Rotary switch

Abstract

A rotary switch includes a rotation movable portion, a movable conductor held in the rotation movable portion, a base portion, a power supply terminal held in the base portion, and a plurality of fixed contacts held in the base portion. The fixed contact and the power supply terminal are connected and disconnected via the movable conductor by a rotational operation of the rotation movable portion. The power supply terminal is disposed at a rotation center position of the rotation movable portion. The plurality of fixed contacts are disposed on a plurality of concentric circles having different diameter dimensions around the power supply terminal.

Claims

1. A rotary switch comprising: a rotation movable portion; a movable conductor held in rotation movable portion; a base portion; a power supply terminal held in the base portion; and a plurality of fixed contacts held in the base portion, wherein the fixed contact and the power supply terminal are connected and disconnected via the movable conductor by a rotational operation of the rotation movable portion, wherein the power supply terminal is disposed at a rotation center position of the rotation movable portion, wherein the plurality of fixed contacts are disposed at positions where the shortest distances from a rotation center of the rotation movable portion are different, wherein when the movable conductor and the plurality of fixed contacts are in contact with each other, switching is ON, when the movable conductor and the plurality of fixed contacts are separated from each other, switching is OFF, wherein the movable conductor includes a power supply contact in pressed contact with the power supply terminal at one end portion and a single movable contact at the other end portion, and wherein the shortest distances are distances between each of the fixed contacts and the rotation center of the rotation movable portion.

2. The rotary switch according to claim 1, wherein a movable contact, which is in contact with or separated from only the fixed contact corresponding to a rotation of the rotation movable portion, is provided in the movable conductor.

3. The rotary switch according to claim 1, wherein a concave portion is provided in the base portion to surround each of the fixed contacts.

4. The rotary switch according to claim 1, wherein a plurality of the movable conductors, including a power supply contact pressed to be in contact with the power supply terminal at one end portion and a single movable contact at the other end portion, are movably held in the rotation movable portion and independent with each other.

5. The rotary switch according to claim 2, wherein the movable contact has a predetermined length and each of the fixed contacts is formed in a linear shape.

6. The rotary switch according to claim 1, wherein the movable conductor includes a plurality of the movable conductors, and wherein the plurality of fixed contacts are respectively applied to the plurality of the movable conductors.

7. The rotary switch according to claim 1, wherein the movable conductor includes a plurality of the movable conductors, and wherein the plurality of the movable conductors are held in accommodation grooves formed in the rotation movable portion.

8. The rotary switch according to claim 1, wherein the movable conductor includes a plurality of the movable conductors, and wherein the plurality of the movable conductors are urged to a surface side of the base portion by the rotation movable portion.

9. The rotary switch according to claim 1, wherein the movable conductor includes a plurality of the movable conductors, and wherein each of the plurality of the movable conductors has a substantially linear shape.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a sectional view illustrating a steering lock device according to an embodiment.

(2) FIG. 2 is an exploded perspective view of a rotary switch.

(3) FIG. 3 is a view illustrating arrangement of fixed contacts.

(4) FIG. 4 is a view illustrating a position of a movable conductor at a LOCK position.

(5) FIG. 5 is a sectional view illustrating a connection state between a power supply terminal and a fixed contact.

(6) FIG. 6 is a view illustrating a position of the movable conductor at an ON position.

(7) FIG. 7 is a view illustrating a position of the movable conductor at a START position.

(8) FIG. 8 is a chart illustrating a conduction state of a contact of the rotary switch.

DETAILED DESCRIPTION

(9) A rotary switch 6 of the disclosure configured as an ignition switch used for a steering lock device is illustrated in FIGS. 1 to 8. The steering lock device of the embodiment has a cylinder lock 11 accommodated in a housing 10 and a cam member 12 that is connected to a terminal end of a plug 11a of the cylinder lock 11, and is fixed to a steering column (not illustrated).

(10) A lock piece 13, which is moved between a lock position projecting to an inside of the steering column and an unlock position accommodated in an inside of the housing by advancing and retreating in a direction intersecting a rotation shaft of the cam member 12 at a predetermined angle, is mounted on the housing 10. The lock piece 13 is urged in a direction of the lock position by a compression spring 14 and when the plug 11a of the cylinder lock 11 is operated to rotate from a lock rotation position, the plug 11a of the cylinder lock 11 moves from the lock position engaged with a steering shaft to the unlock position released from the engagement, and an operation of the steering shaft can be performed.

