A variable resistor includes: a main body and a rotating part vertically separated away from each other, among which the main body includes: a substrate having a first main surface, a second main surface and a through hole vertically penetrating the first main surface and the second main surface; a first conductive portion and a second conductive portion provided on the first main surface; a resistor body connected thereto; an electrode positioned closer to the through hole than the resistor body; and a third conductive portion (i) provided on each of the second main surface and a partition wall surface for partitioning the through hole and (ii) connected to the electrode, and the rotating part includes: an opposing part rotatable in a circumferential direction; and a slider configured to conductively slide as the rotating part rotates.

A variable resistor includes: a main body and a rotating part vertically separated away from each other, among which the main body includes: a substrate having a first main surface, a second main surface and a through hole vertically penetrating the first main surface and the second main surface; a first conductive portion and a second conductive portion provided on the first main surface; a resistor body connected thereto; an electrode positioned closer to the through hole than the resistor body; and a third conductive portion (i) provided on each of the second main surface and a partition wall surface for partitioning the through hole and (ii) connected to the electrode, and the rotating part includes: an opposing part rotatable in a circumferential direction; and a slider configured to conductively slide as the rotating part rotates.

A variable resistor according to the present invention includes a substrate, a resistive element disposed on a first surface of the substrate, oil that coats an upper surface of the resistive element, and a slide member that slides on the upper surface of the resistive element coated with the oil, wherein an output of the variable registor changes as a position at which the slide member makes contact with the resistive element changes. The variable resistor further includes an oil repellent part that surrounds at least a part of the resistive element in plan view viewed from above the first surface of the substrate, the oil repellant part having surface free energy smaller than that of the resistive element, whereby oil can be stably held on a resistive element surface without forming irregularities on the resistive element surface.

A variable resistor according to the present invention includes a substrate, a resistive element disposed on a first surface of the substrate, oil that coats an upper surface of the resistive element, and a slide member that slides on the upper surface of the resistive element coated with the oil, wherein an output of the variable registor changes as a position at which the slide member makes contact with the resistive element changes. The variable resistor further includes an oil repellent part that surrounds at least a part of the resistive element in plan view viewed from above the first surface of the substrate, the oil repellant part having surface free energy smaller than that of the resistive element, whereby oil can be stably held on a resistive element surface without forming irregularities on the resistive element surface.

Provided are a movable contact, a variable resistor, and a method for manufacturing a movable contact that can suppress a cost increase. The movable contacts are spaced apart from each other. The variable resistor, having a resistor, an electrode and the movable contact, comprises: a first wire rod group which has a plurality of first wire rods made of a precious metal and in which the plurality of first wire rods are arranged along the resistor; a second wire rod group which has a plurality of second wire rods made of a metal other than the precious metal and in which the plurality of second wire rods are arranged along the electrode; and a shaft-shaped member which is disposed to cross the first wire rod group and the second wire rod group and is welded to the first wire rod group and the second wire rod group.

A rotary electronic component capable of reducing an abrasion and a metal fatigue of a slider and extending a rotation life time compared to the conventional technology. A rotary electronic component is provided with a buffer member between a sliding portion of a slider and a rotor. Thus, the sliding portion is energized toward the annular electrode with a proper elastic force and the sliding portion is held. Because of this, vibration of the sliding portion is suppressed and metal fatigue of the slider can be reduced. Furthermore, since the lubricant is impregnated into the buffer member and a part of the buffer member is in contact with the annular electrode, the lubricant can be applied on the annular electrode. Consequently, the sliding portion slides smoothly and the abrasion of the contact portion can be further reduced. In addition, since the buffer member functions to wipe the surface of the annular electrode, foreign substances such as dust on the annular electrode are collected. Thus, harmful effect to the contact portion by the foreign substances can be prevented. By the above described configurations, the rotary electronic component of the present invention can obtain the extended life time and high operation reliability.

A rotary variable resistor includes an insulating substrate, a resistor pattern and a current collector pattern that are provided on the insulating substrate, a rotor that is mounted on the insulating substrate in a rotatable manner, and a slider that is mounted on the rotor and makes sliding contact with the resistor pattern and the current collector pattern to cause the resistor pattern and the current collector pattern to be conducted to each other. When a maximum dimension of the resistor pattern, which defines a variable resistor, is Z [mm] and electric linearity is L [%], Z≦4.0 and Z×L<10 are satisfied.

A rotary variable resistor includes an insulating substrate, a resistor pattern and a current collector pattern that are provided on the insulating substrate, a rotor that is mounted on the insulating substrate in a rotatable manner, and a slider that is mounted on the rotor and makes sliding contact with the resistor pattern and the current collector pattern to cause the resistor pattern and the current collector pattern to be conducted to each other. When a maximum dimension of the resistor pattern, which defines a variable resistor, is Z [mm] and electric linearity is L [%], Z≦4.0 and Z×L<10 are satisfied.

A locking mechanism for a control device which utilizes rotation motion of a shaft as a means of actuation, such as a potentiometer. The locking mechanism includes a tubular body, an actuation shaft, a plurality of splines, a plurality of spline-receiving cavities, and a push-lock mechanism. The actuation shaft transfers rotation motion from a user to the control device and is slidably and rotatably positioned within the tubular body. The splines are radially distributed about the actuation shaft to interlock with the plurality of spline-receiving cavities. The spline-receiving cavities are radially positioned around the tubular body with each cavity traversing into the tubular body from an inner surface. The push-lock mechanism locks the actuation shaft relative to the tubular body and is mounted offset to a second end of the tubular body. An output coupling end of the actuation shaft is bistably coupled to the push-lock mechanism.

A locking mechanism for a control device which utilizes rotation motion of a shaft as a means of actuation, such as a potentiometer. The locking mechanism includes a tubular body, an actuation shaft, a plurality of splines, a plurality of spline-receiving cavities, and a push-lock mechanism. The actuation shaft transfers rotation motion from a user to the control device and is slidably and rotatably positioned within the tubular body. The splines are radially distributed about the actuation shaft to interlock with the plurality of spline-receiving cavities. The spline-receiving cavities are radially positioned around the tubular body with each cavity traversing into the tubular body from an inner surface. The push-lock mechanism locks the actuation shaft relative to the tubular body and is mounted offset to a second end of the tubular body. An output coupling end of the actuation shaft is bistably coupled to the push-lock mechanism.