direction 1001H and is perpendicular to direction 1001H. Surface 2137B is connected with end portion 2230B at straight line 2237B.
Front terminal 2030A protruding from side surface 21F of case 21 includes base portion 2130A and end portion 2230A. Base portion 2130A extends from side surface 21F by predetermined distance D1 in direction 1001E perpendicular to operation direction 1001B. End portion 2230A extends from base portion 2130A in direction 1001K approaching operation direction 1001A by an angle of 45°, and has a width identical to that of base portion 2130A. Ascent portion 2037A is provided at end 2330A of front terminal 2030A, i.e., at end 2330A of end portion 2230A. Ascent portion 2037A protrudes in direction 1001L perpendicular to and away from bottom surface 2030P, and is formed by bending the end portion. Ascent portion 2037A has surface 2137A perpendicular to bottom surface 2030P. Surface 2137A faces towards direction 1001K and is perpendicular to direction 1001K. Surface 2137A is connected with end portion 2230A at straight line 2237A.
Back terminal 2030B protruding from side surface 21F of case 21 includes base portion 2130B and end portion 2230B. Base portion 2130B extends from side surface 21F by predetermined distance D2 in direction 1001E perpendicular to operation direction 1001B. End portion 2230B extends from base portion 2130B in direction 1001K approaching operation direction 1001A by an angle of 45°, and has a width identical to that of base portion 2130B. Ascent portion 2037B is provided at end 2330B of back terminal 2030B, i.e., at end 2330B of end portion 2230B. Ascent portion 2037B protrudes in direction 1001L perpendicular to and away from bottom surface 2030P, and is formed by bending the end portion. Ascent portion 2037B has surface 2137B perpendicular to bottom surface 2030P. Surface 2137B faces towards direction 1001K and is perpendicular to direction 1001K. Surface 2137B is connected with end portion 2230B at straight line 2237B.
Two front terminals 2030A extending from side surfaces 21F and 21G, respectively, are arranged symmetrically to each other about moving axis 40J, and have shapes symmetrical to each other about moving axis 40J. Two back terminals 2030B extending from side surfaces 21F and 21G, respectively, are arranged symmetrically to each other about moving axis 40J, and have shapes symmetrical to each other about moving axis 40J.
Push switch 1003 shown in
Front terminal 3030A protruding from side surface 21G of case 21 includes base portion 3130A and end portion 3230A. Base portion 3130A extends from side surface 21G by predetermined distance D1 in direction 1001F perpendicular to operation direction 1001B. End portion 3230A extends from base portion 3130A in direction 1001G approaching operation direction 1001B by an angle of 45°, and has a width identical to that of base portion 3130A. Ascent portion 3037A is provided at end 3330A of front terminal 3030A, i.e., at end 3330A of end portion 3230A. Ascent portion 3037A protrudes in direction 1001L perpendicular to and away from bottom surface 3030P, and is formed by bending the end portion. Ascent portion 3037A has surface 3137A perpendicular to bottom surface 3030P. Surface 3137A faces towards direction 1001G and is perpendicular to direction 1001G. Surface 3137A is connected with end portion 3230A at straight line 3237A.
Back terminal 3030B protruding from side surface 21G of case 21 includes base portion 3130B and end portion 3230B. Base portion 3130B extends from side surface 21G by predetermined distance D2 in direction 1001F perpendicular to operation direction 1001B. End portion 3230B extends from base portion 3130B in direction 1001G approaching operation direction 1001B by an angle of 45°, and has a width identical to that of base portion 3130B. Ascent portion 3037B is provided at end 3330B of back terminal 3130B, i.e., at end 3330B of end portion 3230B. Ascent portion 3037B protrudes in direction 1001L perpendicular to and away from bottom surface 3030P, and is formed by bending the end portion. Ascent portion 3037B has surface 3137B perpendicular to bottom surface 3030P. Surface 3137B faces towards direction 1001G and is perpendicular to direction 1001G. Surface 3137B is connected with end portion 3230B at straight line 3237B.
