JP2001136876A - Electric reel for fishing - Google Patents

Abstract

(57) Abstract: The present invention relates to an electric reel for fishing, and provides an electric reel for fishing that enables a good fish taking-in operation by appropriately stopping a boat by an automatic boat-slip stop device. With the goal. A spool is rotatably supported by a reel body, a spool motor that rotates the spool, and a reeling amount and winding amount of a fishing line based on a rotation speed of a rotating body that rotates by reeling out and winding of the fishing line. Measuring means for measuring the take-up speed, a boat stop position, a storage means for storing a motor drive stop position corresponding to the winding speed of the fishing line, and a ship stop position based on the measurement value of the measuring means. Motor stopping means for sending a motor drive stop signal to a spool motor drive circuit at a motor drive stop position corresponding to a winding speed of the fishing line in a predetermined measurement section in front thereof.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement in an electric fishing reel provided with an automatic stop device for a boat.

[0002]

2. Description of the Related Art An electric reel for fishing (hereinafter referred to as an "electric reel") in which a fishing line is wound by a spool motor is generally used when aiming at a deep fish layer such as boat fishing. In recent years, many fishing electric reels have been provided with a fishing line length (amount of feeding) based on the number of rotations of a spool or the like detected by the number of rotations detecting means in order to improve the fishing results by performing accurate shelving. ) Is mounted on the display, and the angler can draw out the device to a predetermined shelf position based on the display.

Conventionally, in consideration of the protection of the rod tip accompanying the automatic winding of the fishing line, the fishing line is wound up based on the measurement value of the line length measuring device (the position of the display value "0" on the display). At the predetermined position before, that is, where it has been wound up to the ship stop position,
2. Description of the Related Art Electric reels provided with a boatslip automatic stop device for automatically stopping a spool motor are widely used.

[0004]

However, conventionally, this type of automatic boat-slip stop device sends a motor stop signal to a motor drive circuit when the device is wound up to the ship-slip stop position. Due to the structure of stopping the spool motor, particularly when the spool motor is stopped during the winding operation at a medium or high speed, the fishing line is overwound due to the overrun of the spool motor. (Retrieving position), and there is a problem that rework is bad.

Japanese Patent Application Laid-Open No. H11-89488 discloses a method for solving such a problem in which a spool motor overruns during actual winding and a device is excessively rolled in from a predetermined ship stop position. In consideration of the excessive winding amount, the motor drive stop position for sending the motor stop signal at the next winding operation is changed so that when the spool is stopped, the device is reliably stopped at the boatslip stop position. There has been proposed an automatic stopping device for a boatslide.

However, since this automatic boat-slip stop device changes the next motor drive stop position on the basis of the actual winding result, overrunning occurs during the first winding operation. There was a defect. For this reason, when excessive winding occurs due to overrun, the fishing line must be pulled out by dragging or the clutch must be turned off to pull out the fishing line from the spool, as in the related art.

[0007] Since this automatic boat-slide stop device does not consider the winding speed of the device at all, if the initial winding speed is high and many windings due to overrun occur, the next winding is stopped. At the time of operation, a motor stop signal will be sent earlier to change the motor drive stop position, but if the actual winding speed next time is slower, the water depth will be deeper than the predetermined boatslip stop position. Since the spool motor stops at the position, problems have been pointed out, such as that the gimmick does not come close to the angler and the return is poor.

The present invention has been devised in view of the above circumstances, and an object of the present invention is to provide an electric reel capable of performing a good fish catching operation by appropriately stopping a boat by an automatic boat bar stop device. .

[0009]

According to a first aspect of the present invention, there is provided an electric reel comprising: a spool rotatably supported by a reel body; a spool motor for driving the spool to rotate; Based on the number of rotations of the rotating body that rotates during feeding and winding, measuring means for measuring the feeding amount and winding speed of the fishing line, a boat stop position, a motor drive stop position according to the fishing line winding speed, and And a spool motor drive circuit at a motor drive stop position corresponding to a fishing line winding speed in a predetermined measurement section before a boat stop position, based on the measurement value of the measurement means. Motor stopping means for sending a motor drive stop signal.

