JP7775064B2 - Fishing reel with braking section - Google Patents

Description

The present invention relates to a fishing reel equipped with a braking unit that brakes a spool rotatably attached to the reel body.

Dual-bearing reels, particularly baitcasting reels that use a fishing line with a lure or other tackle attached to the end for casting, have traditionally been equipped with a braking device that brakes the spool to prevent backlash during casting.

As an example of a fishing reel equipped with such a braking mechanism, Patent Document 1 discloses a fishing reel with an electrically controllable braking mechanism to suppress backlash during casting. In the fishing reel of Patent Document 1, a permanent magnet on the spool and a coil on the stator (reel body) generate electricity when the spool rotates at high speed. The induced electromotive force generated here is converted to direct current and the voltage is stabilized by a rectifier circuit, and the electricity is supplied to a storage element, which drives a control board and appropriately controls the coil's conductivity, thereby applying an appropriate braking force to the spool.

Japanese Patent Application Laid-Open No. 2004-208630

The fishing reel disclosed in Patent Document 1 is equipped with a detection means, such as a spool rotation detection sensor, which allows it to detect reel status such as line length and winding speed. The detected reel status can be saved as a log or communicated with an external device such as a smartphone, improving user convenience. However, the fishing reel disclosed in Patent Document 1 has a problem in that it cannot supply power to the control board when the spool rotation speed is below a predetermined value (when stopped or at a low speed), making it practically difficult to save the reel status when the spool is rotating at a low speed and to perform various controls, including communicating with the outside world.

The present invention was made in consideration of the above circumstances, and its purpose is to provide a fishing reel that has a braking unit that applies a braking force to the spool, and that can continue to perform control by the control unit, including saving logs and communicating with external devices, even when the spool is stopped. Other purposes of the present invention will become apparent from reading this entire specification.

A fishing reel according to one embodiment of the present invention is configured to include a spool rotatably supported on the reel body of the fishing reel, a braking unit that applies a braking force to the spool through the interaction between a permanent magnet attached to the spool and a coil attached to the reel body, a control unit that controls the braking unit, a power supply unit that can supply power to the control unit, a power generation unit that can generate power in response to braking by the braking unit, and a power source selection unit that can select at least one of the power generated by the power generation unit and the power stored in the power source unit as the power to be supplied to the control unit.

In a fishing reel according to one embodiment of the present invention, the power generating unit is configured to generate electricity through the interaction between the coil and the permanent magnet.

In a fishing reel according to one embodiment of the present invention, the power supply unit is a rechargeable secondary battery, and is configured so that when the power generated by the power generation unit exceeds the driving power of the control unit, the power supply unit can be charged by the power generated by the power generation unit.

A fishing reel according to one embodiment of the present invention further includes an energy harvesting unit, and the power source selection unit is configured to be able to select the power to be supplied to the control unit from at least one of the power generated by the energy harvesting unit, the power generated by the energy harvesting unit, and the power stored in the power source unit.

A fishing reel according to one embodiment of the present invention further includes a detection unit that detects the state of the fishing reel, and the control unit includes at least one of a storage unit that stores the detection information detected by the detection unit and a transmission unit that transmits the detection information detected by the detection unit to an external device, and the control unit is configured to exclusively use the power stored in the power supply unit when the storage unit stores the detection information or the transmission unit transmits the detection information.

In a fishing reel according to one embodiment of the present invention, the control unit is configured to exclusively use the power generated by the power generation unit when controlling the braking force applied to the spool.

A fishing reel according to one embodiment of the present invention is configured to include a spool rotatably supported on a reel body of the fishing reel, a braking unit that applies a braking force to the spool through the interaction between a permanent magnet attached to the spool and a coil attached to the reel body, a control unit that controls the braking unit, a power supply unit that can supply power to the control unit, a power generation unit that can generate power in response to braking by the braking unit, and a power source selection unit that can select at least one of power generated by the power generation unit or power supplied from outside the fishing reel as the power to charge the power source unit. Furthermore, a fishing reel according to one embodiment of the present invention further includes an energy harvesting unit, and the power source selection unit is configured to select at least one of power generated by the power generation unit, power generated by the energy harvesting unit, and power supplied from outside the fishing reel as the power to charge the power source unit.

The above embodiment makes it possible to provide a fishing reel that has a braking device that applies a braking force to the spool, and that can continue to be controlled by the control unit, including saving logs and communicating with external devices, even when the spool is stopped.

