JP6316029B2 - Drag device, fishing reel having the same, and drag device unit - Google Patents

Description

  The present invention relates to a drag device, a fishing reel including the drag device, and a drag device unit, and more particularly, a drag device that brakes rotation of a spool around which a fishing line is wound, a fishing reel including such a drag device, and the like. The present invention relates to a drag device unit used in a drag device.

  2. Description of the Related Art Conventionally, a fishing reel has been provided with a drag mechanism that idles a spool in order to avoid breakage of the line when excessive tension is applied to the line to be wound. In such a drag mechanism, in general, it is possible to adjust a tension (drag force) which is a threshold value at which the spool idles. For example, the operator adjusts the drag force when the thickness of the fishing line to be wound is changed or when it is desired to change the relationship between the tension applied to the fishing line and the amount of withdrawal of the fishing line. It is convenient if the operator can confirm the magnitude of the adjusted drag force. There is a disclosed example of a mechanism for presenting the magnitude of such drag force to the operator. For example, Patent Document 1 discloses that a pressing force of an adjustment knob for adjusting a drag force is detected by a pressure sensor and the detected pressing force is displayed. Patent Document 2 discloses providing a visual recognition unit for visually recognizing the position of a nut member that rotates in accordance with an operation of a drag operation tool for adjusting the drag force.

JP 61-132129 A 4-120471

  However, since the apparatus disclosed in Patent Document 1 uses a pressure sensor to detect the drag force, electric parts such as a power source are required, making it difficult to reduce the number of parts and requiring waterproofing measures. Further, in the device disclosed in Patent Document 2, the moving direction of the nut member is the rotation axis direction of the spool, and this rotation axis direction is the depth direction as viewed from the operator who operates the drag operation tool. It is difficult for the operator to visually recognize the position of the moving nut member. Furthermore, in the apparatus disclosed in Patent Document 2, it is difficult to accurately check the magnitude of the drag force when the amount of movement of the nut member is small.

  An object of the embodiment of the present invention is to make it easy to visually recognize the magnitude of the drag force without using an electrical component. Other objects of the embodiments of the present invention will become apparent by referring to the entire specification.

  A drag device according to an embodiment of the present invention is a drag device that brakes rotation of a spool around which a fishing line is wound, and moves in a first direction according to an operation by an operator, and the spool is moved by the movement. A change member that changes a braking force against the second direction, and at least a part of the change member that is visible to the operator, and a second direction that is different from the first direction according to the change in the braking force by the change member A moving member that displays the braking force by moving in a straight line.

  In the drag device according to the embodiment described above, an operation member having a visual recognition unit that moves the change member in response to an operation by the operator and makes at least a part of the motion member visible to the operator. It can also be set as the aspect provided.

  In the drag device according to the above-described embodiment, a friction member that applies the braking force to the spool, and a biasing member that generates a biasing force against the friction member in accordance with a displacement amount in the first direction. Further, the change member may change the displacement amount by the movement, and the motion member may display the displacement amount by moving according to the change of the displacement amount. In the drag device according to this aspect, the drag device further includes a pressing member that is provided between the friction member and the biasing member and presses the friction member in accordance with the biasing force of the biasing member, The displacement amount may be changed by moving in the first direction and compressing the urging member with the pressing member.

  The fishing reel which concerns on one Embodiment of this invention is equipped with the drag apparatus which concerns on one Embodiment of this invention mentioned above.

  A drag device unit according to an embodiment of the present invention is a unit used in a drag device that brakes rotation of a spool around which a fishing line is wound, and moves in a first direction in response to an operation by an operator. A change member that changes the braking force applied to the spool by the movement, and at least a part of the change member that is visible to the operator, and the first direction according to the change in the braking force by the change member. Includes a moving member that displays the braking force by moving in different second directions.

  According to various embodiments of the present invention, the magnitude of the drag force can be easily visually recognized without using an electrical component.

The disassembled perspective view which shows the components structure of the drag apparatus 100 which concerns on one Embodiment. The disassembled perspective view seen from the opposite side to FIG. Sectional drawing of the drag apparatus 100 after an assembly. Sectional drawing of the drag apparatus 100 of the state which made drag force large compared with the state of FIG. The disassembled perspective view which shows the components structure of the drag apparatus 300 which concerns on other embodiment. The disassembled perspective view seen from the opposite side to FIG. Sectional drawing (A) of the drag apparatus 300 after an assembly, and the front view (B) which looked at the drag apparatus 300 after an assembly from the axial direction. Sectional view (A) of the drag device 300 in a state where the drag force is increased compared to the state of FIG. 7 and a front view of the drag device 300 in the state where the drag force is increased compared to the state of FIG. Figure (B).

  Hereinafter, various embodiments of the present invention will be described with reference to the drawings as appropriate. In addition, the same referential mark is attached | subjected to the common component in drawing.

