JPH02119737A - Motor-driven reel - Google Patents

Abstract

PURPOSE:To carry out pulsing a rotational speed corresponding to the kind or weight of a fish by setting the rotational speed of a motor in pulsing at a rotation speed, indicated by an inputting means and optimum for drawing the fish near just before stopping a motor. CONSTITUTION:When a fish is taken in by pulsing, a motor 16 is once stopped with a stopping switch. The rotational speed of the motor 16 in stopping the motor is memorized in a RAM 42 by a CPU 38. In this state, the stopping switch is connected or disconnected to pulse the motor 16. Thereby, the motor 16 is pulsed at the rotational speed memorized in the RAM 42 to carry out winding.

Description

[Detailed description of the invention] (Industrial application field) The present invention relates to an electric reel.

(Prior Art) When a large amount of fishing line is fed out, such as when fishing on a boat at sea, an electric reel using a motor is used to wind up the fishing line. In conventional electric reels, there are two types of reels: one is to continuously wind up a spool with fishing line wound around it using a motor, and the other is to rotate the motor little by little and unwind the fishing line little by little. If the motor is continuously rotated when taking in or attracting fish, it will simply wind up the fishing line into a tonne, but it will not be possible to finely control the amount of fishing line let out, and the fish will often be missed. was suggested. The instantaneous motion allows the motor to rotate for an appropriate short period of time by operating a switch, making it possible to wind up fishing line little by little.

(Problems to be Solved by the Invention) However, the conventional electric reel described above has the following problems.

The rotational speed of the motor during instantaneous motion is the same rotational speed as when winding up the fishing line continuously. Conventionally, the rotational speed of the motor was constant, and the instantaneous motion was performed at that rotational speed. However, if the rotational speed of the motor is high, the torque for hoisting will be large, and if the pulling force is too strong for fish or squid that have weak mouths, the hook may come off. On the other hand, if the rotational speed of the motor is slow, there is a problem that large fish cannot be attracted because the 1-luke of winding is small.

Therefore, an object of the present invention is to provide an electric reel in which the rotational speed of the motor during instantaneous motion can be varied.

(Means for solving problems) In order to solve the above problems, the present invention includes the following configuration.

That is, in an electric reel in which a motor rotates a spool around which a fishing line is wound, an input means for issuing a signal instructing the rotational speed of the motor, and at least an input means for outputting a signal indicating the rotational speed of the motor, and an input means for outputting a signal indicating the rotational speed of the motor, and at least an input means for outputting a signal indicating the rotational speed of the motor, a storage means for storing the rotational speed; a flashing instruction means for issuing a signal for flashing the rotation of the motor r6i; When the motor is rotated and the rotational speed is stored in the first storage stage, and a signal instructing the spinning is input from the spinning instruction means to reel the fishing line after the motor has stopped. The motor is characterized by comprising a control means for instantaneously rotating the motor at the rotational speed stored in the storage means.

(effect) The effect will be explained.

The rotational speed of the motor when performing the instantaneous motion can be the rotational speed instructed by the input means that is stored in the storage means and is optimal for pulling the motor just before it stops.

(Embodiments) Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 shows a plan view of the electric reel 10 of this embodiment.

Reference numeral 12 denotes a spool which can be rotated in forward and reverse directions and around which the fishing line 14 is wound. The spool 12 is a DC motor 16
, so that the spool 12 can wind up the fishing line 14.

Reference numeral 18 denotes an operation section, which is provided with a speed setting switch 20, 22, 24 that is an input means, a stop switch 26 that is also a flash instruction means, and an LCD display 28 that displays the amount of the fishing line 14 being fed out, etc. There is. A detection section (not shown), which will be described later, is provided on the back side of the operation section 18. The detection section includes a rubber roller that is brought into contact with the outer periphery of the spool 12 around which the fishing line 14 is wound and rotates as the spool 12 rotates. Furthermore, the detection section is provided with a Hall element that rotates with the rotation of the roller and emits a signal when it comes into contact with and separates from a fixed magnet.