1 is a diagram illustrating a fishing reel 1 according to an embodiment of the present invention. 1 is a diagram illustrating a control method for a fishing reel 1 according to an embodiment of the present invention. 1 is a diagram illustrating a control method for a fishing reel 1 according to an embodiment of the present invention. 1 is a diagram illustrating a control method for a fishing reel 1 according to an embodiment of the present invention. 1 is a diagram illustrating a control method for a fishing reel 1 according to an embodiment of the present invention. 1 is a diagram illustrating a control method for a fishing reel 1 according to an embodiment of the present invention. 1 is a diagram illustrating a control method for a fishing reel 1 according to an embodiment of the present invention. 10A to 10C are diagrams illustrating a fishing reel 1 according to another embodiment of the present invention.

Embodiments of a fishing reel according to the present invention will now be described in detail with reference to the accompanying drawings. Components common to multiple drawings are designated by the same reference numerals throughout the drawings. Please note that the drawings are not necessarily drawn to scale for ease of explanation.

A fishing reel according to one embodiment of the present invention will be described with reference to Figures 1 to 8. Figures 1(a), (b), and (c) are system diagrams showing the electrical functional configuration of a fishing reel 1 according to one embodiment of the present invention.

First, using Figure 1, the component configuration of a fishing reel 1 according to one embodiment of the present invention will be described. As shown in the figure, the fishing reel 1 according to one embodiment of the present invention is configured to include a frame (reel body) 2, a spool 3, a brake unit (braking means) 4, a control unit (control means) 5, a detection unit (detection means or sensor unit) 6, and a power supply unit 7, but may also include other components.

The frame (reel body) 2 is configured to be attachable to a fishing rod (not shown). Like conventional fishing reels, the fishing reel 1 according to one embodiment of the present invention has an operating unit or operating means (e.g., a handle) (not shown), which can be operated by a user to rotate the spool 3 in the forward direction and reel in fishing line. The rotation of the operating unit or operating means (hereinafter referred to as the operating unit) is transmitted to the spool 3 by a transmission means such as a gear (not shown).

The fishing reel 1 according to one embodiment of the present invention also has a clutch unit (clutch means) (not shown), which the user can operate to select whether to connect or disconnect power transmission to the spool 3. When power transmission to the spool 3 is connected, winding is possible using the operating unit. On the other hand, when power transmission to the spool 3 is disconnected, the spool can be rotated freely in both forward and reverse directions, allowing the fishing line to be released.

The fishing reel 1 according to one embodiment of the present invention may also be equipped with a drag unit or drag means (not shown) that prevents the fishing line from breaking by causing the spool 3 to spin freely when torque equal to or greater than a predetermined value is generated, and a reverse rotation prevention unit or reverse rotation prevention means (not shown) that prevents the operating unit from rotating in the reverse direction. Furthermore, an oscillator device (not shown) may also be provided that evenly winds the fishing line by reciprocating the position of the fishing line guide that guides the fishing line in accordance with the rotation of the spool 3.

The spool 3 is supported on the reel body 2 so that it can rotate relative to the reel body 2. When the spool 3 rotates in the forward direction, fishing line can be wound onto the outer periphery of the spool 3. On the other hand, when casting a lure, the spool 3 rotates in the reverse direction, releasing the wound fishing line. If the amount of fishing line released is greater than the amount of movement of the lure, the excess fishing line can cause line tangles known as backlash, which can interfere with normal use of the fishing reel 1. For this reason, such backlash is prevented by applying an appropriate braking force to the spool 3 using the brake unit 4, which will be described later.

Next, we will explain the braking unit 4. The braking unit 4 is composed of a permanent magnet 41 provided on the spool 3, a coil 42 held integrally with the frame 2, and a switch element 43 provided in the control unit 5.

The permanent magnet 41 is formed in a roughly cylindrical shape coaxial with the rotation axis of the spool 3, and its outer periphery is divided into n equal parts and magnetized with alternating north and south poles. The coil 42 is wound in a roughly rectangular shape so that the wound core wire faces the permanent magnet 41 and is positioned within the magnetic field of the magnet 41. When multiple coils 42 are arranged, the coils are electrically connected in series or parallel, and both ends are connected to the switch element 43.