  First, a drag device 100 according to an embodiment of the present invention will be described with reference to FIGS. 1 to 4. A drag device 100 according to an embodiment of the present invention is used for a fishing spinning reel and brakes rotation of a spool of the reel. 1 to 4 show a drag device 100 for a fishing spinning reel. 1 is an exploded perspective view showing a component configuration of the drag device 100, FIG. 2 is an exploded perspective view seen from the side opposite to FIG. 1, and FIG. 3 is a sectional view of the drag device 100 after assembly. FIG. 4 is a cross-sectional view of the drag device 100 in a state where the drag force is increased as compared with the state of FIG. In this specification, when it says simply an axial direction, a circumferential direction, a radial direction, and a rotation direction, it means the direction on the basis of the spool axis | shaft 101 mentioned later, and when it says up and down, the top in FIG.3 and 4 and Means below.

  The illustrated drag device 100 is accommodated in a recess provided above the spool 102. The drag device of the present invention can be widely applied to general fishing spinning reels. Fishing spinning reels typically include a reel body that supports a handle and a rotor. When the operator rotates the handle in such a fishing spinning reel, the rotation of the handle is transmitted to the rotor through the rotation transmission mechanism, whereby the fishing line guided by the bail arm provided in the rotor is spool 102. Is wound around the thread winding portion 1021. Many fishing spinning reels include an oscillating mechanism that reciprocates the spool shaft 101 in the front-rear direction in accordance with the rotation of the rotation transmission mechanism. Since the spool 102 is mounted in front of the spool shaft 101, when the fishing line is wound according to the rotation of the handle, the spool can be reciprocated back and forth by the oscillating mechanism. The fishing line can be evenly wound around 1021.

  The spool shaft 101 according to the embodiment includes a main body portion (reference numeral omitted) having the largest diameter, a spool support portion 1011 having a smaller diameter than the main body portion and extending upward, and a diameter smaller than the spool support portion 1011. And extending in the upward direction and having an external thread portion 1012 formed with a screw on the outer peripheral surface. The spool 102 includes a bobbin winding portion 1021 around which a fishing line is wound, a shaft portion 1022 provided inside the bobbin winding portion 1021 and having a substantially cylindrical shape, and a substantially disc shape and a diameter from the upper end of the shaft portion 1022. A wall portion 1023 that extends in the direction and connects to the inner wall of the bobbin portion 1021. The spool 102 is rotatably supported on the spool support portion 1011 of the spool shaft 101 via the shaft portion 1022. As a result, the spool 102 can rotate with respect to the spool shaft 101.

  As shown in the figure, a recess is provided above (front) the spool 102, and as described above, the drag device 100 is accommodated in this recess. Hereinafter, the drag device 100 will be described in detail. As shown in FIGS. 1 to 4, the drag device 100 includes a friction member 103 that applies a braking force to the spool 102, and the friction member 103 according to the amount of displacement of the spool shaft 101 in the axial direction (first direction). A biasing spring (biasing member) 104 that generates a biasing force against the nut, and a nut (changing member) that moves in the axial direction of the spool shaft 101 in accordance with an operation by the operator and changes the displacement amount of the biasing spring 104 by the movement ) 105, a pressing member 106 provided between the friction member 103 and the biasing spring 104 and pressing the friction member 103 according to the biasing force of the biasing spring 104, and the nut 105 is moved according to an operation by the operator The operating member 107 to be operated and at least a part of the operating member 107 are provided at a position where the operator can visually recognize the spool. And a slider (moving member) 108 for displaying the displacement amount by moving (linear motion) in the direction of the axial direction substantially perpendicular to the 1, functions as a drag device for braking rotation of the spool 102.

  In one embodiment, the friction member 103 has a substantially disk shape and is disposed on the upper surface of the wall portion 1023 of the spool 102. On the inner peripheral surface of the friction member 103, a slit is formed that is non-rotatably locked to a chamfered portion formed on the outer periphery of the male screw portion 1012. In this way, the friction member 103 is prevented from rotating with respect to the male screw portion 1012 (that is, with respect to the spool shaft 101). When the friction member 103 presses the wall portion 1023, a braking force can be applied to the rotating spool 102. Here, the friction member 103 has a relatively high friction coefficient, a small change in the friction coefficient with respect to changes in wear and pressing force, a small difference between the dynamic friction coefficient and the static friction coefficient, etc. It is desirable to have characteristics. In addition, the drag device 100 in one embodiment can include a plurality of friction members 103. In this case, a washer (not shown) may be provided between the plurality of friction members 103 so as not to rotate with respect to the spool shaft 101. According to this configuration, the spool 102 can be braked by the friction generated between the plurality of friction members 103 and the washer, so that a larger frictional force can be applied to the spool than when only one friction member 103 is provided. .

  The urging spring 104 in one embodiment is a compression spring formed in a coil shape. For example, a linear spring in which the urging force increases linearly with respect to a displacement amount (compression amount) can be used. In one embodiment, the biasing spring 104 is disposed between the nut 105 and the pressing member 106.