Front terminal 3030A protruding from side surface 21F of case 21 includes base portion 3130A and end portion 3230A. Base portion 3130A extends from side surface 21F by predetermined distance D1 in direction 1001E perpendicular to operation direction 1001B. End portion 3230A extends from base portion 3130A in direction 1001J approaching operation direction 1001B by an angle of 45°, and has a width identical to that of base portion 3130A. Ascent portion 3037A is provided at end 3330A of front terminal 3030A, i.e., at end 3330A of end portion 3230A. Ascent portion 3037A protrudes in direction 1001L perpendicular to and away from bottom surface 3030P, and is formed by bending the end portion. Ascent portion 3037A has surface 3137A perpendicular to bottom surface 3030P. Surface 3137A faces towards direction 1001J and is perpendicular to direction 1001J. Surface 3137A is connected with end portion 3230A at straight line 3237A.
Back terminal 3030B protruding from side surface 21F of case 21 includes base portion 3130B and end portion 3230B. Base portion 3130B extends from side surface 21F by predetermined distance D2 in direction 1001E perpendicular to operation direction 1001B. End portion 3230B extends from base portion 3130B in direction 1001J approaching operation direction 1001B by an angle of 45°, and has a width identical to that of base portion 3130B. Ascent portion 3037B is provided at end 3330B of back terminal 3030B, i.e., at end 3330B of end portion 3230B. Ascent portion 3037B protrudes in direction 1001L perpendicular to and away from bottom surface 3030P, and is formed by bending the end portion. Ascent portion 3037B has surface 3137B perpendicular to bottom surface 3030P. Surface 3137B faces towards direction 1001J and is perpendicular to direction 1001J. Surface 3137B is connected with end portion 3230B at straight line 3237B.
Two front terminals 3030A extending from side surfaces 21F and 21G, respectively, are arranged symmetrically to each other about moving axis 40J, and have shapes symmetrical to each other about moving axis 40J. Two back terminals 3030B extending from side surfaces 21F and 21G, respectively, are arranged symmetrically to each other about moving axis 40J, and have shapes symmetrical to each other about moving axis 40J.
Push switch 1004 shown in
Front terminal 4030A protruding from side surface 21G of case 21 includes base portion 4130A and end portion 4230A. Base portion 4130A extends from side surface 21G by predetermined distance D1 in direction 1001F perpendicular to operation direction 1001B. End portion 4230A extends from base portion 4130A in direction 1001B, and has a width identical to that of base portion 4130A. Ascent portion 4037A is provided at end 4330A of front terminal 4030A, i.e., at end 4330A of end portion 4230A. Ascent portion 4037A protrudes in direction 1001L perpendicular to and away from bottom surface 4030P, and is formed by bending the end portion. Ascent portion 4037A has surface 4137A perpendicular to bottom surface 4030P. Surface 4137A faces towards direction 1001B and is perpendicular to direction 1001B. Surface 4137A is connected with end portion 4230A at straight line 4237A.
Back terminal 4030B protruding from side surface 21G of case 21 includes base portion 4130B and end portion 4230B. Base portion 4130B extends from side surface 21G by predetermined distance D2 in direction 1001F perpendicular to operation direction 1001B. End portion 4230B extends from base portion 4130B in direction 1001B, and has a width identical to that of base portion 4130B. Ascent portion 4037B is provided at end 4330B of back terminal 4130B, i.e., at end 4330B of end portion 4230B. Ascent portion 4037B protrudes in direction 1001L perpendicular to and away from bottom surface 4030P, and is formed by bending the end portion. Ascent portion 4037B has surface 4137B perpendicular to bottom surface 4030P. Surface 4137B faces towards direction 1001B and is perpendicular to direction 1001B. Surface 4137B is connected with end portion 4230B at straight line 4237B.