The invention according to claim 2 is based on claim 1.
In the electric reel described above, an overrun yarn length value is detected based on an actual stop position of the boat slide when the spool is stopped measured by the measuring unit and a stop position of the boat slide stored in the storage unit. Means and a motor drive stored in the storage means in accordance with the winding speed of the fishing line based on the overrun line length value so that the actual boatslip stop position coincides with the boatslip stop position at the next winding operation. Motor drive stop position changing means for changing the stop position.

(Operation) According to the electric reel of the first aspect, based on the line length measured by the measuring unit and the winding speed of the fishing line, the motor stopping unit controls the motor drive in accordance with the winding speed of the fishing line. At the stop position, a motor drive stop signal is sent to the spool motor drive circuit to stop the spool motor, and the device is stopped at the boat boat stop position.

According to the second aspect of the present invention, the overrun yarn length value detecting means determines the overrun yarn length value from the actual slippage stop position when the spool stops and the slippage stop position stored in the storage means. Is detected. Then, based on the overrun yarn length value, the motor drive stop position adjusting means controls the motor drive stop at each winding speed such that the actual length of the boat-slip stop coincides with the boat-slip stop position at the next winding operation. Since the position is changed, even if the condition of the fishing ground changes from moment to moment, the device will surely stop at the boat-slip stop position when the spool stops.

[0013]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 shows an embodiment of the electric reel according to claims 1 and 2, wherein 1 is a reel body having side plates 5, 7 mounted on both left and right sides of a frame 3, 9 is a spool, One end of the spool 9 is rotatably supported by the frame 3 via a bracket (not shown), and the other end is a bracket 1 fixed to the spool 9.
1 and a bearing 15 of a set plate 13 attached to the frame 3 so as to be rotatable on the reel body 1.

Reference numeral 17 denotes a spool motor which is mounted in the spool 9 so that the axes thereof are aligned. Between the motor shaft 17a of the spool motor 17 and the spool 9, a sun gear 19, a plurality of planetary gears 21 meshing with the sun gear 19 and the like are provided. Power transmission mechanism 2
3, and the winding power of the spool motor 17 is transmitted to the spool 9 via the power transmission mechanism 23.

The boss 25a of the planetary gear support 25 that supports the planetary gear 21 is relatively rotatably fitted into the boss 11a of the bracket 11 that supports the spool 9. A pinion 29 rotatably supported by a pinion shaft 27 disposed coaxially with the motor shaft 17a and movably supported in the axial direction is clutch-coupled to the planetary gear support 25. A clutch plate 31 for engaging and disengaging the planetary gear support 25 with the planetary gear support 25;
Is arranged.

The clutch plate 31 is a component of a clutch mechanism for transmitting / cutting off the winding power of the spool motor 17 and the manual handle 33 to and from the spool 9, and FIG. 2 shows the clutch mechanism 35 in detail. In FIG. 2, reference numeral 37 denotes a clutch operating plate for operating the clutch plate 31, and the clutch operating plate 37 is
Is formed to be long from the upper rear to the lower front. A long hole 41 through which the handle shaft 39 of the manual handle 33 is inserted is provided at the center of the clutch operation plate 37.
Are formed, and two cams 4 are sandwiched between the long holes 41.
3 are provided.

Further, a lower front side plate 5 of the reel body 1 is provided.
A clutch driving motor (hereinafter, referred to as a “clutch motor”) 45 is mounted between the clutch motors 7.
, And the clutch is turned on / off. That is, as shown in FIG.
Is equipped with a speed reduction mechanism 47,
A pin 51 attached to the lever 49 is engaged with a long hole 53 provided on the rear end side of the clutch operation plate 37. The clutch motor 45 is driven by the operation of a clutch switch 59 provided on an operation panel 57 on the control box 55 shown in FIG. 1, and the clutch motor 47 is rotated by the operation of the clutch switch 59. Then, when the lever 49 moves in the direction of arrow C in FIG. 2, the clutch operating plate 37 moves in the direction of arrow A.

