CN109511620B

CN109511620B - Backup system of electric fishing reel

Info

Publication number: CN109511620B
Application number: CN201810836612.2A
Authority: CN
Inventors: 木谷哲也
Original assignee: Shimano Inc
Current assignee: Shimano Inc
Priority date: 2017-09-19
Filing date: 2018-07-26
Publication date: 2021-12-28
Anticipated expiration: 2038-07-26
Also published as: TWI760512B; KR102621886B1; JP6946127B2; KR20190032205A; CN109511620A; TW201914421A; JP2019050789A

Abstract

The invention provides a backup system of an electric fishing reel (100), which is provided with a control part (21), a storage part (25), a time measuring part (26) and a backup power supply (27). The control unit controls the electric reel by the power supplied from the external Power Supply (PS). The storage unit (25) stores control information related to control of the electric reel. The time measurement unit measures a power interruption time until power supply from the external power source is restarted after power supply from the external power source is interrupted. The backup power supply operates the time measurement unit while the power supply from the external power supply is interrupted. The control unit controls the electric reel based on the control information stored in the storage unit when the power cut-off time is within a predetermined range, and deletes the control information stored in the storage unit when the power cut-off time exceeds the predetermined range. The invention can inhibit the large scale of the standby power supply and realize the backup of water depth information and the like.

Description

Backup system of electric fishing reel

Technical Field

The present invention relates to a backup system (backup system) for an Electric reel (Electric reel).

Background

It is known that an electric reel is provided with a display unit for displaying water depth information of a hook unit attached to a tip end of a fishing line. A control unit including a microcomputer is provided in the electric reel, and the control unit controls a motor of the electric reel, calculates a water depth of the hook assembly based on rotation data of the spool, and displays the water depth information on a display unit. The control unit of the electric reel is supplied with electric power via a power cord (power cord) connected to an external power source.

In such an electric reel, the power supply line may be disconnected from the external power supply for some reason, and the supply of electric power from the external power supply to the control unit may be interrupted. When the power supply to the control unit is cut off and the microcomputer of the control unit is reset, the water depth information calculated by the microcomputer is also reset. Therefore, when the power supply line is reconnected, the water depth information displayed on the display unit may be incorrect.

In order to solve the above problem, patent document 1 discloses the following structure: a backup power supply such as a capacitor is provided in the electric reel, and when the supply of electric power from the external power supply is interrupted, electric power is supplied from the backup power supply. Accordingly, when the supply of power from the external power supply is restarted, the water depth information before the power cut is received, and the received water depth information is displayed on the display unit.

Documents of the prior art

Patent document

Patent document 1: japanese laid-open patent publication No. 2000-175603

Disclosure of Invention

In such an electric reel, in order to avoid resetting of the microcomputer of the control unit, the microcomputer is put into a standby state, and backup of water depth information and the like is realized. Therefore, during the period from the normal state to the standby state of the microcomputer, the current in the normal state needs to be supplied from the backup power supply to the microcomputer. However, the standby power supply may be increased in size in order to satisfy the current consumption in the normal state of the microcomputer.

The technical problem to be solved by the invention is to realize backup of water depth information and the like while suppressing the upsizing of a standby power supply.

The backup system of the electric fishing reel according to an aspect of the present invention includes a control unit, a storage unit, a time measurement unit, and a backup power supply. The control unit controls the electric reel by electric power supplied from an external power supply. The storage unit stores control information related to control of the electric reel. The time measurement unit measures a power interruption time until power supply from the external power source is restarted after power supply from the external power source is interrupted. The backup power supply operates the time measurement unit at least while the power supply from the external power supply is interrupted. The control unit controls the electric reel based on the control information stored in the storage unit when the power cut-off time is within a predetermined range, and deletes the control information stored in the storage unit when the power cut-off time exceeds the predetermined range.

In this backup system for an electric reel, it is not necessary to supply a normal current from the backup power supply to the control unit after the power supply from the external power supply is cut off, and the control unit is put into a standby state. Accordingly, a small-capacity backup power supply can be used for the electric reel, and therefore, the backup power supply can be reduced in size. Further, by providing the time measurement unit, it is possible to control the backup time, and it is easy to determine whether or not the backup power source is lost when the supply of power from the external power source is restarted after the supply of power from the external power source is cut off. Therefore, it is possible to accurately determine whether or not to execute the backup processing.