(11) In addition, an ignition switch 6, which performs conduction between predetermined terminals in accordance with the rotation of the plug 11a and changes a power supply state to an electric system of the vehicle, is connected to the housing 10. In order to transmit the rotational operation of the plug 11a to the ignition switch 6, a connecting bar 15, which meshes with the cam member 12 and rotates together with the cam member 12, is disposed in the housing 10.

(12) The ignition switch 6 has a switch case 16 including a base portion 3 having a circular shape in plan view, a rotation movable portion 1 that is rotatable around a center (C3) of the base portion 3 with respect to the switch case 16, and a switch cover 17 that is connected to the switch case 16 and covers the rotation movable portion 1. A power supply terminal 4 and fixed contacts 5 are disposed in the base portion 3 formed of an insulating material in a state of being exposed on a rotation boundary surface with the rotation movable portion 1 (see FIG. 2).

(13) The power supply terminal 4 and each of the fixed contacts 5 are drawn out to a connector fastening member 16a via wires wired in the switch case.

(14) The rotation movable portion 1 is formed of an insulating material and a connecting hole la for connection with the connecting bar 15 is formed at one end portion thereof. The rotation movable portion 1 is urged only when returning from a START position to an ON position by a torsion spring 18 and moderately rotates at an appropriate connecting operation angle by fitting a click ball 20 urged by a click spring 19 into a groove of an inner wall of the switch cover 17.

(15) Furthermore, a plate-like movable conductor 2 having a predetermined plate thickness is accommodated in the rotation movable portion 1 so that a plate thickness surface faces the base portion 3. The movable conductor 2 has a V-shaped protruding power supply contact 9 at one end and a flat movable contact 7 at the other end, and a tip of the power supply contact 9 is chamfered in order to keep a contact state good when the power supply contact 9 is in pressed contact with the power supply terminal 4 of the base portion 3.

(16) As illustrated in FIG. 1, the movable conductor 2 formed as described above is accommodated in an accommodation groove 1b formed in the rotation movable portion 1, is movable in a direction along a rotation axis (C3), and is urged to a surface side of the base portion 3 by compression springs 21 which are accommodated in the rotation movable portion 1 and press back surfaces of the power supply contact 9 and the movable contact 7 (see FIG. 2).

(17) As illustrated in FIG. 3, the power supply terminal 4 is formed in a circular shape, is connected to power supply (not illustrated), and is disposed at a center portion of the base portion 3, that is, a position of the rotation center (C3) of the rotation movable portion 1.

(18) In addition, as illustrated in FIG. 8, three fixed contacts 5 of +IGN1, +IGN2, and START, at which the connection with the power supply terminal 4 is sequentially switched when the plug is operated to rotate in order of the LOCK, ON, and START positions, are provided. First, during moving from the LOCK position to the ON position, the +IGN2 contact 5 (IGN2) is connected to the power supply terminal 4 and power is supplied to a +IGN2 terminal having the +IGN2 contact 5 (IGN2). Next, the +IGN1 contact 5 (IGN1) is connected to the power supply terminal 4 and power supply to a +IGN1 terminal is added. When the plug is moved to the ON position, power supply to both the +IGN1 terminal and the +IGN2 terminal is completed.

(19) Thereafter, when the plug is operated to rotate from the ON position to the START position, first, the connection of the +IGN2 contact 5 (IGN2) with the power supply terminal 4 is released and power supply to the +IGN2 terminal is stopped. Next, a START contact 5 (ST) supplies power to a START terminal connected to the power supply terminal 4.

(20) Power supply to the +IGN1 terminal is continued even by moving the plug to the START position and then power supply to the START terminal and the +IGN1 terminal is continued to a stroke end position.

(21) As illustrated in FIG. 3, the three fixed contacts 5 described above are disposed on two concentric circles with respect to the center (C3) of the base portion 3. As illustrated in FIG. 8, an operation angle between the ON position and the START position is as small as substantially 30. If the +IGN2 contact 5 (IGN2) and the START contact 5 (ST) which are in contact or separate at the ON position and the START position are disposed on the same circumference, the START contact 5 (ST) and the +IGN2 contact 5 (IGN2) are disposed on different concentric circles when considering that an interval between both contacts is shortened. That is, the START contact 5 (ST) and the +IGN2 contact 5 (IGN2) are disposed at positions where the shortest distance from the center (C3) of the base portion 3 is different.

(22) Furthermore, the +IGN2 contact 5 (IGN2) is disposed on an inner circumference when considering that the number of occurrences of abrasion powder is large at the time of contacting or separating the contacts.