The clutch plate 39 is urged in the direction of the clutch operating plate 37 by the coil spring 61. When the clutch operating plate 37 moves in the direction of arrow A by the rotation of the clutch motor 45 as described above, the coil spring Cam 4 against spring force of 61
3 moves the clutch plate 31 in the axial direction of the pinion shaft 27, the clutch plate 31 moves the pinion 29 in the axial direction of the pinion shaft 27, and releases the clutch connection with the planetary gear support 25 (clutch OF
F).

A magnet 63 is mounted on one side edge of the clutch operating plate 37, and the reed switch 6 is turned on / off by the magnet 63.
Reference numerals 5 and 67 are arranged on the guide member 69 of the clutch operation plate 37 corresponding to ON / OFF of the clutch. Then, as shown in FIG. 2, the clutch operating plate 37 is moved in the direction of arrow B by the rotation of the clutch motor 45 in the direction of arrow D by the operation of the clutch switch 59, and the displacement of the clutch plate 31 by the cam 43 is released. Then, the clutch plate 31 causes the pinion 29 to be clutch-coupled to the planetary gear support 25 by the restoring force of the coil spring 61, and the clutch is turned ON. At this time, the reed switch 65 is turned ON by the magnet 63, and the clutch motor 45 is stopped by a command from the control device (microcomputer) 71 in the control box 55 to which the signal is input.

Similarly, when the clutch operating plate 37 is moved in the direction of arrow A by the rotation of the clutch motor 45 in the direction of arrow C and the clutch is turned off, the reed switch 67 is turned off.
Is turned ON by the magnet 63 and the clutch motor 45
Are stopped by a command from the control device 71. In FIG. 1, reference numeral 33 denotes a manual handle for winding the fishing line.
The manual handle 33 is connected to the outside end of the side plate 7 of the handle shaft 39 rotatably attached to the set plate 13.

The handle shaft 39 is provided with a ratchet 73 for preventing the spool from rotating in the reverse direction, and a drive gear 75 is rotatably mounted on the handle shaft 39. A conventional well-known drag (not shown) is provided between the drive gear 75 and the handle shaft 39. The winding power of the manual handle 33 is transmitted to the drive gear 75 by being frictionally coupled by the device. And
As shown in FIG. 2, a locking claw 77 urged by a spring (not shown) is in contact with the ratchet wheel 73, and the locking claw 77 is pivotally attached to the set plate 13 by a pin 79. I have.

On the other hand, in FIG. 1, reference numeral 80 denotes a rotation sensor (rotation speed detecting means) for detecting the rotation speed and the rotation direction of the spool 9. The rotation sensor 80 includes a pair of lead switches 81 mounted on the frame 3. 4 and a plurality of magnets 83 fixed to the peripheral edge of one end of the spool 9 in opposition thereto. The reed switch 81 is connected to the CPU via the input interface of the control means 71 as shown in FIG. It is connected.

The control means 71 is disclosed in Japanese Unexamined Patent Application Publication No.
As with the fishing reel disclosed in Japanese Patent No. 3567, a determination signal of forward rotation and reverse rotation of the spool 9 output from the reed switch 81 is taken in to determine whether the fishing line 85 is to be fed or wound, and the reed switch 81 The rotation pulse signal of the spool 9 taken in from the controller is counted, and the thread length calculation formula stored in the ROM of the control means 71 is calculated and executed based on the counted value.

