Abstract: This spring used for a suspension device for a vehicle is provided with: a metal wire material which constitutes a spring section and which has a cover layer provided on the surface thereof; and a seat section which is subjected to a load acting on the spring section, is formed from an elastically deformable material, has a groove section into which the wire material fits, and is bonded to the wire material by an adhesive. The minimum thickness of the portion of the adhesive, which protrudes from the groove section, is greater than or equal to the thickness of an adhesion layer formed in the groove section.

Abstract: This spring used for a suspension device for a vehicle is provided with: a metal wire material which constitutes a spring section and which has a cover layer provided on the surface thereof; and a seat section which is subjected to a load acting on the spring section, is formed from an elastically deformable material, and is bonded to the cover layer by an adhesive. The difference between the hardness of the seat section and the hardness of the adhesive is greater than the difference between the hardness of the adhesive and the hardness of the cover layer.

Abstract: Disclosed is a spring for a suspension device for a vehicle. The spring includes: a spring section made of a coil-shaped wire; and a seat section made of an elastically deformable material, brought into contact with a seat turn section of the spring section, and bearing load acting on the spring section. When a direction orthogonal to a direction of the load acting on the spring section is set as a widthwise direction, at least a part of the seat section is provided with a movable region support section having a widthwise dimension less than or equal to predetermined times a diameter dimension of the wire.

Abstract: This spring used for a suspension device for a vehicle is provided with: a metal wire material which constitutes a spring section and which has a cover layer provided on the surface thereof; and a seat section which is subjected to a load acting on the spring section, is formed from an elastically deformable material, has a groove section into which the wire material fits, and is bonded to the wire material by an adhesive. The minimum thickness of the portion of the adhesive, which protrudes from the groove section, is greater than or equal to the thickness of an adhesion layer formed in the groove section.

Abstract: A terminal supporting apparatus is provided with: a hub that is attached to an end of the outer cable and is provided with a flange on an outer periphery; a cushion member that is provided to surround the outer periphery of the hub and abuts on the flange at both a front surface and a back surface of the flange; and a housing that houses the cushion member. The cushion member includes a large-diameter portion that abuts on the flange. At least within a range contacting with the hub, at least a part of an outer peripheral surface of the large-diameter portion is fixed to an inner surface of the housing, while a clearance is formed between the cushion member and the inner surface of the housing over an entire region of an end surface of the large-diameter portion in a cable axis direction.

Abstract: A terminal supporting apparatus is provided with: a hub that is attached to an end of the outer cable and is provided with a flange on an outer periphery; a cushion member that is provided to surround the outer periphery of the hub and abuts on the flange at both a front surface and a back surface of the flange; and a housing that houses the cushion member. The cushion member includes a large-diameter portion that abuts on the flange. At least within a range contacting with the hub, at least a part of an outer peripheral surface of the large-diameter portion is fixed to an inner surface of the housing, while a clearance is formed between the cushion member and the inner surface of the housing over an entire region of an end surface of the large-diameter portion in a cable axis direction.

Abstract: A terminal supporting apparatus is provided with: a hub that is attached to an end of the outer cable and is provided with a flange on an outer periphery; a cushion member that is provided to surround the outer periphery of the hub and abuts on the flange at both a front surface and a back surface of the flange; and a housing that houses the cushion member. The cushion member includes a large-diameter portion that abuts on the flange. At least within a range contacting with the hub, at least a part of an outer peripheral surface of the large-diameter portion is fixed to an inner surface of the housing, while a clearance is formed between the cushion member and the inner surface of the housing over an entire region of an end surface of the large-diameter portion in a cable axis direction.

Abstract: A terminal supporting apparatus is provided with: a hub that is attached to an end of the outer cable and is provided with a flange on an outer periphery; a cushion member that is provided to surround the outer periphery of the hub and abuts on the flange at both a front surface and a back surface of the flange; and a housing that houses the cushion member. The cushion member includes a large-diameter portion that abuts on the flange. At least within a range contacting with the hub, at least a part of an outer peripheral surface of the large-diameter portion is fixed to an inner surface of the housing, while a clearance is formed between the cushion member and the inner surface of the housing over an entire region of an end surface of the large-diameter portion in a cable axis direction.

Abstract: A spiral spring for reducing maximum stress value and variations in stress distribution. The spiral spring is elastically deformable from a minimally to maximally deformed state. In maximally deformed state, the spiral spring includes a non-contact section, wherein at least some spring material portions are adjacent in radial direction not contacting each other, and a contact section, wherein all spring material portions are adjacent in radial direction contacting each other. An inner reference portion is corresponding to a central angle of 80° or more and 160° or less about a spiral center along a direction of spiral portion extension with a reference line connecting the spiral center and outer contact portion, wherein the outer end portion and outer fixing member contact in maximally deformed state, the inner reference portion being on a radially spiral portion inner side. The contact section is on a radially inner reference portion outer side.

Abstract: A terminal supporting apparatus 10 supports at least one of two ends of a control cable having an inner cable and an outer cable. The terminal supporting apparatus 10 includes: a hub 12 attached to an end of the outer cable, and having a flange on an outer periphery thereof; a cushion member 14 disposed to surround the outer periphery of the hub, and being in contact with the flange at both a front surface and a rear surface of the flange; and a housing 17 having a housing part that houses the cushion member. When an angle formed between an axis of the housing part and an axis of the hub is varied in a range of 0.0° to 6.0°, a diagonal static spring constant of the cushion member in an axial direction thereof may be in a range of 350 to 600 N/mm.

Abstract: The present invention provides a method for predicting a routing arrangement for control cable without preparing experimental control cables. In the method according to the present invention, characteristics of a control cable to be laid are obtained (S1, S2, and S3). The characteristics of the control cable can be obtained by subjecting a test piece of control cable to a known test (tensile test). Next, a length of the control cable and a condition for connecting the control cable are provided as conditions for a computation (S4 and S5). Then, the given length of the cable, the given condition for connecting the cable, and the obtained characteristic of the control cable are used for a computation model, which was formed by dividing the control cable into a plurality of elements, in order to perform a finite element method, and, thus, a routing arrangement is calculated (S7).

Abstract: The present invention provides a method for predicting a routing arrangement for control cable without preparing experimental control cables. In the method according to the present invention, characteristics of a control cable to be laid are obtained (S1, S2, and S3). The characteristics of the control cable can be obtained by subjecting a test piece of control cable to a known test (tensile test). Next, a length of the control cable and a condition for connecting the control cable are provided as conditions for a computation (S4 and S5). Then, the given length of the cable, the given condition for connecting the cable, and the obtained characteristic of the control cable are used for a computation model, which was formed by dividing the control cable into a plurality of elements, in order to perform a finite element method, and, thus, a routing arrangement is calculated (S7).