Preferably, the time measurement unit includes a real-time clock (real-time clock), and measures the power cut-off time based on time information when the power supply from the external power source is cut off and time information when the power supply from the external power source is restarted. In this case, since the power consumption of the circuit of the real-time clock is small, a small-capacity backup power supply can be used. In addition, the backup time can be controlled with high accuracy by the real-time clock.

Preferably, the storage unit is a volatile memory, and the backup power supply supplies power to the storage unit when the external power supply is turned off. In this case, if the backup power is lost, the data stored in the storage unit is also reset, and therefore, when it is determined that the backup processing is not necessary, the data stored in the storage unit does not need to be deleted.

Preferably, the backup power source is a capacitor. In this case, after the power supply from the external power supply is cut off, the control unit is set to the standby state without supplying the current in the normal state from the backup power supply to the control unit. Accordingly, the backup power supply can use a small capacitor, and thus the backup power supply can be miniaturized.

Preferably, the fishing hook further includes a water depth display unit that displays water depth information relating to a water depth of the fishing hook assembly, and the control unit further includes a water depth display control unit that displays the water depth information on the water depth display unit. The control information stored in the storage unit includes water depth information, and the water depth display control unit displays the water depth information stored in the storage unit on the water depth display unit when the power cut-off time is within a predetermined range. In this case, if the power cut-off time is within the predetermined range, the water depth information stored before the power supply from the external power supply is cut off is displayed on the water depth display unit, and therefore fishing can be performed while maintaining accurate water depth information.

Effects of the invention

According to the present invention, in the backup system of the electric reel, backup of water depth information and the like can be realized while suppressing an increase in size of the backup power supply.

Drawings

Fig. 1 is a plan view of an electric reel according to an embodiment of the present invention.

Fig. 2 is an enlarged view of a display portion of the electric reel.

Fig. 3 is a block diagram showing the configuration of a control system of the electric reel.

Fig. 4 is a flowchart showing the flow of backup processing.

Description of the reference numerals

16 a: a water depth display unit; 21: a control unit; 21 b: a water depth display control unit; 25: a storage unit; 26: a time measuring part; 26 a: a real-time clock; 27: a standby power supply; 100: spinning reel (spinning reel); 100: an electric fishing reel; PS: an external power supply; t: power off time.

Detailed Description

As shown in fig. 1, the electric reel 100 according to an embodiment of the present invention is an electric reel in which a motor is driven by electric power supplied from an external power supply PS. The electric reel 100 has a water depth display function for displaying the water depth of the hook assembly according to the fishing line reel-out length or the fishing line reel-up length.

The electric reel 100 mainly includes: a reel unit 1 that can be attached to a fishing rod; a spool 2 disposed inside the reel unit 1; a handle 3 for rotating the spool 2, which is disposed on the side of the reel unit 1; a Star drag mechanism (Star drag)4 for adjusting drag (braking force) disposed on the handle 3 on the reel unit 1 side; and a counter box 5 for displaying the water depth.

The reel unit 1 includes: a frame 6; and a 1 st side cover 7a and a 2 nd side cover 7b which cover both right and left sides of the frame 6. A level winding mechanism (level winding device), not shown, which operates in conjunction with the spool 2, and a rotation transmission mechanism, not shown, are provided in the reel unit 1; the rotation transmission mechanism transmits rotation of the handle 3 and a motor 8 described later to the spool 2.

The 2 nd side cover 7b is provided with a connector (connector)11, and a power supply line 12 connecting the electric reel 100 and the external power supply PS is connected to the connector 11. Electric power is supplied from the external power supply PS to the electric reel 100 via the power supply line 12.

The spool 2 is rotatably provided on the reel unit 1 between the 1 st side cover 7a and the 2 nd side cover 7 b. A motor 8 is disposed inside the spool 2, and the motor 8 drives the spool 2 to rotate in the winding direction.