The control means 71 controls the display drive circuit 8
7, the calculation result is displayed on a display 89 on the operation panel 57.
In addition to the automatic stop of a boatslide described later in consideration of the protection of the rod tip accompanying the winding of the fishing line 85, the fishing line 85 is used for shelving the fishing line 85 when it is fed. That is, as shown in FIG. 6, the display 89 is provided with a line length display portion 89a for displaying the line length of the fishing line 85 and a shelf display portion 89b for displaying the shelf position. For example, as shown in FIG. When the fishing line 85 (the tackle 90) is paid out from the rod tip 91 to the sea surface 93 one meter below, the control means 71 calculates the feeding amount of the fishing line 85 based on the rotation pulse signal from the reed switch 81, and the calculation result is As shown in FIG. 6, they are displayed on both display sections 89a and 89b.

On the other hand, as shown in FIG. 1, the display values of both display portions 89a and 89b are displayed on the operation panel 57, respectively.
Set switches 95 and 97 for setting to “0.0M” are mounted. Then, when the set switch 95 is operated in the display state of FIG. 6 and the display value of the line length display portion 89a is set to “0.0M” as shown in FIG. 7, the fishing line 85 is extended by, for example, 125 m as shown in FIG. , Both display sections 89a, 89b
Is displayed as shown in FIG. 8, and in this state, if the set value of the shelf display section 89b is set to "0.0M" as shown in FIG.
Is stored in the RAM as the shelf position E.

When the fishing line 85 is wound from the shelf position E, the control means 71 calculates the winding amount of the fishing line 85 based on the rotation pulse signal from the reed switch 81, and displays the line length. The display value of the section 89a is sequentially reduced from "125.0M", and the display value of the shelf display section 89b is sequentially increased from "0.0M" to display the distance from the shelf position E. ing.

Then, as in the prior art, when the device 90 is extended to the shelf position E in the subsequent extending operation, the control means 7 is controlled.
1 is configured to send a command to the clutch motor drive circuit 99 to drive the clutch motor 45 and stop the feeding of the fishing line 85 by connecting the clutch. On the other hand, an auto switch 101 and a manual switch 103 are mounted on the operation panel 57 as shown in FIG.
By these operations, the spool motor 17 is driven and the fishing line 85
Is wound up.
As shown in FIG. 7, the OM is set at a position 2 m below the water depth with the display value "0.0M" of the thread length display section 89a set by the set switch 95 as the winding end (the thread length display section 8).
9a) is stored in advance as a boat stop position F at the time of shipment from the factory.

In consideration of the overrun of the spool motor, the CPU of the control means 71 sets the spool from the reed switch 81 described above as a measurement section 10 m before the boat stop position F as shown in FIG. The winding speed of the fishing line 85 is measured based on the rotation pulse signal 9 and a built-in timer. And RO of the control means 71
In M, at the factory stage, a predetermined water depth before the boat stop position F shown below is stored as a motor drive stop position G for each winding speed of the fishing line 85, and the winding speed (m / s) Motor drive stop position (cm) 0.5 +5 1.0 +10 1.5 +20 2.0 +30 2.5 +40:::: Spool motor 17 is driven by operation of auto switch 101 or manual switch 103. When the fishing line 85 is wound around the spool 9, the control means 71
The winding speed of the fishing line 85 in a measurement section 10 m before the boat stop position F shown in FIG. 5 is measured. For example, if the winding speed is 0.5 m / s, the fishing line 85 is moved to the boat stop position. Motor drive stop position G 5 cm before F (thread length display section 89
When the winding speed is 2.0 m / s, if the winding speed is 2.0 m / s, a fishing line is sent to the spool motor drive circuit 105 in FIG. When the motor 85 is wound up to the motor drive stop position G 30 cm before the boat stop position F (the display value "2.3M" on the yarn length display portion 89a), a motor stop command is sent out to cause the spool motor 17 to rotate. It is designed to stop.

As described above, in the present embodiment, the winding speed is reduced by transmitting the motor stop command at the motor drive stop position G corresponding to the winding speed of the fishing line 85 in consideration of the overrun of the spool motor 17. Even if it changes, the gimmick 90 is surely stopped at the boat stop position F when the spool stops. Further, since the conditions of the fishing spot and the mechanism change every moment, for example, as shown in FIG.
When the speed is 5 m / s, even if the control means 71 sends a motor stop command to the spool motor drive circuit 105 at the motor drive stop position 20 cm before the boat stop position F, the boat stop position F is exceeded by 10 cm. Sometimes they run.