The switch element 43 is composed of, for example, two parallel-connected field-effect transistors (FETs) that can be turned on and off at high speed, and can select whether to electrically connect or disconnect the coil 42.

This configuration makes it possible to apply braking to the spool 3 using so-called dynamic braking. As the spool 3 rotates at high speed, the magnetic field created by the permanent magnet 41 moves relative to the coil 42. When the coil 42 is electrically connected using the switch element 43, an electromotive force is generated in the coil 42. This electromotive force generates a current in the circuit created by the coil 42, generating a magnetic force in the permanent magnet 41 that acts in the opposite direction to the direction of rotation. This generates a braking torque in the spool 3 that is proportional to the square of the rotation speed. Furthermore, when the coil 42 is electrically disconnected using the switch element 43, the generation of this braking torque can be stopped.

By appropriately switching the connection and disconnection of the switch element 43, a predetermined braking torque can be generated in the spool 3. While braking torque is being generated in the spool 3, the mechanical energy of the spool 3 is converted into electrical energy in the circuit formed by the coil 42.

In this specification, this conversion means is referred to as the power generation unit (power generation means or power generation mechanism) 8 or spool power generation unit 8. Here, the power generation unit 8 is composed of a permanent magnet 41, a coil 42, a switch element 43, a rectifier circuit, and a storage element, but may include components other than these. The power generation unit 8 generates electrical energy, and by supplying the generated electrical energy to the control unit 5, the control unit 5 can be operated and driven. In this specification, the power generation produced by the power generation unit 8 is referred to as spool power generation. Note that a yoke may be placed around the outer periphery of the coil 42 to efficiently generate a magnetic field from the permanent magnet 41 in the coil 42.

Next, the control unit 5 controls the braking unit 4 to apply appropriate braking to the spool 3. The control unit 5 has a ROM that stores a predetermined program, a memory unit (RAM) that temporarily stores detection information and the like during program processing, and a CPU (not shown) that controls these components, with each component being located within a single semiconductor component or on a board with an electrical circuit printed on it. The control unit 5 may also have a storage means (storage unit) such as a flash ROM that can store data even after the power is turned off, a display unit such as an LED or LCD, and a communication means (communication unit) that communicates with the outside world via wireless communication network technology, a USB connector, etc.

The CPU (not shown) of the control unit 5 is configured to acquire information from the detection unit 6, which detects the state of the fishing reel. The detection unit 6 may include, for example, a spool rotation detection unit or means 61 that detects the rotation state of the spool, a handle rotation detection unit or means 62 that detects the rotation state of the handle, a clutch detection unit or means 63 that detects the engaged/disengaged state of the clutch, a tension detection unit or means 64 that detects the tension of the fishing line, a set drag force detection unit or means 65 that detects the set drag force, a motion sensor 66 that detects the movement of the fishing reel and fishing rod, and a braking force detection unit 67 that detects the braking force of the braking unit 4, but the control unit 5 may be configured to include some or all of these.

The spool rotation detection unit 61 can detect whether the spool is rotating by an electrical signal generated when a detectable part, such as a magnet, attached to the spool comes close to a detector, such as a coil, attached to the reel body (frame). Conventional detection methods, such as photosensors and magnetic sensors, can be used as the detection means, and an appropriate detectable part can be attached to the spool depending on the detection means.

The handle rotation detection unit 62 can be realized by attaching a rotation sensor to the handle or a gear that rotates in conjunction with the handle. This can be realized by known means, such as an incremental rotation sensor that uses a photointerrupter or magnetic sensor. A non-contact rotation sensor is preferable to ensure smooth rotation of the handle. By taking the difference between the handle rotation detection unit 62 and the spool rotation detection unit 61, the amount of rotation caused by the drag device can be calculated.

The clutch detection means 63 can detect whether the fishing line can be released from the spool by attaching a limit switch, proximity sensor, or other sensor to a part of the clutch operating member. The tension detection unit 64 can be realized using various conventionally known technologies, such as using a strain sensor to detect the force acting on the rotating shaft of the pulley that guides the fishing line.

The set drag force detection unit 65 also detects the set tension, which is the threshold at which the spool spins freely. This can be achieved by detecting the charging force acting on the friction member inside the drag device using a pressure sensor or the like.