The handle 3 is rotatably supported by the 1 st side cover 7 a. Further, a shift lever 14 and a clutch operating member 15 are arranged swingably on the side surface of the reel unit 1 on the handle 3 side. The shift lever 14 is a member for adjusting the output of the motor 8, and the output of the motor 8 varies according to the swing position of the shift lever 14. The clutch operating member 15 is a member for performing a clutch operation for turning on and off the handle 3 and the motor 8 and transmitting drive to the spool 2.

The counter case 5 is fixed to the upper portion of the front side of the reel unit 1. A display unit 16 having a liquid crystal display is provided on the upper surface of the counter case 5. The display unit 16 includes a water depth display unit 16a that displays water depth information relating to the water depth of the hook assembly.

As shown in fig. 2 in an enlarged manner, the water depth display unit 16a includes a water depth display area 16b for displaying the water depth of the hook assembly, a fish layer record display area 16c for displaying the position of the fish layer, a water bottom record display area 16d for displaying the water bottom, and a stop number display area 16e for displaying the position of the shift lever 14 by the stop number. The water depth display unit 16a calculates the length of the fishing line paid out from the electric reel 100 based on, for example, the rotation speed of the spool 2 and the barrel diameter, and displays the calculated value. The water depth information displayed on the water depth display unit 16a may be a distance to the hook unit based on the water surface or a distance to the hook unit based on the water bottom.

A plurality of switch operation portions 17 are provided on the rear side of the display portion 16, and the plurality of switch operation portions 17 are used for changing the control state and performing various settings. A control unit 21 (see fig. 3) for controlling the electric reel 100 is housed in the counter case 5.

The control unit 21 controls the electric reel 100 by the electric power supplied from the external power supply PS. The control section 21 has a microcomputer including a CPU having an arithmetic function, a RAM, a ROM, an I/O interface, and the like. As shown in fig. 3, the control unit 21 includes: a motor control unit 21a that performs PWM control of the motor 8; and a water depth display control unit 21b for displaying information on the water depth of the hook assembly on the water depth display unit 16 a.

The control unit 21 is connected to the shift lever 14, the switch operation unit 17, the spool sensor 22, and the spool counter 23. The display unit 16, the motor drive circuit 24, the storage unit 25, the time measurement unit 26, and the backup power supply 27 are connected to the control unit 21.

The bobbin sensor 22 is constituted by 2 reed switches (reed switches) arranged in tandem, and detects the rotation direction of the bobbin 2 according to which reed switch first generates a detection pulse. The spool sensor 22 detects the rotation speed of the spool 2 based on the detection pulse. The bobbin counter 23 is a counter that counts the detection pulses, and can obtain rotation data of the bobbin 2 based on the counted value. The fishing line length is calculated from the rotation data, and information on the water depth is displayed on the water depth display unit 16a based on the calculated value.

The motor drive circuit 24 PWM-drives the motor 8. The motor drive circuit 24 controls a duty ratio (duty ratio) by the control section 21. The control section 21 controls the motor 8 in any one of a speed constant mode and a tension constant mode.

The storage unit 25 is constituted by a nonvolatile memory such as a ROM or a flash memory. The storage unit 25 stores information related to control information of the electric reel 100, and the information related to control information of the electric reel 100 includes water depth information related to the water depth of the hook assembly displayed on the water depth display unit 16 a. The information related to the control information may include control information such as a display mode of the water depth display unit 16a and a control mode of the motor 8. The time information when the information related to the control information of the electric reel 100 is stored in the storage unit 25 based on the time measured by the time measuring unit 26 described later.

The time measuring unit 26 measures the power cut-off time T from when the supply of power from the external power supply PS to the control unit 21 is cut off to when the supply of power from the external power supply PS to the control unit 21 is restarted. In the present embodiment, the time measurement unit 26 includes a real-time clock (RTC) 26a for measuring time. When the supply of power from the external power supply PS to the control unit 21 is interrupted, the time measurement unit 26 continues to measure the time by the power supplied from the backup power supply 27.