By analyzing the output pattern of the Hall element and determining the rotation speed and rotation direction of the roller, it is possible to determine the amount of the fishing line 14 to be let out and whether it is being let out or wound up. This determination is also made by a microcomputer system (described later) included in an electric circuit section provided on the back side of the operation section 18.

Next, the electrical configuration will be explained together with the block diadam of FIG. 2.

A power source 28 is a DC power source such as a battery, and is supplied with a predetermined DC voltage by a DC stabilizing circuit 30 consisting of a three-terminal regulator or the like.

32 is the above-mentioned detection section, and the rising month, month, and H2 from the Hall element are sent to the microcomputer system 34 as measurement data.

The microcomputer system 34 includes an amplifier circuit 36 that amplifies the output H1H2 of the Hall element inputted from the detection unit 32, a CPU 38 that is a control means, a program that presets the operation of the CPU 38, and various preset data. The stored ROM40 and details will be described later,
A RAM 42 is included as a storage means for temporarily storing information processed by the CPU 38.

44 is an input key, which is the speed setting switch 20.2 mentioned above.
2.24, a stop switch 26, etc. are included. switch 2
0 is a switch that inputs to the CPU 38 a signal for switching the rotational speed of the motor 16 to high speed mode or low speed mode by turning ON10FF of the motor 16 and sliding it left and right.

The switch 22 sends a CP signal so that the rotational speed of the motor 16 decreases in proportion to the time it is pressed when the motor 16 is in the low speed mode.
03B, and when the motor j6 is OFF, the water depth of the shelf is stored in the RAM 42 and stored.

The switch 24 sends a signal that causes the rotation speed to increase in proportion to the time the motor 16 is pressed in low speed mode (CI).
When the motor 16 is OFF and the motor 16 is OFF, the RAM 4 is
This is a switch that clears the water depth of the shelf set to 2 to zero. The switch 26 is a switch that not only stops the rotation of the motor 16 but also inputs a signal to the CP LJ 38 that causes the motor 16 to spin only while the switch is pressed. It goes without saying that the arrangement and functions of the switches are not limited to those described above.

In addition, in the rotation of the motor 16, high speed motor refers to a state in which the rotation speed of the motor 16 is the highest, and low speed mode refers to a state in which the rotation speed of the motor 16 in the high speed mode is 1o.

When expressed as %, it refers to a rotation speed of about 60% to 98%. However, the setting range of the low speed mode may be set arbitrarily from 0% to 99%. In this embodiment, in the low speed mode, the speed can be changed in about 100 steps using the switches 22 and 24.

Next, the contents stored in the RAM 42 will be explained.

First, in the RAM 42, the amount of the fishing line 14 to be let out, which is obtained by processing the data of the outputs 11 and H2 of the Pol element detected by the detection unit 32, by the CPU 38, is stored and updated every moment as the information processing is performed. Ru. Also, motor 1
The rotation speed of 6 is also stored and updated. In addition, in the case of low speed mode, the initial setting value of the rotation speed of the motor 16 is stored in the ROM.
For example, it is set to 70% by the 40 programs. Additionally, the RAM 42 stores a reference feeding amount and a value for determining whether to reduce the rotational speed of the motor 16 to a low speed or to the speed just before the motor 16 stops when performing instantaneous motion after the motor 16 once stops. The judgment value is also stored. The judgment value can be arbitrarily set using an input switch (not shown).Next, the automatic speed selection at the time of instantaneous motion, which is a feature of the present invention, will be explained with reference to the flowchart of FIG.