(23) That is, abrasion powder at the time of contacting or separating the contacts is likely to occur at places (four places surrounded by bold circles in FIG. 3) where the contact transits from an OFF state to an ON state. In addition to moving the plug from the LOCK position to the START position, even when returning from the START position to the ON position, the opposite end is switched from the OFF state to the ON state and switching to the ON state occurs at both ends of the contact while the +IGN2 contact 5 (IGN2) has one contact point when another contact transits from the OFF state to the ON state.

(24) From the above, since the number of occurrences of abrasion powder in the +IGN2 contact 5 (IGN2) is larger than that of other fixed contacts 5, the +IGN2 contact 5 (IGN2) is substantially separated from moving paths of the other fixed contacts 5 and thereby it is possible to effectively prevent deterioration of the entire insulation performance.

(25) In addition, the fixed contacts 5 are respectively disposed such that the transition place from the OFF state to the ON state is uniformly distributed within a plurality of fan-shaped regions 22 of which apexes are the center of the base portion 3 and center angles are substantially equal to each other. In FIG. 3, boundaries of the fan-shaped regions 22 are indicated by chain lines.

(26) Furthermore, as indicated by hatching in FIG. 3, a sliding bearing surface 23 is formed on the circumference on which each of the fixed contacts 5 is disposed. Each of the fixed contacts 5 is formed in a linear shape intersecting the sliding bearing surface 23 formed in an arc shape.

(27) Since the sliding bearing surface 23 supports the movable contact 7 when the movable conductor 2 which is described below moves, the sliding bearing surface 23 is formed at a position higher than a height of each of the fixed contacts 5 so that contact with the fixed contact 5 can be performed smoothly. In addition, the power supply terminal 4, the fixed contact 5, and the sliding bearing surface 23 are formed such that surroundings thereof are surrounded by a concave portion 8.

(28) In addition, the sliding bearing surface 23 which is formed on an inner circumference is formed to be lower in height than the sliding bearing surface 23 formed on an outer circumference and the movable contact 7 of the movable conductor 2 running on the sliding bearing surface formed on the outer circumference is not in contact with the fixed contact 5 and the sliding bearing surface 23 on the inside.

(29) On the other hand, as illustrated in FIGS. 4 and 5, the same number of the movable conductors 2 as the number of the fixed contacts 5 is used and in the embodiment having three fixed contacts 5, three movable conductors 2 are used.

(30) Each of the movable conductors 2 causes the power supply contact 9 to abut against the power supply terminal 4 of the base portion 3, the movable contact 7 to abut against the sliding bearing surface 23, and the power supply contact 9 and the movable contact 7 to be in pressed contact with the power supply terminal 4 and the sliding bearing surface 23 by the compression springs 21 in a state where the plug 11a is at the LOCK position.

(31) When the rotation movable portion 1 is rotated from this state to the ON position in the clockwise direction, as illustrated in FIG. 6, the +IGN1 and +IGN2 fixed contacts 5 are connected to the power supply terminal 4 via the movable conductor 2, and power is supplied to the +IGN1 and +IGN2 terminals. As described above, abrasion powder is likely to be generated at points of switching from OFF to ON of both the fixed contacts 5, that is, the contact start points of both the fixed contacts 5 due to use for a long period of time. However, the generated abrasion powder quickly falls into the concave portions 8 disposed at each contact start point, a side edge of the fixed contact 5, and a side edge of the sliding bearing surface 23. Therefore, dielectric breakdown or the like is prevented from occurring.

(32) When operating to rotate from the ON position to the START position, as illustrated in FIG. 7, only the contact of the +IGN2 contact 5 (IGN2) is released and then power is supplied to the +IGN2 terminal with the opposite end with respect to the contact start point as the contact start point in a forward path of the +IGN2 contact 5 (IGN2) again when returning to the ON position.

(33) During the operation described above, the movable conductor 2 moves on the linear fixed contact 5 by an arcuate trajectory so that the movable conductor 2 operates so as to sweep abrasion powder on the fixed contact 5 by the movable conductor 2 and stagnation of abrasion powder on the fixed contact 5 is regulated.

(34) This application is based on Japanese patent application (Japanese Patent Application No. 2015-103731) filed on May 21, 2015 and the contents of which are incorporated herein by reference.

REFERENCE SIGNS LIST

(35) 1 rotation movable portion 2 movable conductor 3 base portion 4 power supply terminal 5 fixed contact 6 rotary switch 7 movable contact 8 concave portion 9 power supply contact