  The nut 105 includes a plate-like plate-like portion (reference numeral omitted) having a hexagonal radial cross section, and extends downward from the plate-like portion, and a female screw is formed on the inner peripheral surface. A spring holding portion 1052 provided on the lower surface of the plate-like portion and coming into contact with one end portion (upper end portion) of the biasing spring 104; and a plate plate having a substantially right triangle protruding upward from the plate-like portion. And a cam portion 1053. When the nut 105 is rotated relative to the spool shaft 101, the female screw portion 1051 and the male screw portion 1012 of the spool shaft 101 are screwed together, and the nut 105 moves in the axial direction. Further, a known rotation prevention mechanism (not shown) is provided between the nut 105 and the spool shaft 101, and relative rotation between the nut 105 and the spool shaft 101 is prevented except when adjusting the drag force. ing. An operator can unlock the rotation prevention mechanism and rotate the nut 105. In the present embodiment, the moving direction of the nut 105 is an axial direction coaxial with the spool shaft 101. Thus, by attaching the nut 105 to the spool shaft 101, it can also serve as an attachment member for the spool 102. However, the embodiment of the present invention is not limited to this configuration, and the moving direction of the nut 105 (that is, the urging direction of the attached spring 104) may be any direction as long as a braking force is applied to the spool 102. Can do.

  A cam groove extending in the radial direction is formed at the upper end of the cam portion 1053 of the nut 105. Although described in detail later, the cam portion 1053 can transmit (convert) the movement of the nut 105 in the axial direction to the movement of the slider 108 in the radial direction. The cam portion 1053 is disposed so that the shaft extending along the cam groove is included in a plane constituted by the axial direction that is the moving direction of the nut 105 and the radial direction that is the moving direction of the slider 108. In one embodiment, the cam portion 1053 is formed in a substantially right triangle plate shape, and the cam groove is formed in a substantially linear shape on the inclined side of the cam portion 1053. The cam groove formed in this way is inclined at a predetermined angle with respect to the radial direction.

  The pressing member 106 has a substantially cylindrical shape that opens upward. The pressing member 106 contacts the other end (lower end) of the biasing spring 104 on the upper surface of the bottom, and the biasing force from the biasing spring 104 on the lower surface of the bottom. In response, the friction member 103 is pressed.

  In one embodiment, the operation member 107 is formed in a substantially disc shape. The operation member 107 is provided on the outermost side (upper side) of the drag device 100 so that the operation of the operator can be easily accepted and can be easily recognized by the operator during the operation. In one embodiment, the operation member 107 is operated by an operator, a pressing member fixing portion 1071 fitted in an opening formed on a side surface of the pressing member 106, a nut support portion 1072 that supports the nut 105, and the operator. It has an operation knob 1073 and a visual recognition part 1074 that can visually recognize a part of a slider 108 described later. The nut support portion 1072 is formed so that its inner wall is along two sides of the plate-like portion of the nut 105 formed in a hexagon shape. Therefore, when the operation member 107 rotates, the nut 105 is spooled together with the operation member 107. While rotating with respect to the shaft 101, the female screw portion 1051 and the male screw portion 1012 of the spool shaft 101 can be moved in the axial direction as well. The operation knob 1073 is provided on the upper surface of the operation member 107 so as to have a shape extending in the radial direction. The visual recognition part 1074 has a substantially linear slit S1 provided in the operation knob 1073 and extending in the radial direction. The slit S1 is formed to extend along the cam groove of the cam portion 1053 of the nut 105. Scales D1 for facilitating confirmation of the position of the slider 108 are attached to both sides of the slit.

  The slider 108 includes a box-shaped main body (reference number omitted) in which a plate-like upper wall and a bottom wall extending along the slit S1 formed in the operation knob 1703 are connected by a pair of side walls, It has a cam follower 1081 protruding downward in the radial direction from the bottom wall, a protrusion (indicating portion) 1082 protruding upward from the upper wall of the main body, and guide holes 1083 provided in both side walls of the main body. The slider 108 is disposed between the nut 105 and the operation member 107 so that the cam follower 1081 engages with the cam portion 1053 of the nut 105 and the protrusion 1082 is received in the slit S1 of the operation knob 1073.

  The guide member 109 is a rod-like member extending in the radial direction, and is fixed along the operation knob 1073 inside the operation member 107. Specifically, the guide member 109 is inserted into a set of insertion holes provided at the edge of the operation member 107. The insertion hole is formed at a position where the longitudinal direction of the guide member 109 coincides with the extending direction of the slit S1. The slider 108 is supported by the operating member 107 so as to be able to go straight in the radial direction along the slit S1 by inserting the guide member 109 through the guide hole 1083 provided in the side wall thereof.

  Since the slider 108 is provided between the nut 105 and the operation member 107 as described above, the cam follower 1081 engages and is guided by the cam portion 1053 of the nut 105, whereby the axial direction of the nut 105 is reached. Is converted into a radial movement of the slider 108. In other words, the motion conversion mechanism that converts the axial movement of the nut 105 into the radial movement of the slider 108 is realized by the cam portion 1053 of the nut 105 and the cam follower 1081 of the slider 108.

  Next, the operation of the drag device 100 thus configured will be described. First, an operation for braking the rotation of the spool 102 will be described, and then an operation for displaying the magnitude of the drag force will be described. The drag mechanism realized by the drag device 100 according to the embodiment includes a frictional force that acts between the friction member 103 and the spool 102 by pressing the friction member 103 fixed to the spool shaft 101 against the spool 102. Thus, the spool 102 is braked. While the tension T acting on the fishing line wound around the spool 102 is small, the spool 102 does not rotate with respect to the spool shaft 101 due to the static frictional force acting from the friction member 103, but this tension T exceeds a predetermined threshold Tmax. When this happens, the spool 102 rotates relative to the spool shaft 101. At this time, a dynamic friction force acts on the spool 102. In this manner, the drag mechanism realized by the drag device 100 can prevent a force exceeding a predetermined force (Tmax force) from acting on the fishing line, thereby preventing the fishing line from being cut. .