Front terminal 4030A protruding from side surface 21F of case 21 includes base portion 4130A and end portion 4230A. Base portion 4130A extends from side surface 21F by predetermined distance D1 in direction 1001E perpendicular to operation direction 1001B. End portion 4230A extends from base portion 4130A in direction 1001B, and has a width identical to that of base portion 4130A. Ascent portion 4037A is provided at end 4330A of front terminal 4030A, i.e., at end 4330A of end portion 4230A. Ascent portion 4037A protrudes in direction 1001L perpendicular to and away from bottom surface 4030P, and is formed by bending the end portion. Ascent portion 4037A has surface 4137A perpendicular to bottom surface 4030P. Surface 4137A faces towards direction 1001B and is perpendicular to direction 1001B. Surface 4137A is connected with end portion 4230A at straight line 4237A.
Back terminal 4030B protruding from side surface 21F of case 21 includes base portion 4130B and end portion 4230B. Base portion 4130B extends from side surface 21F by predetermined distance D2 in direction 1001E perpendicular to operation direction 1001B. End portion 4230B extends from base portion 4130B in direction 1001B, and has a width identical to that of base portion 4130B. Ascent portion 4037B is provided at end 4330B of back terminal 4030B, i.e., at end 4330B of end portion 4230B. Ascent portion 4037B protrudes in direction 1001L perpendicular to and away from bottom surface 4030P, and is formed by bending the end portion. Ascent portion 4037B has surface 4137B perpendicular to bottom surface 4030P. Surface 4137B faces towards direction 1001B and is perpendicular to direction 1001B. Surface 4137B is connected with end portion 4230B at straight line 4237B.
Two front terminals 4030A extending from side surfaces 21F and 21G, respectively, are arranged symmetrically to each other about moving axis 40J, and have shapes symmetrical to each other about moving axis 40J. Two back terminals 4030B extending from side surfaces 21F and 21G, respectively, are arranged symmetrically to each other about moving axis 40J, and have shapes symmetrical to each other about moving axis 40J.
Push switch 1005 shown in
The terminals having the above arrangements may be used in a single push switch. The terminals may protrude from side surfaces 21F and 21G of case 21 in directions 1001G, 1001H, 1001K or 1001J, respectively, but not in directions 1001E and 1001F.
The front terminals are affected by the moment produced by the operating force applied to operation portion 40A more strongly than the back terminals are. A push switch may include back terminals having shapes identical to those of terminals 5 of conventional push switch 501 shown in
Similarly to terminals 30 of push switch 1001 shown in
Similarly to terminals 30 of push switch 1001 shown in
As described above, push switches 1001 to 1005 in accordance with the embodiment can be mounted securely on board 60 without legs provided at cover 50 for soldering. The push switches are not removed easily from the board, and have a small thickness.
Lower protrusion 21A, bump 21B, and terminals 30 having various shapes may be combined for providing large effects. However, the push switch may include at least one of them. The push switch may include bump 21B according to requirement.
As described above, the terminal which includes the deviating end portion and the ascent portion provided at the end of the end portion is applicable to other switches and other devices including a terminal extending from a case perpendicularly to an operation direction, and provides the same effects.
Number | Date | Country | Kind |
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2006-159436 | Jun 2006 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
4359614 | Green et al. | Nov 1982 | A |
4778965 | Valenzona | Oct 1988 | A |
6489580 | Yanai et al. | Dec 2002 | B2 |
6809272 | Yamada | Oct 2004 | B2 |
6815628 | Okita et al. | Nov 2004 | B2 |
6894240 | Komoto et al. | May 2005 | B2 |
6967295 | Ting | Nov 2005 | B2 |
7022928 | Watanabe et al. | Apr 2006 | B2 |
7157650 | Rochon | Jan 2007 | B2 |
Number | Date | Country |
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2005-122989 | May 2005 | JP |
Number | Date | Country | |
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20070284236 A1 | Dec 2007 | US |