The motion sensor 66 can also detect the movement of the fishing rod or reel. This can be achieved by using a gyro sensor, a conventionally known technology, such as a method of detecting frequency changes in a vibrating piezoelectric element. By using a sensor known as a nine-axis motion sensor, which detects the direction, acceleration, and angular velocity of each of three orthogonal axes, the sensor can function as a direction detection unit, acceleration detection unit, and angular velocity detection unit. The set braking force detection unit 67 can also detect the set value of the braking force used to suppress backlash.

The control unit 5 can generate a predetermined braking torque on the spool 3 by appropriately switching between connection and disconnection of the switch element 43 at known switching timing in accordance with the detection results of the above-mentioned detection unit 6. This makes it possible to increase the casting distance of lures and the like while avoiding backlash.

In a fishing reel 1 according to one embodiment of the present invention, the control unit 5 may be configured to save the reel state. One example of a method for doing so is to acquire the detection results of the detection unit at predetermined times (e.g., every predetermined time). Then, as necessary, the detection results are calculated and saved in a temporary memory area or storage unit or means. This allows the time-varying reel state of the fishing reel to be saved. Specifically, it is possible to obtain a detailed understanding of the time-varying change in the spool rotation speed during casting, or to record the change in the fishing line length and reeling speed when retrieving a lure. The saved information may also be transmitted via the communication unit (communication means) to an information communication terminal such as a personal computer or smartphone, or to an external device such as another fishing reel or fish finder equipped with the communication unit. The information may also be communicated to the user by outputting it to an output unit (output means) such as an LCD or speaker.

A fishing reel 1 according to one embodiment of the present invention is configured to include a spool 3 rotatably supported on the reel body 2 of the fishing reel 1, a braking unit 4 that applies a braking force to the spool 3 through the interaction between a permanent magnet 41 attached to the spool 3 and a coil 42 attached to the reel body 2, a control unit 5 that controls the braking unit 4, a power supply unit 7 that can supply power to the control unit 5, a power generation unit 8 that can generate power in response to braking by the braking unit 4, and a power source selection unit 9 that can select at least one of the power generated by the power generation unit 8 and the power stored in the power supply unit 7 as the power to be supplied to the control unit 5.

The fishing reel 1 according to one embodiment of the present invention has a braking unit 4 that applies a braking force to the spool 3, and it is possible to provide a fishing reel 1 that can continue to be controlled by the control unit 5, including saving logs and communicating with external devices, even when the spool 3 is stopped. Specifically, for example, it is possible to save changes in line length while fishing and check that information on an external device such as a smartphone.

In a fishing reel 1 according to one embodiment of the present invention, the power generating unit 8 is configured to generate electricity through the interaction between a permanent magnet 41 attached to the spool 3 and a coil 42 attached to the reel body 2. In this way, the kinetic energy generated when the spool 3 rotates can be used to generate power to drive the control unit.

In a fishing reel 1 according to one embodiment of the present invention, the power supply unit 7 is a rechargeable secondary battery, and is configured so that when the power generated by the power generation unit 8 exceeds the drive and operating power of the control unit 5, the power supply unit 7 can be charged with the power generated by the power generation unit 8. In this way, when the spool rotation speed reaches a predetermined value or higher, the power supply unit 7 can be charged without an external power supply.

A fishing reel 1 according to one embodiment of the present invention further includes an environmental power generation unit 10, and the power source selection unit 9 is configured to be able to select the power to be supplied to the control unit 5 from at least one of the power generated by the power generation unit 8, the power generated by the environmental power generation unit 10, and the power stored in the power source unit 7. In this way, it becomes possible to drive the control unit 5 using environmental energy present around the fishing reel, such as sunlight, temperature differences, and vibrations, thereby extending the battery life of the fishing reel.

A fishing reel 1 according to one embodiment of the present invention further includes a detection unit (sensor unit) 6 that detects the state of the fishing reel 1, and the control unit 5 includes at least one of a storage unit 11 that stores the detection information detected by the detection unit (sensor unit) 6 or a transmission unit 12 that transmits the detection information detected by the detection unit (sensor unit) 6 to an external device. When the storage unit 11 stores the detection information or the transmission unit 12 transmits the detection information, the control unit 5 is configured to exclusively use the power stored in the power supply unit 7. Here, "exclusively" refers to a power supply that is at least the minimum power required to drive the control unit 5. In this way, even when the spool rotation speed is below a predetermined value and the power from the power generation unit 8 is low, the control unit 5 can be stably driven by the power from the power supply unit 8.