  Adjustment of the frictional force acting between the friction member 103 and the spool 102 is performed by rotating the operation member 107 and moving the nut 105 in the axial direction of the spool shaft 101, whereby the displacement amount (compression) of the urging spring 104 is compressed. This is realized by changing the amount). Adjustment of the frictional force acting on the spool 102 will be further described with reference to FIG. As shown in FIG. 4, the displacement amount of the biasing spring 104 is x, the spring constant of the biasing spring 104 is k, the coefficient of friction between the friction member 103 and the wall 1023 of the spool 102 is μ, the friction member 103 The diameter (equivalent friction radius) corresponding to 1/2 of the equivalent friction diameter is R1, and the winding radius of the fishing line is R2. The frictional force F acting on the spool 102 from the friction member 103 is F = μkx according to Coulomb's law of friction. The maximum torque M generated in the spool 102 is M = R1 × F = R1 μkx, and the tension Tmax at which the spool 102 starts to rotate relative to the spool shaft 101 is Tmax = M / R2 = R1 μkx / R2. In this way, the tension Tmax at which the spool 102 starts to rotate relative to the spool shaft 101 can be adjusted by changing the displacement amount x of the urging spring 104 by moving the nut 105 in the axial direction. Note that the fishing line winding radius R <b> 2 means the distance from the axis of the spool shaft 101 to the surface of the fishing line wound around the spool 102.

  Next, an operation for displaying the magnitude of the drag force will be described. When the operation member 107 is rotated to adjust the drag force, the nut 105 moves in the axial direction of the spool shaft 101 as described above. When the drag force is increased, the nut 105 is moved downward in the axial direction. Conversely, when the drag force is decreased, the nut 105 is moved upward in the axial direction. At this time, since the pressing member 106 whose lower surface is in contact with the friction member 103 is restricted from moving downward in the axial direction, the nut 105 and the pressing member 106 are moved in accordance with the movement of the nut 105 in the vertical direction. The amount of displacement of the urging spring 104 disposed between the two changes, and the drag force acting on the spool 102 changes accordingly. On the other hand, when the nut 105 moves in the vertical direction, the slider 108 engaged with the cam groove via the cam follower 1081 along the cam groove of the cam portion 1053 provided in the nut 105 as described above. Move in the radial direction. As described above, when the nut 105 moves in the axial direction according to the rotation operation to the operation member 107 (that is, when the distance between the nut 105 and the pressing member 106 changes), according to the displacement amount of the biasing spring 104, The drag force acting on the spool 102 and the radial position of the slider 108 change. For example, when the operator rotates the operation knob 1073 of the operation member 107 in a predetermined direction, the nut 105 is rotated relative to the spool shaft 101 and screwed downward in the axial direction, and the biasing spring 104 is compressed in the axial direction. . At this time, the cam follower 1081 is pushed out in the radial direction (left-right direction in FIGS. 3 and 4) by the action of the cam portion 1051, and the slider 108 is pushed in the radial direction (from the position shown in FIG. 3 to the position shown in FIG. 4). Go to). At this time, the operator can confirm the magnitude of the drag force by visually recognizing the position of the protrusion 1082 moving in the slit S1 of the visual recognition portion 1074 of the operation member 107.

  Here, if the displacement amount of the urging spring is x and the angle of inclination with respect to the radial direction of the cam groove of the cam portion 1051 is θ, the moving distance y of the slider 108 can be expressed as y = x / Tan θ. . Therefore, if θ is set to be less than 45 °, the radial movement distance y of the slider 108 (protrusion 1082) can be made larger than the change width of the displacement amount of the biasing spring 104. Can be further improved. That is, as θ becomes smaller, the moving distance in the radial direction of the slider 108 with respect to the change in the unit amount of the drag force can be increased. On the other hand, if θ is made too small, the slider 108 will not move smoothly unless the friction coefficient between the cam portion 1051 and the cam follower 1081 is made sufficiently small. Therefore, it is desirable to set θ to 5 ° or more.

  In the drag device 100 according to the embodiment described above, the slider 108 that displays the displacement amount by moving in the radial direction according to the change of the displacement amount of the biasing spring 104 is provided at a position that can be visually recognized by the operator. Yes. Therefore, since the magnitude of the drag force (the amount of displacement of the biasing spring 104) can be indicated by the radial position of the slider 108 (protrusion 1082), compared to the case indicated by the position of the member moving in the axial direction. The operator can more easily visually recognize the magnitude of the drag force. In addition, since no electrical parts are used, it is not necessary to provide a power source or the like, so that the entire apparatus can be saved, and waterproofness and reliability can be improved.