First, the operation when lowering the fishing line 14 to a predetermined water depth (shelf) will be described. Here, it is assumed that the judgment value stored in the RAM f12 is 10 m and the target water depth is 150 m. Before letting out the fishing line 14, the judgment value is manually stored in the RAM 42. Then, the fishing line 14 is let out by the gravity of the weight. Then, the data measured by the detection unit 32 is sent to the CPU 38 and processed, and the amount of the fishing line 14 fed out is also stored and updated in the RAM 42 every moment (step 100). Since the payout amount and the judgment value do not become equal until the payout amount of the fishing line 14 reaches the judgment value of 10 m (step 1o2), the CPU 38 makes a judgment to stop the motor (step 112). However, since the motor 16 is not operating during feeding, no processing is performed. Further, the fishing line 14 is let out, and the amount of the fishing line 14 is 1.
When it reaches 0 m (step 1O2), the detection unit 32 determines the rotational direction of the spool 12 from the rotational direction of the roller measured, and determines whether the fishing line 14 is being wound or not (
Step 104). However, since it is a feeding operation, the rotational speed of the RAM 42 is set to low speed mode)' (LO) (step 110). In this case, the rotation speed is the initial value of 70 for low speed moto.
%. However, as described above, this value is variable. Further, when the fishing line 14 is fed out and reaches 0150 m, the fishing line 14 may be wound up by a flash motion for fine adjustment. In that case, the stop switch 26 is pressed to cause the motor 16 to spin, but since the rotational speed of the RAM 42 is in the low speed mode, the motor 16 spins at a low speed. Therefore, CPU38
Since the operator makes the determination in step 102, the rotational speed can be set to a low speed mode during feeding.

Next, let's talk about winding.

If the fish is 1↑), select high speed mode (II+) or low speed mode (LO) with the speed setting switch 20, and in the case of low speed mode, press the speed setting switch 22 or 2.
4 to set the motor 16 to a suitable rotational speed. The motor 16 is continuously rotated at that rotational speed to attract fish. Then, the fishing line 14 is continuously wound and unwound, but until the unwinding amount reaches 10 m, the CPU 3B executes steps 100, 102, . . , unless the motor 16 is stopped.
112 loops are repeated. Then, if the fish is attracted and from then on you try to take in the fish with flash motion, -dan mork 16
is stopped by the stop switch 26. CP LJ 3
Step 112>, motor 1 is determined to stop the motor.
Step 1 to determine whether the rotation speed in step 6 is in high-speed mode.
06), if it is a high speed mode, the rotation speed of the RAM 42 is set to high speed (step 108), and if it is a low speed mode, the rotation speed of the RAM 42 is set to a high speed.
42 is set to a low speed (variable value) (step 11
0). Therefore, in this state, if the stop switch 2 [;
Winding is performed by instantaneous movement at the rotational speed stored in the memory. Note that if the amount of fishing line 14 that is fed out is equal to the judgment value, C
The PLJ 38 determines the winding (step 104), determines the rotational speed (step 106), and stores the rotational speed in the RAM 42 (step 108 or 11O). After that, even if the continuous rotational speed of the motor 16 is changed, if the motors 1 and others are stopped, the rotational speed is changed again in step 112, so the rotational speed in the case of twinkling is 0:1 rotation when the motor 16 is stopped. It can be speed.

Hereinafter, various preferred embodiments of the present invention have been described; however, the present invention is not limited to the above-described embodiments; many modifications may be made without departing from the spirit of the invention. Of course.

(Effects of the Invention) When using the electric reel according to the present invention, the rotational speed of the motor that falls during instantaneous motion when catching fish can be automatically set to any rotational speed immediately before the motor stops. , there are advantages such as the ability to instantaneously move the motor according to the weight.

[Brief explanation of drawings]

FIG. 1 is a plan view of the electric reel according to the present invention, FIG. 2 is a block diagram of its electrical components, and FIG. 3 is a flowchart showing the operation of the microcomputer system. 10... Electric reel, 12... Spool, 14
...Fishing line, 16...Motor, 20.22.24
...Speed setting switch, 26...Stop switch,
38...CPU, 42...RAM.

Claims (1)

[Scope of Claims] 1. An electric reel in which a motor rotates a spool around which a fishing line is wound, an input means for issuing a signal instructing the rotational speed of the motor, and at least a stop signal for the motor. a storage means for storing the rotational speed when the motor is inputted, a spinning instruction means for emitting a signal to instantiate the rotation of the motor, and a rotation instructed by the signal input from the input means. When the motor is rotated at a speed and the rotational speed is stored in the storage means, and after the motor has once stopped, a signal instructing a flashing motion is input from the flashing command means to wind up the fishing line. and a control means for instantaneously driving the motor at the rotational speed stored in the storage means.