In the present embodiment, the backup power supply 27 is a Capacitor, and an Electric Double Layer Capacitor (EDLC) is used. The backup power supply 27 supplies power to the time measuring unit 26 and operates the time measuring unit 26 at least while the power supply from the external power supply PS to the control unit 21 is interrupted. In the present embodiment, while the external power supply PS supplies power to the control unit 21, the external power supply PS supplies power to the time measurement unit 26. During this time, the backup power supply 27 is charged by the external power supply PS. Further, while the power is supplied from the external power supply PS to the control unit 21, the power may be supplied from the backup power supply 27 to the time measurement unit 26 to operate the time measurement unit 26.

[ for backup processing ]

Next, the flow of the backup process by the control unit 21 will be described with reference to the flowchart of fig. 4. Here, water depth information relating to the water depth of the hook assembly will be described as an example of control information relating to control of the electric reel 100.

In step S1, when the electric reel 100 is started, the time measuring unit 26 starts measuring the time. At this time, power is supplied from the external power supply PS to the control unit 21. When the time measuring unit 26 measures the time based on the power supplied from the backup power supply 27 when the electric reel 100 is started, the time measuring unit 26 continues to measure the time based on the time information.

In step S2, the water depth information is stored in the storage unit 25. The storage of the water depth information into the storage unit 25 is performed periodically while the electric power is supplied from the external power supply PS, and the stored information is updated every time the water depth information is periodically stored. The time point at which the water depth information is stored is, for example, every predetermined time, every time the water depth information changes, or when the switch operating unit 17 is operated. In step S2, the storage time T1 when the water depth information is stored in the storage unit 25 based on the time measured by the time measuring unit 26.

In step S3, it is determined whether or not the supply of electric power from the external power supply PS to the control unit 21 is cut off. When it is determined that the supply of electric power from the external power supply PS to the control unit 21 is not cut off, the backup process is not executed. When determining that the supply of electric power from the external power supply PS to the control unit 21 is cut off, the process proceeds to step S4.

In step S4, power is supplied from backup power supply 27 to only time measurement unit 26. Accordingly, the time measurement unit 26 continues to measure the time even after the supply of power from the external power supply PS to the control unit 21 is cut off.

In step S5, it is determined whether or not the supply of electric power from the external power supply PS to the control unit 21 has been restarted. When determining that the supply of electric power from the external power supply PS to the control unit 21 has been restarted, the process proceeds to step S6. In other words, when electric power is supplied from the external power supply PS to the control unit 21, the process proceeds to step S6. If the supply of electric power from the external power supply PS to the control section 21 is not restarted, the backup process is not executed.

In step S6, a restart time T2 at which the supply of electric power from the external power supply PS to the control unit 21 is restarted is first determined based on the time measured by the time measuring unit 26. Then, the power cut-off time T from when the power supply from the external power supply PS is cut off to when the power supply from the external power supply PS is restarted is calculated from the difference between the storage time T1 and the restart time T2. Here, the storage time T1 is regarded as time information when the power supply is cut off, and the power cut-off time T is calculated.

In step S7, it is determined whether or not the power shutoff time T calculated in step S6 is within a predetermined range. When it is determined that the power shutoff time T is within the predetermined range, the routine proceeds to step S8. The specified range here is, for example, 6 hours. In step S8, the water depth information stored in step S2 is displayed on the water depth display unit 16a, and the electric reel 100 is controlled based on the water depth information stored in step S2. That is, the backup processing is performed here.

When it is determined in step S7 that the power shutoff time T exceeds the predetermined range, the routine proceeds to step S9. In step S9, the water depth information stored in step S2 is deleted. Even when the time data measured by the time measurement unit 26 is initialized, that is, when the power supply from the external power supply PS to the control unit 21 is interrupted for a long time and the backup power supply 27 is lost, the water depth information stored in step S2 is deleted as if more time than necessary has elapsed.

By performing the backup processing described above, the following effects can be obtained. First, the power consumption of the circuit of the real-time clock 26a is small, and at step S4, power is supplied only to the time measuring unit 26 from the backup power supply 27. Accordingly, the backup power supply 27 can use an electric double layer capacitor having a small capacity, and thus the backup power supply 27 can be downsized.

In general, the electric double layer capacitor having a large internal resistance has a smaller volume than the electric double layer capacitor having a small internal resistance. In the present embodiment, when the supply of electric power from the external power supply PS to the control unit 21 is interrupted, electric power is not supplied from the backup power supply 27 to the control unit 21, and therefore, an electric double layer capacitor having a large internal resistance can be used as the backup power supply 27. That is, a small electric double layer capacitor can be used as the backup power supply 27.