  As shown in the figure, the drag mechanism such as the drag device 100 is often housed in a recess formed at the axial end of the spool in order to save space. Therefore, the components constituting the drag mechanism are easy to see the direction seen from the rotation axis direction of the spool (the direction in which the recess for accommodating the drag mechanism is provided), and the drag mechanism is blocked by the spool from other directions. The components of are difficult to see. Furthermore, in general, the drag force is often adjusted by moving the drag force adjusting member (for example, the nut 105 in the above embodiment) in the axial direction. Since the movement direction of the drag force adjusting member is the depth direction, it is difficult to visually recognize this position. On the other hand, in the drag device 100 of one embodiment, the drag force can be shown at the position of the slider 108 that moves in the radial direction, and a part of the slider 108 (projection 1082) is disposed on the outermost side in the axial direction. Since the operation member 107 is exposed outward in the axial direction, the magnitude of the drag force can be easily recognized from the axial direction even when the drag mechanism is disposed in the spool.

  In the drag device 100 according to the embodiment, as described above, the radial position of the slider 108 is determined according to the amount of displacement of the biasing spring 104 (the distance between the nut 105 and the pressing member 106). The magnitude of the drag force can be displayed more accurately as compared with the case where it is determined according to the rotation amount of the member and the position of the nut on the spool shaft. For example, in a so-called drag-free state where the nut 105 is positioned near the upper end of the spool shaft 101 and the pressing member 106 is separated from the friction member 103, the biasing spring 104 is compressed even if the nut 105 moves downward in the axial direction. In addition, the slider 108 does not move. When the nut 105 further moves downward in the axial direction and the pressing member 106 presses the friction member 103, the biasing spring 104 is compressed and the slider 108 moves. As described above, in the drag device 100 according to the embodiment, since the movement of the slider 108 is started after the urging spring 104 starts compression, the operator does not operate in a state where the drag force is applied. A state can be distinguished and recognized. On the other hand, when the slider is moved according to the rotation amount of the operation member and the position of the nut on the spool shaft, the slider moves regardless of whether the biasing spring is compressed. It cannot be recognized.

  In general, the friction member 103 is often formed of a material that is more likely to be deformed than the spool 102 and the nut 105, and further, because the member applies a braking force to the spool 102, wear is likely to occur. When the friction member 103 is worn, the pressing member 106 moves downward due to wear of the friction member 103 even if the position of the nut 105 on the spool shaft 101 is the same. It gets smaller. Therefore, when the drag force is displayed according to the position of the nut 105 on the spool shaft 101, the decrease in the displacement amount of the biasing spring 104 due to the wear of the friction member 103 is not reflected in the display of the drag force. On the other hand, in the drag device 100 according to the embodiment, the drag force is displayed according to the displacement amount of the biasing spring 104 (the distance between the nut 105 and the pressing member 106). The drag force corresponding to the amount of displacement of the spring 104 can be displayed.

  Further, in the drag device 100 according to the embodiment, by setting the angle θ at which the cam groove of the cam portion 1053 is inclined with respect to the radial direction to be less than 45 °, the moving distance of the slider 108 can be changed by the displacement of the biasing spring 104. The change width of the amount (relative movement distance of the nut 105 with respect to the pressing member 106) is larger. As a result, the magnitude of the drag force can be displayed with even better visibility.

  Furthermore, in the drag device 100 of one embodiment, the slider 108 that displays the magnitude of the drag force is disposed inside the operation member 107 (operation knob 1073) disposed on the outermost side. Therefore, the magnitude of the drag force can be displayed with good visibility without impairing the operability when adjusting the drag force, and the size of the apparatus can be suppressed.

  In one embodiment, the cam groove of the cam portion 1053 of the nut 105 is formed linearly, but the shape of the cam groove is not limited to this. For example, when the relationship between the displacement amount of the urging spring 104 and the urging force is not a proportional relationship, the relationship between the displacement amount of the urging spring 104 and the drag force is also a non-linear relationship. By forming the cam groove of the cam portion 1053 so as to have a corresponding shape, the movement of the slider 108 according to the drag force can be realized. In one embodiment, a cam mechanism called a “positive cam” in which the cam follower follows the cam regardless of the biasing force of the spring or the like is applied. However, the cam follower follows the cam by the biasing force of the spring or the like. It is also possible to apply a cam mechanism. Further, the motion conversion mechanism that converts the axial movement of the nut 105 into the radial movement of the slider 108 is not limited to the cam mechanism, and various mechanisms such as a gear mechanism and a link mechanism can be used. .

  Next, a drag device 300 according to another embodiment of the present invention will be described with reference to FIGS. FIG. 5 is an exploded perspective view showing a component configuration of the drag device 300, and FIG. 6 is an exploded perspective view seen from the side opposite to FIG. 7A is a cross-sectional view of the drag device 300 after assembly, and FIG. 7B is a front view of the drag device 300 after assembly viewed from the axial direction. FIG. FIG. 8 is a cross-sectional view of the drag device 300 in a state where the drag force is increased as compared with the state of FIG. 7, and FIG. 8B is a front view of the drag device 300 in this state viewed from the axial direction. . In addition, the same referential mark is attached | subjected to the component similar to the drag apparatus 100 which concerns on one Embodiment mentioned above, The detailed description is abbreviate | omitted suitably. Further, in the description of this embodiment, when simply referring to the top and bottom, it means the top and bottom in FIGS.