Therefore, in the present embodiment, based on the yarn length measurement value, the control means 71 further acts as an overrun yarn length value detection means so that the actual boat stop actual stop position (the tackle 90) when the spool stops.
The actual run stop position at the time of spool stop, that is, the spool stop position, that is, the spool stop position F, is detected from the ship stop position F stored in the ROM. Assuming that the display value of the yarn length display section 89a at the time of stop is "1.9M", the control means 71 calculates 2.2-1.9 = 0.3 (m) to obtain the overrun yarn. Detect the long value.

Then, the control means 71 calculates 2.0 + 0.3 = 2.3 (m) as a motor drive stop position adjusting means based on the detected overrun yarn length value "0.3 m". Winding speed stored in ROM
Motor drive stop position G for 5m / s from + 20cm to +
Change to 30 cm and store this in RAM. And
When the next winding speed is 1.5 m / s, a motor stop command is sent to the spool motor drive circuit 105 at the water depth of the display value “2.3 M” of the yarn length display portion 89 a. I have.

The control means 71 sets the actual stop position at the time of spool stop and the RO
The overrun yarn length value is detected from the slip stop position F stored in M. For example, when the next winding speed is 1.5 m / s, the yarn length display section when the spool is stopped If the indicated value of 89a is "2.0M", the overrun yarn length value is "0", so that the motor drive stop position G (+30 cm) corresponding to the winding speed of 1.5 m / s is corrected. If the thread length display section 89a when the spool is stopped displays "1.9M", the control means 71 executes the equation 2.3-1.9 = 0.4 (m). Then, based on the overrun yarn length value, the motor drive stop position corresponding to the winding speed of 1.5 m / s stored in the RAM is obtained from the equation of 2.0 + 0.4 = 2.4 (m). G from + 30cm to +4
Change to 0cm.

Therefore, if the next winding speed is 1.5 m / s, the control means 71 instructs the spool motor drive circuit 105 to stop the motor at the display value "2.4 M" of the yarn length display section 89a. Will be sent. On the other hand, if the display value at the time of stopping the spool is not "1.9M" but "2.1M", then 2.3-2.1 = 0.2 (m) and overrun yarn Since the length value has changed for some reason, the motor drive stop position G corresponding to the winding speed of 1.5 m / s stored in the RAM is obtained from the equation 2.0 + 0.2 = 2.2 (m). From + 30cm to +20
cm, and when the next winding speed is 1.5 m / s, a motor stop command is sent to the spool motor drive circuit 105 with the display value "2.2M" of the thread length display section 89a. ing.

Thereafter, the control means 71 repeats the above-described procedure, and after finishing the fishing, the angler operates the main switch 107 on the operation panel 57 to turn the electric reel 109 off.
When set to FF, the correction data in the RAM is erased.

In addition, in FIG.
The electric reel 109 is connected to a battery or the like disposed on the ship via the connector 113. Since the present embodiment is configured as described above, when fishing, the main switch 107 is operated to activate the spool motor 17, the clutch motor 45, the control device 71, and the like, and then the mechanism 90 is extended to the shelf position E. Just wait for the fish to hit.

When the fisher hits the fish and operates the auto switch 101 or the manual switch 103, the spool motor 17 is driven and the fishing line 85 is wound.
In addition to performing the line length measurement based on the rotation pulse signal, the winding speed of the fishing line 85 is measured in a measurement section 10 m before the boat stop position F. For example, if the winding speed is 0.5 m / s, When the fishing line 85 has been wound up to the motor drive stop position G 5 cm before the boat stop position F, a motor stop command is sent to the spool motor drive circuit 105 to stop the spool motor 17 and rewind. If the speed is 2.0 m / s, the motor stop command is sent out at the motor drive stop position G 30 cm before the boat stop position F and the spool motor 17 is stopped.