In a fishing reel 1 according to one embodiment of the present invention, the control unit 5 is configured to exclusively use the power generated by the power generation unit 8 when controlling the braking force on the spool 3. Here, "exclusively" means that at least the minimum power required to drive the control unit 5 is supplied from the same power source. In this way, the control unit can be driven by power from the power generation unit 8 during casting, which avoids power consumption within the power supply unit and enables the battery to last longer. In particular, because the power generated by the power generation unit 8 is consumed by the control unit immediately after generation, it is less susceptible to energy loss due to power storage and allows for efficient power use.

A fishing reel 1 according to one embodiment of the present invention is configured to include a spool 3 rotatably supported on a reel body 2 of the fishing reel 1, a braking unit 4 that applies a braking force to the spool 3 through the interaction between a permanent magnet 41 attached to the spool 3 and a coil 42 attached to the reel body 2, a control unit 5 that controls the braking unit 4, a power supply unit 7 that can supply power to the control unit 5, a power generation unit 8 that can generate power in response to braking by the braking unit 4, and a power source selection unit 9 that can select at least one of the power generated by the power generation unit 8 and power supplied from an external source to the fishing reel 1 as the power to charge the power source 7. The fishing reel according to one embodiment of the present invention also includes an energy harvesting unit, and the power source selection unit is configured to select at least one of the power generated by the power generation unit, power generated by the energy harvesting unit, and power supplied from an external source to the fishing reel as the power to charge the power source unit.

The fishing reel 1 according to one embodiment of the present invention has a braking unit 4 that applies a braking force to the spool 3, and can continue to be controlled by the control unit 5, including saving logs and communicating with external devices, even when the spool 3 is stopped. Specifically, even when the spool 3 is stopped, such as while waiting for a fish to bite after casting, the acceleration sensor can record the operation of the rod and send that data to a smartphone.

As previously mentioned, the power source for the control unit 5 in the fishing reel 1 according to one embodiment of the present invention is selected by the power source selection unit 9. The power source options include at least the power generation unit (spool power generation unit) 8 described above and the power source unit 7 (e.g., a battery). Examples of batteries that can store enough power to drive the control unit 4 for a certain period of time include, but are not limited to, replaceable dry batteries such as button batteries, secondary batteries such as lithium ion batteries and lithium polymer batteries, and power storage devices such as lithium ion capacitors and electric double layer capacitors.

The power source selection unit 9 is a means for electrically selecting the source of power supply to electrical components such as the control unit 5 and detection unit 6, and is realized, for example, by a power source selector IC, FET, switch, etc. The power source selection unit 9 in the fishing reel 1 according to one embodiment of the present invention will be described with reference to Figures 2 to 7.

Next, the fishing reel 1 according to one embodiment of the present invention will be further described with reference to Figures 2 to 7. Figures 2 to 7 are diagrams showing the direction of power transfer from each component. When the rotation speed of the spool 3 reaches a predetermined value or more and the power generated by the power generator (spool power generator) 8 exceeds the power consumption of the control unit 5, as shown in Figure 2, the power source selection unit 9 switches so that the power generated by the coil 42 is used to operate or drive the control unit 5.

This allows the control unit 5 to be operated or driven without consuming power stored in the power supply unit 7 (e.g., a battery). The momentary voltage drop that occurs during switching can be compensated for by a capacitor or the like. Furthermore, if a rechargeable secondary battery is used as the power supply unit 7 (e.g., a battery) and the generated power is sufficiently large, the charging circuit 13 can be operated using power from the power generation unit (spool power generation unit) 8 to charge the secondary battery in addition to operating or driving the control unit 5. Whether or not the secondary battery can be charged can be determined by whether or not the power generated by the power generation unit (spool power generation unit) 8 exceeds a predetermined value within a predetermined time. This allows the user to charge the battery without performing any special operations, even while using the fishing reel. Note that the charging circuit 13 is not required when using a primary battery.

On the other hand, when the spool 3 is stopped or rotating slowly, or when the spool 3 is rotating at a speed below a predetermined value, the power consumption of the control unit 5 exceeds the power generated by the power generation unit (spool power generation unit) 8. In this case, as shown in FIG. 4, the power source selection unit 9 can be switched to operate or drive the control unit 5 using power stored in the power source unit 7 (e.g., a battery). This allows the control unit 5 to be operated or driven at all times, regardless of the amount of rotation of the spool 3. Therefore, even when the spool 3 is stopped or the fishing reel is being slowly reeled in, the reel status, such as the rotation speed of the spool 3, can be saved, the reel status can be displayed, and external communication can be performed.