  As shown in FIGS. 5 to 8, the drag device 300 in this embodiment includes a friction member 103, a biasing spring (biasing member) 104, and an axial direction (first order) of the spool shaft 101 according to an operation by the operator. 1) and a biasing force of the biasing spring 104 provided between the friction member 103 and the biasing spring 104, and a nut (change member) 305 that changes the displacement amount of the biasing spring 104 by the movement. A pressing member 306 that presses the friction member 103 according to the operation, an operation member 307 that moves the nut 305 according to the operation by the operator, and at least a part of which is provided at a position that can be visually recognized by the operator. A rotating body (motion member) 308 that displays a displacement amount by rotating in a coaxial manner with the spool shaft 101 according to a change in the displacement amount of the urging spring 104 is provided. 5 and 6, illustration of the spool shaft 101, the spool 102, and the friction member 103 is omitted.

  In another embodiment, the nut 305 includes a plate-like plate-like portion (reference numeral omitted), and extends downward from the plate-like portion, and a female screw is formed on the inner peripheral surface. A spring retainer 3052 that is provided on the lower surface and contacts one end (upper end) of the biasing spring 104; a follower pin 3053 that protrudes upward from a position radially displaced from the center of the plate-like portion; Have When the nut 305 is rotated relative to the spool shaft 101, the female screw portion 3051 and the male screw portion 1012 of the spool shaft 101 are screwed together, and the nut 305 moves in the axial direction. Further, a known rotation prevention mechanism (not shown) is provided between the nut 305 and the spool shaft 101, and relative rotation between the nut 305 and the spool shaft 101 is prevented except when adjusting the drag force. ing. An operator can unlock the rotation prevention mechanism and rotate the nut 305. The follower pin 3053 of the nut 305 has a substantially cylindrical shape extending in the axial direction, and a spherical tip comes into contact with a cam surface 3081 of the rotating body 308 described later.

  The pressing member 306 has a substantially annular shape, contacts the other end (lower end) of the biasing spring 104 on the upper surface, and presses the friction member 103 on the lower surface according to the biasing force from the biasing spring 104. To do. A pair of press-fitting portions (reference numerals omitted) are provided at both ends of the upper surface of the pressing member 306.

  In another embodiment, the operation member 307 is formed in a substantially disc shape. The operation member 307 is provided on the outermost side (upper side) of the drag device 300 so that the operation of the operator can be easily accepted and can be easily recognized by the operator during the operation. In this embodiment, the operation member 307 includes a nut support portion 3072 that supports the nut 305, an operation knob 3073 that is operated by the operator, a visual recognition portion 3074 that allows a part of the rotating body 308 to be described later to be visually recognized, and a rotation. A rotating body support hole 3075 that rotatably supports the body 308 is provided. The nut support portion 3072 is composed of two rod-like members extending downward, and is inserted into a pair of insertion holes provided at both ends of the plate-like portion of the nut 305, and the tip thereof is the upper surface of the pressing member 306. It is press-fitted and held in the press-fitting part. Therefore, when the operation member 307 rotates, the nut 305 rotates with respect to the spool shaft 101 together with the operation member 307, and the female thread portion 3051 and the threaded portion 1012 of the spool shaft 101 are screwed together to axially move. Can also move. The operation knob 3073 has a shape extending in the radial direction on the upper surface of the operation member 307. The visual recognition unit 3074 has a fan-shaped slit S2 along the arc of one of the two semicircular regions separated by the operation knob 3073 on the upper surface of the operation member 307. A scale D2 for facilitating confirmation of the rotational position of the rotating body 308 is attached to the outside in the radial direction of the slit S2.

  The rotating body 308 includes a substantially cylindrical main body (reference numeral omitted), a cam surface 3081 formed as a spiral surface in a substantially semicircular region on the lower surface of the main body, and a radial direction from the side of the main body. A protrusion (indicating portion) 3082 that protrudes upward in the axial direction at the radial end portion of the extending plate-like member, and has a substantially cylindrical shape that protrudes upward from the upper surface of the main body portion and has a smaller diameter than the main body portion, and a spool shaft 101 has a shaft portion 3083 that is coaxial with 101, and a spring hook 3084 that protrudes upward at the base of a plate-like member provided with a projection 3082 at the radial end, and has a substantially cylindrical shape. The rotating body 308 is disposed between the nut 305 and the operation member 307 so that the cam surface 3081 contacts the follower pin 3053 of the nut 305 and the protrusion 3082 is received in the slit S2 of the operation knob 3073.

  The rotator biasing spring 310 is a torsion coil spring, and is arranged along the outer peripheral surface of the main body of the rotator 308, and one of the two arms extending linearly at both ends of the spring is operated. It is fixed on the lower surface of the member 307, and the other arm portion is in contact with the side surface of the spring hook 3084 of the rotating body 308 described above. The rotating body urging spring 310 provided in this manner applies a urging force in the rotational direction about the shaft portion 3083 to the rotating body 308.