At the same time, the control means 71 determines, based on the measured yarn length, the actual stop position at the time of stopping the spool,
The overrun yarn length value is detected from the boat stop position F stored in the ROM, and for example, as shown in FIG.
When the fishing line 85 has been wound up to the boatslip stop position F at the winding speed of s, the display value of the line length display portion 89a becomes "1.9M".
, The control means 71 performs an operation of 2.2-1.9 = 0.3 (m) to detect the overrun yarn length value, and then calculates 2.0 + 0.3 = 2.3 (m). m) and the winding speed 1. stored in the ROM.
The motor drive stop position G corresponding to 5 m / s is changed from +20 cm to +30 cm, and this is stored in the RAM.

Therefore, when the next winding speed is 1.5 m / s, the control means 71 issues a motor stop command to the spool motor drive circuit 105 at the water depth of the display value "2.3 M" of the yarn length display section 89a. And the spool motor 17 is stopped. Then, the control means 71 controls the fishing line 85
In each take-up operation, the overrun yarn length value is detected from the actual slippage stop position when the spool is stopped and the slippage stop position F stored in the ROM and RAM. In the case of s, if the display value of the thread length display section 89a when the spool is stopped is "2.0M", the overrun thread length value is "0", so that the winding speed of 1.5 m / s. The motor drive stop position G (+30 cm) corresponding to (1) is not corrected, and the thread length display section 89a when the spool is stopped indicates "1.
If “9M” is displayed, the control means 71 calculates and executes the equation of 2.3-1.9 = 0.4 (m), and based on this overrun yarn length value, 2.0 + 0. From the equation of 4 = 2.4 (m), the motor drive stop position G for the winding speed of 1.5 m / s stored in the RAM is changed from +30 cm to +40.
cm.

Accordingly, when the next winding speed is 1.5 m / s, the control means 71 instructs the spool motor drive circuit 105 to stop the motor at the display value "2.4 M" of the thread length display section 89a. Will be sent. On the other hand, if the display value at the time of stopping the spool is not "1.9M" but "2.1M", then 2.3-2.1 = 0.2 (m) and overrun yarn Since the length value has changed for some reason, the motor drive stop position G for the winding speed of 1.5 m / s was changed from +30 cm to +20 cm from the equation of 2.0 + 0.2 = 2.2 (m). If the next winding speed is 1.5 m / s, the control means 71
The motor stop command is sent to the spool motor drive circuit 105 with the display value "2.2M" of the thread length display section 89a.

Thereafter, the control means 71 repeats the above-described procedure, and when the angler operates the main switch 107 to turn off the electric reel 109, the correction data in the RAM is erased and thereafter stored in the ROM. At the initial motor drive stop position G, the control means 71 repeats the above procedure again while sending a motor stop command to the spool motor drive circuit 105.

As described above, according to the present embodiment, in order to protect the rod tip accompanying the automatic winding of the fishing line 85 by the spool motor 17, the overshoot of the spool motor 17 at the time of the stoppage of the boat boat is taken into consideration. Before F, a motor drive stop position G corresponding to the winding speed of the fishing line 85 is set, and the control means 71 overruns from the actual ship stop position when the spool stops and the ship stop position F stored in the ROM. The line length value is detected, and based on the overrun line length value, the motor drive stop position G corresponding to the winding speed of the fishing line 85 is adjusted so that the actual boatslide stop position is set at the next winding operation. Since the configuration is made to coincide with the sliding stop position F, it is possible to prevent the occurrence of winding due to overrun from the first winding operation.

According to the present embodiment, even if the winding speed of the fishing line 85 changes each time, or if the fishing ground and the state of the tackle change every moment, there is no excess or shortage. The device 90 can be stopped at the predetermined boat stop position F. As a result, as compared with the conventional example disclosed in Japanese Patent Application Laid-Open No. 11-89488, the device 90 can surely come to the angler at the time of catching fish. As a result, a series of operations such as winding, setting of a device, and feeding can be more easily performed.