The threshold value at which the amount of power generated by the power generation unit (spool power generation unit) 8 can activate or drive the control unit 5 and detection unit 6 is determined by the power generation efficiency of the power generation unit (spool power generation unit) 8. Possible methods for increasing power generation efficiency include increasing the volume of the permanent magnet 41, using a material with a high magnetic flux density, increasing the number of turns of the coil 42, or increasing the diameter of the winding. Furthermore, the threshold value can be reduced by reducing the power consumption of the control unit 5 and detection unit 6.

When reeling in the fishing line, the switch element 43 is connected, switching the brake unit 4 to a constant braking state (a braking state refers to a state in which the circuit created by the coil 42 forms a loop, generating a back electromotive force in the coil 42 and applying a braking force to the magnet installed in the spool), thereby increasing the amount of power generated by the power generator (spool power generator) 8. While this increases the operating torque required when the user operates the handle, it increases the amount of power stored in the storage element and extends the time for which the control unit 5 and detection unit 6 are driven. The detection unit 6 detects the rotation direction of the spool 3, and if the rotation speed in the release direction exceeds a predetermined value, it executes a braking sequence to prevent backlash and intermittently drives the switch element 43 as necessary. If the rotation direction of the spool 3 is the reeling direction, the brake unit 4 is constantly in a braking state, ensuring sufficient power generation by the power generator (spool power generator) 8.

In another embodiment, the power source selection unit 9 can be equipped with a power source/combining function that combines multiple power sources in addition to the power source selection function, in which case the following can be performed (for convenience in this specification, this will be referred to as the power source selection unit 9). Here, "combining" refers to supplying the total power supplied from multiple power supply sources to the control unit 5. When the rotation speed of the spool 3 is sufficiently high and higher than the power consumption of the control unit 5, the power source selection unit 9 switches so that the power generated by the power generation unit (spool power generation unit) 8 is used to operate or drive the control unit, as shown in Figure 2, as in the above case.

When the rotation speed of the spool 3 falls below a predetermined value and the power generation unit (spool power generation unit) 8 is generating almost no power, the power source selection unit 9 switches to drive the control unit 5 using power stored in the power source unit 7 (e.g., a battery), as shown in Figure 3. When the rotation speed of the spool 3 is above a predetermined value and the power generation unit (spool power generation unit) 8 is generating a certain amount of power but is lower than the power consumption of the control unit 5, the power source selection unit 9 switches to combine the power generated by the power generation unit (spool power generation unit) 8 and the power stored in the power source unit 7 (e.g., a battery) and supply it to the control unit, as shown in Figure 4.

By using this method and configuration, the power source selection unit 9 can reduce power consumption by the power source unit 7 (e.g., a battery) even when the amount of power generated by the power generation unit (spool power generation unit) 8 is less than the power consumption of the control unit 5, thereby achieving a longer battery life.

In a fishing reel 1 according to one embodiment of the present invention, the power supply options can include an environmental power generation unit (environmental power generation means) 10. Specifically, the environmental power generation unit 10 can be a photovoltaic cell that converts light energy into electrical energy, a vibration power generation unit/means that converts mechanical vibration energy into electrical energy, or a temperature difference power generation unit/means that converts energy corresponding to the temperature difference between two points into electricity, but other units are also possible. Furthermore, one of these units may be used, or a combination of two or more may be used.

In this configuration, the power source selection unit 9 can function as follows. First, when the rotation speed of the spool 3 is equal to or greater than a predetermined value and the amount of power generated by the power generation unit (spool power generation unit) 8 is greater than the power consumption of the control unit 5, as shown in FIG. 5, the power source selection unit 9 switches so that the power generated by the power generation unit (spool power generation unit) 8 is used to operate or drive the control unit 5. In this case, if a secondary battery is used as the power source unit 7 and the generated power is greater than the power consumption, the secondary battery may be charged by the charging circuit 13.