  Since the rotating body 308 is applied with the urging force in the rotating direction as described above, the cam surface 3081 is guided by the follower pin 3053 of the nut 305, so that the axial movement of the nut 305 is performed in the rotating body 308. Is converted into a rotational motion. In other words, the follower pin 3053 of the nut 305 and the cam surface 3081 of the rotating body 308 realize a motion conversion mechanism that converts the axial movement of the nut 305 into the rotating motion of the rotating body 308.

  Next, the operation of the drag device 300 thus configured will be described. Since the operation of braking the rotation of the spool 102 is the same as that of the drag device 100 in the above-described embodiment, description thereof will be omitted, and the operation in which the drag device 300 in this embodiment displays the magnitude of the drag force will be described.

  When the operation member 307 is rotated to adjust the drag force, the nut 305 moves in the axial direction of the spool shaft 101 as described above. When the drag force is increased, the nut 305 is moved downward in the axial direction. Conversely, when the drag force is decreased, the nut 305 is moved upward in the axial direction. At this time, since the pressing member 306 whose lower surface is in contact with the friction member 103 is restricted from moving downward in the axial direction, the nut 305 and the pressing member 306 are moved according to the vertical movement of the nut 305. The amount of displacement of the urging spring 104 disposed between the two changes, and the drag force acting on the spool 102 changes accordingly. On the other hand, when the nut 305 moves in the vertical direction, the rotating body 308 rotates along the spiral surface of the cam surface 3081 in contact with the follower pin 3053 provided on the nut 305 as described above. As described above, when the nut 305 moves in the axial direction according to the rotation operation to the operation member 307 (that is, when the distance between the nut 305 and the pressing member 306 changes), according to the displacement amount of the biasing spring 104, The drag force acting on the spool 102 and the rotation position (rotation angle) of the rotating body 308 change. For example, when the operator rotates the operation knob 3073 of the operation member 307 in a predetermined direction, the nut 305 is rotated relative to the spool shaft 101 and screwed downward in the axial direction, and the biasing spring 104 is compressed in the axial direction. . At this time, the follower pin 3053 of the nut 305 also moves downward, so that the rotating body 308 maintains the contact state between the cam surface 3081 and the follower pin 3053 by the biasing force of the rotating body biasing spring 310. Rotate around the axis of rotation. The operator visually recognizes the position of the protrusion 3082 that moves in the slit S2 of the visual recognition portion 3074 of the operation member 307 (from the position shown in FIG. 7B to the position shown in FIG. 8B), thereby increasing the drag force. Can be confirmed.

  Here, the displacement amount of the biasing spring 104 is x, the lead angle of the spiral surface of the cam surface 3081 is θ, the radial distance from the shaft portion 3083 to the follower pin 3053 is R3, and the diameter from the shaft portion 3083 to the protrusion 3082 is When the distance in the direction is R4, the rotation angle of the rotating body 308 can be expressed as x / (R3 · tan θ) rad, and the moving distance y (the length of the arc) of the protrusion 3082 is y = R4x / (R3 · tan θ). Therefore, by providing the follower pin 3053 and the protrusion 3082 so that the value of R4 / R3 becomes a large value, the movement distance y of the protrusion 3082 can be increased, and as a result, the visibility of the magnitude of the drag force can be improved. This can be further improved. Further, for example, when the friction coefficient between the cam surface 3083 and the follower pin 3053 is relatively high, it is desirable to increase the lead angle θ of the spiral surface of the cam surface 3081 in order to move the rotating body 308 smoothly. However, the larger the lead angle θ, the smaller the movement distance y of the protrusion 3082 described above. However, in this embodiment, as described above, since the movement distance of the protrusion 3082 can be increased by increasing the value of R4 / R3 independent of the lead angle θ, the lead angle θ must be increased. Even if it is not obtained, the movement distance of the protrusion 3082 can be increased.

  In the drag device 300 according to another embodiment described above, the rotating body 308 that displays the displacement amount by rotating according to the change of the displacement amount of the biasing spring 104 is provided at a position that can be visually recognized by the operator. Yes. Accordingly, the magnitude of the drag force (the amount of displacement of the biasing spring 104) can be indicated by the rotation position (rotation angle) of the rotator 308 (projection 3082). In comparison, the operator can more easily visually recognize the magnitude of the drag force. In addition, since no electrical parts are used, it is not necessary to provide a power source or the like, so that the entire apparatus can be saved, and waterproofness and reliability can be improved. Of course, the same effect as the drag device 100 in the above-described embodiment can be obtained.

  In the drag device 300 according to another embodiment, the rotating body 308 is configured to rotate about the shaft portion 3083 that is coaxial with the spool shaft 101 as a rotating shaft, but it is not necessarily required to rotate coaxially with the spool shaft 101. For example, it can be rotated by a rotating shaft that is in the same direction as the spool shaft 101 and has a different radial position.

  In the embodiment described above, a compression spring that generates an urging force according to compression is used as the urging spring. However, an urging member such as a tension spring that generates an urging force according to tension is used according to the embodiment of the present invention. It is also possible to configure a drag device.