In the above embodiment, the set switch 9
The display value "0.0M" of the thread length display section 89a set in step 5
With the winding end as the end of the water, the position at a depth of 2 m before that is stored in advance in the ROM as the boat stop position F, and the motor drive stop position G corresponding to the winding speed of the fishing line 85 is stored in the ROM in advance. The angler's input operation may be used to arbitrarily set the boat stop position F and the motor drive stop positions G.

Further, for example, after winding is stopped at a predetermined water depth (1 to 5 m) for a predetermined time (10 to 15 seconds), the control means 71 detects the clutch OFF state (the clutch by the reed switches 65 and 67). When the OFF is detected or the rotation of the spool 9 in the feeding direction is detected by the reed switch 81), the position may be stored in the RAM as the boat-slip stop position F.

Therefore, according to each of these embodiments,
As in the above embodiment, the intended purpose can be achieved.

[0046]

As described above, according to the electric reel of the first aspect, it is possible to prevent the occurrence of winding due to overrun from the time of the first winding operation, and to wind the fishing line. Even if the speed changes each time, the gimmick can be stopped at the specified boat stop position,
A series of operations such as winding, device setting, and feeding can now be performed more easily than in the past.

According to the second aspect of the present invention, even if the fishing ground and the state of the tackle change moment by moment, the tackle can be stopped at a predetermined boat stop stop position so that there is no excess or deficiency. There is an advantage that a simple fish taking operation can be easily performed.

[Brief description of the drawings]

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

FIG. 2 is a partially cutaway side view of the electric reel shown in FIG. 1;

FIG. 3 is a sectional view taken along line III-III of FIG. 2;

FIG. 4 is a control block diagram of the electric reel shown in FIG. 1;

FIG. 5 is an explanatory diagram of a shelf position, a boat stop position, a motor drive stop position, and a measurement section.

FIG. 6 is an explanatory diagram of a display state of a thread length display section and a shelf display section of the digital display.

FIG. 7 is an explanatory diagram of a display state of a thread length display section and a shelf display section of the digital display.

FIG. 8 is an explanatory diagram of a display state of a thread length display section and a shelf display section of the digital display.

FIG. 9 is an explanatory diagram of a display state of a thread length display section and a shelf display section of the digital display.

FIG. 10 is an explanatory diagram of a method of correcting a motor drive stop position.

[Explanation of symbols]

 Reference Signs List 1 reel body 9 spool 17 spool motor 31 clutch plate 35 clutch mechanism 37 clutch operating plate 45 clutch motor 57 operation panel 65, 67, 81 reed switch 71 control means 80 rotation sensor 85 fishing line 89 indicator 90 device 109 electric reel E shelf position F Shipyard stop position G Motor drive stop position

Claims (2)

[Claims] 1. A spool rotatably supported by a reel body, a spool motor for rotating the spool, and a feed amount of a fishing line based on a rotation speed of a rotating body which rotates by feeding and winding the fishing line. Measuring means for measuring the take-up speed; storage means for storing a boat-slip stop position; and a motor drive stop position corresponding to the fishing line take-up speed; and a ship-slip stop position based on the measurement value of the measuring means. A motor stop means for sending a motor drive stop signal to a spool motor drive circuit at a motor drive stop position corresponding to the winding speed of the fishing line in a predetermined measurement section before the fish. Electric reel for fishing. 2. An overrun yarn length value detecting means for detecting an overrun yarn length value based on an actual rung stop position at the time of stopping the spool measured by the measuring means and a hull stop position stored in the storage means. Based on the overrun line length value, the motor drive stop position stored in the storage means is determined based on the overrun line length value so that the actual boatslip stop position matches the boatslip stop position at the next winding operation. The electric reel for fishing according to claim 1, further comprising: a motor drive stop position changing unit that changes the motor drive stop position.