When the rotation speed of the spool 3 is below a predetermined value and the amount of power generated by the power generation unit (spool power generation unit) 8 is less than the power consumed by the control unit 5, but the amount of power generated by the environmental power generation unit 10 is greater than the power consumed by the control unit 5, as shown in Figure 6, the power source selection unit 9 is switched so that the power generated by the environmental power generation unit 10 is used to operate or drive the control unit 5. In this case, if a secondary battery is used as the power source unit 7 and the generated power is greater than the power consumed, the secondary battery may be charged by the charging circuit 13.

When the amount of power generated by the power generation unit (spool power generation unit) 8 and the amount of power generated by the energy harvesting unit 10 are both smaller than the power consumption of the control unit 5, as shown in Figure 7, the power source selection unit 9 switches so that power stored in the power source unit 7 (e.g., a battery) is supplied to the control unit 5. This reduces the frequency with which the power stored in the battery is used, thereby making it possible to extend the battery's lifespan.

Furthermore, if the power source selection unit 9 has the function of combining multiple power sources in addition to the function of selecting a power source, similar to the method described above, the power generated by the power generation unit (spool power generation unit) 8 and the energy harvesting unit 10 and the power stored in the power source unit 7 (e.g., a battery) can be combined to operate or drive the control unit 5, and the battery can also be charged as needed.

Furthermore, the power source selection unit 9 can add an external power supply as an option for the power supply source. Possible external power supplies include, but are not limited to, a wired power supply means in which a connector terminal such as a USB terminal is provided on the fishing reel 1 and a wired cable is connected to the connector terminal to supply power from an external source via a wire, or a wireless power supply means in which a power receiving coil is provided within the device and power is supplied wirelessly from an external antenna. In this way, by using externally supplied power to supply power to the control unit 5, a stable power supply to the control unit 5 is possible, despite the constraints of the wired cable and external antenna, and there is no need to worry about the battery running out while the fishing reel 1 is connected.

Next, another embodiment of the present invention will be described using Figure 8. In a fishing reel 1 according to another embodiment of the present invention, a rechargeable secondary battery is used as the power supply unit 7, and the secondary battery can be used to supply power to the control unit 5. As in the above embodiment, the control unit 5 is able to grasp the reel state of the fishing reel by receiving a signal from the detection unit 6, and can accordingly issue a control command to the braking unit 4, save the reel state as a log, or output it to an external device.

When the rotation speed of the spool 3 reaches or exceeds a predetermined value, the power generated by the power generation unit (spool power generation unit) 8 can be supplied to the secondary battery, which is the power supply unit 7, via the charging circuit 13. The power source to be supplied to the charging circuit 13 can be selected by the power source selection unit 9 from one or more of the power generation unit (spool power generation unit) 8, external power source 14, and energy harvesting unit 10. From these options, the one with the greatest power generation may be selected, or if an external power source is connected, the external power source may be selected as the preferred power source, or two or more of these may be selected (combined). Note that the energy harvesting unit 10 is not essential and can be omitted.

Furthermore, as in the above embodiment, the power source selector 9 can be configured to have the function of combining multiple power sources, and the power generated from the multiple power source options can be combined and then supplied to the charging circuit 13. This increases the complexity of the charging circuit 13, but allows for effective use of the generated power. With the fishing reel 1 according to the above embodiment of the present invention, power generated by the power generator (spool power generator) 8 can be supplied to the power source 7 (e.g., a battery) even when no external power source is being supplied to the fishing reel 1. This makes it possible to achieve longer battery life, lower capacity, and lower costs.

Finally, we will explain the effects of the fishing reel 1 according to the above-described embodiment of the present invention. In the fishing reel 1 according to the above-described embodiment of the present invention, when the control unit is operated or driven by the power supply unit in addition to the spool power generation unit 8, power can be supplied stably to the control unit even when the spool rotation speed is low and sufficient power cannot be generated by power generation. Therefore, power can be supplied to the control unit (and detection unit) even when the spool is stopped or the fishing line is being reeled in slowly, making it possible to constantly record reel information and display or communicate that information on an external device.

Furthermore, when a rechargeable secondary battery is used as the power supply in the fishing reel 1 according to the above-described embodiment of the present invention, the secondary battery serving as the power supply can be charged by the spool power generation unit or the environmental power generation unit. This allows the secondary battery to be charged depending on the situation, even while the fishing reel is in use, thereby extending the battery's life and enabling smaller size and lower costs due to the lower battery capacity.