Further, by using the real-time clock 26a in the time measurement unit 26, even when the electric double-layer capacitor is used in the backup power supply 27, the time range up to the loss of the backup power supply 27 does not change greatly due to environmental differences such as temperature conditions or individual differences. Therefore, the backup time can be controlled with high accuracy. When the supply of power from the external power supply PS to the control unit 21 is interrupted for a long time and the backup power supply 27 is lost, the time measured by the time measuring unit 26 is initialized. Therefore, it is easy to determine whether or not the backup power supply 27 is lost after the power supply to the control unit 21 is cut off until the power supply to the control unit 21 is restarted, and it is possible to accurately determine whether or not to execute the backup process.

< other embodiments >

While one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the scope of the invention. In particular, the embodiments described in the present specification can be combined as desired.

(a) In the above embodiment, the storage unit 25 is configured by a nonvolatile memory, but the storage unit 25 may be configured by a volatile memory. In this case. When the supply of electric power from the external power supply PS to the control unit 21 is cut off, electric power is supplied from the backup power supply 27 to the storage unit 25 and the time measurement unit 26. In the case where the storage unit 25 is formed of a volatile memory, it is necessary to use a volatile memory whose operating voltage is surely lower than that of the time measurement unit 26.

(b) In the above embodiment, the backup power supply 27 uses a capacitor, but a primary battery such as a manganese dry cell battery or a secondary battery such as a nickel-cadmium battery may be used as the backup power supply 27.

(c) In the above embodiment, the storage of the water depth information is periodically executed in step S2, but the storage of the water depth information in the storage unit 25 may be controlled as follows: when determining that the supply of electric power from external power supply PS to control unit 21 is interrupted, the water depth information and storage time T1 at that time are stored in storage unit 25. The time measurement unit 26 may start measurement of time after the power supply from the external power supply PS to the control unit 21 is cut off, or may start measurement of time by a timer or the like.

(d) In the above-described embodiment, the time measuring unit 26 measures the time from when the storage unit 25 stores the control information to when the supply of power from the external power supply PS to the control unit 21 is restarted, but the time measured by the time measuring unit 26 is not limited to this. For example, the time from when the supply of electric power from the external power supply PS to the control unit 21 is cut off to when the supply of electric power from the external power supply PS to the control unit 21 is restarted may be measured, and the control unit 21 may execute the backup process when the measured time is within a predetermined range.

Claims

1. A backup system of an electric fishing reel is characterized in that,

comprises a control unit, a storage unit, a time measuring unit, and a backup power supply,

the control part controls the electric fishing reel through the electric power supplied by an external power supply;

the storage unit stores control information related to control of the electric reel;

the time measuring unit measures a power cut-off time from when the power supply from the external power source is cut off to when the power supply from the external power source is restarted;

the backup power supply is configured to operate the time measurement unit at least while the power supply from the external power supply is interrupted,

the control unit controls the electric reel based on the control information stored in the storage unit when the power cut-off time is within a predetermined range, and deletes the control information stored in the storage unit when the power cut-off time exceeds the predetermined range.

2. The backup system of an electric reel according to claim 1,

the time measurement unit has a real-time clock, and measures the power interruption time based on time information when the power supply from the external power source is interrupted and time information when the power supply from the external power source is restarted.

3. The backup system of an electric fishing reel according to claim 1 or 2,

the storage section is a volatile memory that is,

the backup power supply supplies power to the storage unit when the external power supply is turned off.

4. The backup system of an electric fishing reel according to claim 1 or 2,

the backup power source is a capacitor.

5. The backup system of an electric fishing reel according to claim 1 or 2,

further comprises a water depth display part for displaying water depth information related to the water depth of the fishhook assembly,

the control unit further includes a water depth display control unit that displays the water depth information on the water depth display unit,

the control information stored in the storage unit includes the water depth information,

when the power cut-off time is within the predetermined range, the water depth display control unit displays the water depth information stored in the storage unit on the water depth display unit.