In the above-described embodiment, the drag device configured to brake the rotation of the spool 102 by the frictional force acting between the friction member 103 and the spool 102 is illustrated, but the embodiment of the present invention is not limited to such a configuration. For example, the rotation of the spool may be braked by a braking force other than the frictional force (for example, a braking force using fluid viscosity or electromagnetic force).
As a configuration using the braking force using the viscosity of the fluid, a configuration in which a viscous fluid whose viscosity can be changed is arranged so as to give a viscous force to the spool can be exemplified. Here, the viscous fluid whose viscosity can be changed includes a magnetic fluid whose viscosity changes according to the strength of the magnetic field, and a functional fluid such as an electrorheological fluid whose viscosity changes according to the strength of the electric field. And the braking force with respect to a spool can be adjusted by comprising so that the intensity | strength of a magnetic field and the intensity | strength of an electric field may be changed by movement of a nut etc. The configuration for moving the moving members corresponding to the slider 108 and the rotating body 308 in the above embodiment in accordance with the movement of the nut or the like is the same as in the above embodiment. Moreover, as a structure using the braking force using electromagnetic force, the structure which attaches the coil which sends an electric current to one of a spool and a spool axis | shaft, and attaches a magnet to the other can be illustrated. With this configuration, the Lorentz force generated between the magnet and the coil can be used as a braking force for the spool. And the braking force with respect to a spool can be adjusted by comprising so that the magnetic force of a magnet and the electric current to a coil may be changed by movement of a nut etc. The configuration for moving the moving members corresponding to the slider 108 and the rotating body 308 in the above embodiment in accordance with the movement of the nut or the like is the same as in the above embodiment.

  In the above-described embodiment, the entire drag device has been described. However, the present invention is also applied as an embodiment of a single unit for the drag device, and the same effect as the drag device in the above-described embodiment can be realized. As is clear from the description of the above-described embodiment, the spring 104, the nut 105 (305), the pressing member 106 (306), the operation member 107 (307), and the slider 108 (rotary body 308) are a single unit. It can comprise as a unit (unit for drag apparatuses), and this unit for drag apparatuses is contained in one Embodiment of this invention. And by making this unit for drag apparatus exchangeable, the drag apparatus without the function to display drag force can be made to function as a drag apparatus concerning an embodiment of the present invention. In one embodiment, the drag device unit does not necessarily include the biasing spring 104 and the pressing member 106 (306), and at least one of these members may be provided on the drag device main body side.

  The embodiment of the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention. For example, the material, shape, dimensions, form, number, arrangement, etc., of each member in the above-described embodiment can be changed as appropriate.

100, 300 Drag device 101 Rotating shaft 102 Spool 103, Friction member 104 Biasing spring (biasing member)
105, 305 Nut (change member)
106, 306 Pressing member 107, 307 Operation member 108 Slider (motion member)
308 Rotating body (motion member)

Claims (12)

A drag device for braking rotation of a spool around which a fishing line is wound,
A changing member that moves in a first direction in response to an operation by an operator and changes the braking force on the spool by the movement;
At least partially disposed in a position visible by the operator, according to the change of the braking force by the change member, it is caused to move in a second direction different from the first direction by the changing member movements a member, a moving member having an instruction unit for displaying an equivalent the braking force Ri by the said movement,
An operation member that moves the change member in response to an operation by the operator;
With
The drag device includes a visual recognition unit that allows the operator to visually recognize an instruction unit included in the motion member.   The drag device according to claim 1, wherein the first direction is a rotation axis direction of the spool.   The drag device according to claim 1, wherein the motion member linearly moves in a direction substantially orthogonal to the first direction.   3. The drag device according to claim 1, wherein the moving member rotates in a rotation axis in the same direction as the first direction.   The drag device according to claim 1, wherein the visual recognition unit is a slit extending in the second direction. It said movement member, those the instruction unit drag device according to any one of claims 1 to 5 moves so that the position corresponding to the braking force.   The drag device according to claim 6, wherein the movement member moves such that a moving distance of the instruction unit is larger than a change width of the braking force.   The drag device according to any one of claims 1 to 7, wherein the moving member moves in a second direction different from the first direction using any one of a cam mechanism, a link mechanism, and a gear mechanism. A friction member for applying the braking force to the spool;
A biasing member that generates a biasing force against the friction member in accordance with a displacement amount in the first direction;
The change member changes the displacement amount by the movement,
The movement member displays the displacement amount by moving according to the change of the displacement amount.
The drag device according to claim 1. A pressing member that is provided between the friction member and the biasing member and presses the friction member according to the biasing force of the biasing member;
The change member changes the amount of displacement by moving in the first direction and compressing the biasing member between the change member,
The drag device according to claim 9.   A fishing reel comprising the drag device according to claim 1. A unit used in a drag device for braking rotation of a spool around which a fishing line is wound,
A changing member that moves in a first direction in response to an operation by an operator and changes the braking force on the spool by the movement;
At least partially disposed in a position visible by the operator, according to the change of the braking force by the change member, it is caused to move in a second direction different from the first direction by the changing member movements a member, a moving member having an instruction unit for displaying an equivalent the braking force Ri by the said movement,
An operation member that moves the change member in response to an operation by the operator;
With
The operation device is a drag device unit having a visual recognition portion that allows the operator to visually recognize an instruction portion included in the motion member.

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