Furthermore, in the fishing reel 1 according to the above-described embodiment of the present invention, the control unit is used to adjust the braking force during casting. During casting, the spool rotation speed generally increases and the change in rotation speed also becomes greater. In this case, the control unit must adjust the braking force of the braking unit at high speed, which generally increases power consumption. However, since the power generated by the spool power generation unit increases in accordance with the spool rotation speed, the generated power increases as power consumption increases. As a result, an increase in power consumption in the power supply unit can be avoided. In this way, during casting, the control unit can be operated or driven primarily using power from the spool power generation unit.

The control unit can also be used to detect the reel state and communicate with the outside world when not being thrown. In this case, the change in reel state is smaller than when being thrown, so the power consumption of the control unit is generally lower. Although the power generated by the spool power generation unit is lower when not being thrown, the power consumption of the control unit is relatively small, so the impact on battery life can be reduced. In this way, when the detection unit is acquiring, saving, or communicating reel information when not being thrown, the control unit can be operated or driven primarily using the power stored in the power supply unit (e.g., a battery).

The dimensions, materials, and arrangement of each component described in this specification are not limited to those explicitly described in the embodiments, and each component can be modified to have any dimensions, materials, and arrangement that fall within the scope of the present invention. Furthermore, components not explicitly described in this specification can be added to the described embodiments, and some of the components described in each embodiment can be omitted.

1 Fishing reel 2 Frame (reel body)
3 Spool 4 Brake unit 5 Control unit 6 Detection unit 7 Power supply unit 8 Power generation unit 9 Power source selection unit 10 Energy harvesting unit 11 Storage unit 12 Transmission unit 13 Charging circuit 14 External power source 61 Spool rotation detection unit (spool rotation detection means)
62 Steering wheel rotation detection unit (steering wheel rotation detection means)
63 Clutch detection unit (clutch detection means)
64 Tension detection unit (tension detection means)
65 Set drag force detection unit (set drag detection means)
66 Motion sensor 67 Braking force detection unit (braking force detection means)

Claims (8)

a spool rotatably supported on a reel body of the fishing reel;
a braking unit that applies a braking force to the spool by interaction between a permanent magnet attached to the spool and a coil attached to the reel body;
a control unit that controls the braking unit;
a power supply unit capable of supplying power to the control unit;
a power generating unit capable of generating power in response to braking of the braking unit;
a power source selection unit that can select, as the power to be supplied to the control unit, at least one of the power generated by the power generation unit and the power stored in the power source unit;
A fishing reel comprising: The fishing reel of claim 1, wherein the power generating unit generates electricity through interaction between the coil and the permanent magnet. the power supply unit is a rechargeable secondary battery,
3. The fishing reel according to claim 1, wherein when the power generated by the power generating unit exceeds the drive power of the control unit, the power supply unit can be charged with the power generated by the power generating unit. Further comprising an energy harvesting unit,
4. The fishing reel according to claim 1, wherein the power source selection unit is capable of selecting, as the power to be supplied to the control unit, at least one of the power generated by the power generation unit, the power generated by the energy harvesting unit, and the power stored in the power source unit. Further, a detection unit for detecting a state of the fishing reel is provided.
the control unit includes at least one of a storage unit that stores detection information detected by the detection unit and a transmission unit that transmits the detection information detected by the detection unit to an external device,
5. The fishing reel according to claim 1, wherein the control unit exclusively uses the power stored in the power supply unit when the storage unit stores the detection information or the transmission unit transmits the detection information. A fishing reel as described in any one of claims 1 to 4, wherein the control unit exclusively uses the power generated by the power generation unit when controlling the braking force on the spool. a spool rotatably supported on a reel body of the fishing reel;
a braking unit that applies a braking force to the spool by interaction between a permanent magnet attached to the spool and a coil attached to the reel body;
a control unit that controls the braking unit;
a power supply unit capable of supplying power to the control unit;
a power generating unit capable of generating power in response to braking of the braking unit;
a power source selection unit that can select the power to be charged to the power source unit from at least one of the power generated by the power generation unit and the power supplied from an external source of the fishing reel;
A fishing reel comprising: Further comprising an energy harvesting unit,
8. The fishing reel according to claim 7, wherein the power source selection unit is capable of selecting, as the power to charge the power source unit, at least one of power generated by the power generation unit, power generated by the energy harvesting unit, and power supplied from an external source to the fishing reel.