A damping device (1) for a suspension (100) of a bicycle includes: a first tubular body (2) defining a first chamber (4); a second tubular body (3) defining a second chamber (5) fluidically communicating with the first chamber (4); a third tubular body (8) disposed inside the second chamber (5), the interior thereof defining a third chamber (9) fluidically communicating with the second chamber (5); a hollow stem (10) integral with the first tubular body (2), defining a through cavity (11) which establishes a fluid communication between the third chamber (9) and the first chamber (4); a first static valve (12) disposed between the second chamber (5) and the third chamber (9); a second static valve (14), connected to the stem (10), operatively disposed between the third chamber (9) and the cavity (11) of the stem (10); a dynamic valve (15) connected to the first tubular body (2) inside the first chamber (4), operatively disposed between the cavity (11) of the stem (10) and the first chamber (4).

An electronic modal base valve is disclosed. The electronic modal base valve includes a motive component, a controller communicatively coupled with the motive component, and a control valve coupled with the motive component. The controller is configured to control an operation of the motive component, wherein a movement of the motive component is configured to cause the control valve to adjust a flow rate for a flow path through the electronic modal base valve.

A shock absorber includes a hard-side damping element for applying resistance to a flow of liquid from a compression side chamber to an extension side chamber, a solenoid valve capable of changing an opening area of a compression side bypass passage for communicating the compression side chamber and the extension side chamber by bypassing the hard-side damping element, and a soft-side damping element provided in the compression side bypass passage in series with the solenoid valve. The hard-side damping element has an orifice and a leaf valve provided in parallel with the orifice. The soft-side damping element has an orifice having an opening area larger than that of the orifice.

A shock absorber includes a hard side damping element that imparts a resistance to a flow of liquid moving between an extension side chamber and a compression side chamber, a solenoid valve configured to change an aperture area of a bypass passage that bypasses the hard side damping element and communicates with the extension side chamber and the compression side chamber, a soft side damping element provided in series with the solenoid valve in the bypass passage, and a tank connected to the compression side chamber. The hard side damping element includes an orifice and leaf valves provided in parallel with the orifice. The soft side damping element includes an orifice having a larger aperture area than the orifice.

A valve mechanism includes: a cylindrical body; a plurality of valve bodies; and a drive valve. The drive valve includes a shaft portion having a flow path penetrating in the axial direction, and a first step portion extending from an outer peripheral surface of the shaft portion to a radial outside of the shaft portion. The shaft portion has a protrusion portion protruding further toward the cylindrical body side than the first step portion and a base portion extending to a side opposite to the protrusion portion with respect to the first step portion. A gap between the valve bodies is changed by elastically deforming an inner peripheral portion of the valve body, which comes into contact with the drive valve moved in a direction approaching the valve body, in a direction approaching the cylindrical body with respect to an outer peripheral portion of the valve body.

Systems and devices to control linear, rotational, and/or arcuate motion are provided herein. In some examples, a pin system is configured for insertion in a door and/or door jamb, and to control motion of the door, such as a speed with which the door closes. In some examples, a hinge pin is configured to replace a conventional hinge pin and to control motion of the door. In some examples, a hinge system is configured to replace a conventional door hinge and to control motion of the door.

Systems and devices to control linear, rotational, and/or arcuate motion are provided herein. In some examples, a pin system is configured for insertion in a door and/or door jamb, and to control motion of the door, such as a speed with which the door closes. In some examples, a hinge pin is configured to replace a conventional hinge pin and to control motion of the door. In some examples, a hinge system is configured to replace a conventional door hinge and to control motion of the door.

Systems and devices to control linear, rotational, and/or arcuate motion are provided herein. In some examples, a pin system is configured for insertion in a door and/or door jamb, and to control motion of the door, such as a speed with which the door closes. In some examples, a hinge pin is configured to replace a conventional hinge pin and to control motion of the door. In some examples, a hinge system is configured to replace a conventional door hinge and to control motion of the door.

A damping device (1) for a suspension (100) of a bicycle includes: a first tubular body (2) defining a first chamber (4); a second tubular body (3) defining a second chamber (5) fluidically communicating with the first chamber (4); a third tubular body (8) disposed inside the second chamber (5), the interior thereof defining a third chamber (9) fluidically communicating with the second chamber (5); a hollow stem (10) integral with the first tubular body (2), defining a through cavity (11) which establishes a fluid communication between the third chamber (9) and the first chamber (4); a first static valve (12) disposed between the second chamber (5) and the third chamber (9); a second static valve (14), connected to the stem (10), operatively disposed between the third chamber (9) and the cavity (11) of the stem (10); a dynamic valve (15) connected to the first tubular body (2) inside the first chamber (4), operatively disposed between the cavity (11) of the stem (10) and the first chamber (4).

A valve mechanism includes: a cylindrical body; a plurality of valve bodies; and a drive valve. The drive valve includes a shaft portion having a flow path penetrating in the axial direction, and a first step portion extending from an outer peripheral surface of the shaft portion to a radial outside of the shaft portion. The shaft portion has a protrusion portion protruding further toward the cylindrical body side than the first step portion and a base portion extending to a side opposite to the protrusion portion with respect to the first step portion. A gap between the valve bodies is changed by elastically deforming an inner peripheral portion of the valve body, which comes into contact with the drive valve moved in a direction approaching the valve body, in a direction approaching the cylindrical body with respect to an outer peripheral portion of the valve body.