WO1984004616A1

WO1984004616A1 - Tape reader

Info

Publication number: WO1984004616A1
Application number: PCT/JP1984/000228
Authority: WO
Inventors: Seiichi Hattori
Original assignee: Fanuc Ltd
Priority date: 1983-05-06
Filing date: 1984-05-04
Publication date: 1984-11-22
Also published as: JPS59205684A

Abstract

The present invention is designed to reduce the electric power consumed by a capstan-driven tape reader, and prevent the generation of heat in the capstan motor thereof. When a detector means (15) detects the fact that a feed magnet (5) has not been excited for a predetermined period of time, a capstan motor (3) is stopped by control means (23, 24).

Description

Detailed tape reader technology field

The present invention relates to a capstan drive type table reader which consumes less power and can prevent heat generation of a capstan motor. is there.

Background technology

The tape drive of the capstan drive system is rotated by energizing the feed magnet and rotating by the capstan motor. The tape is fed by bringing the feed roller into contact with the captive dump roller to excite the brake magnet net. This causes the tape to stop. At this time, the conventional tape reader always rotates the capstan motor until the tape reader power is turned on and then turned off. However, there were the following disadvantages. That is, even when the tape is not fed, the capstan motor is driven, and there is a drawback that wasteful power is consumed because of the power that is used. In addition, there is a disadvantage that the operating margin is reduced due to the heat generated by the capstan motor.

To remedy such drawbacks, it may be possible to say that the capstan motor is only rotated when the tape is fed. Depends on the push motor's drive

OMPI AT10 It takes a long time for the rotation to stabilize after the start of the capstan motor, and the tape feed is performed by the capstan motor. Since the rotation must be performed stably, the above-described method has a disadvantage that the dead time increases.

Disclosure of the invention

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned drawbacks, and its purpose is to reduce power consumption and to prevent heat generation of a cabinet motor. According to the present invention, there is provided detecting means for detecting that the feed magnet is not excited for a fixed time, and the feed magnet is not excited for a fixed time by the detecting means. When the power is detected, the power consumption is reduced and the heat generated by the capacitor motor is prevented because the control device stops the capacitor motor. it can.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a block diagram of an embodiment of the present invention, and FIG. 2 is an operation explanatory diagram of FIG.

BEST MODE FOR CARRYING OUT THE INVENTION

Hereinafter, examples will be described in detail.

FIG. 1 is a block diagram of an embodiment of the present invention, where 1 is a tape 2, a capstan roller, and 5 a capstan motor 4 is a feeder. , 5 is a feedback magnet, ό is a brake magnet, 7 is a brake magnet, 8 is a light emitting element, 9 is a light receiving element, 10 and 11 are transistors, 12 is a data output section, 13 is a data input section, and 14 is a microprocessor. A processing unit, such as 15, is a re-triggerable monostable multivibrator, which is triggered on the falling edge of the signal. Also, 1ό is an age, 17 and 20 are innocents, 18 is a switch, 1 is a NAND gate, 21 is an AND gate, and 22 is an AND gate. An orgate, 23 is a transistor, and 24 is a relay. The switch 18 is connected to the contact S when the capstan motor 5 is constantly rotated, and the command for reading the information of the tape 1 is processed at a certain time. In order to stop the capstan motor 3 when the output is not output from the device 14, the one connected to the contact A is used.

Now, it is assumed that the switch 18 is connected to the power contact A side. To start reading the information perforated on tape 1, the processing unit 14 applies a control signal to the data output unit 12 and changes the capstan motor activation signal ci to "1". " As a result, the transistor is switched to the 25-power state, the relay is switched to the 24-power state, and the capstan motor is rotated to the third power. When a certain time (time until the rotation of the capstan motor 3 is stabilized) elapses after the capstan motor activation signal ^ is set to "1", the processing is performed. The processing device 14 outputs a command to read the information of Tape 1. Now, assuming that a read command is output at time έ1, the output signals of the data output unit 12 are as shown in FIG. 2 ^ and (£), respectively. 1 "and" 0 ", and the capstan motor start signal becomes" 0 ".

As a result, the transistors 1 □ and 11 are turned on, respectively. The feed magnet 5 is turned off, the voltage is applied to the feed magnet 5 and it is excited, and the cable 4 is attached to the taper σ-2 and the tape 1 is attached to the tape 1. Contact via At this time, the signal and b are “1” and “0”, respectively, and the output signal s of the monostable multivibrator 15 is “0” as shown in FIG. Therefore, the output signal / of the NAND gate 19 becomes "1" as shown in the figure, and is added to one of the input terminals of the third gate 21. The other input terminal of the AND gate 21 receives a capstan motor stop signal c from the data output unit 12 via the inverter 20. However, the signal c is "0" except when the capstan motor 3 is stopped in an emergency, and the output of the AND gate 21 is generated. The force signal becomes "1" as shown in Fig. ©, whereby the transistor 23 is turned on, the relay 24 operates, and the caps are operated. Tammo ..5 continues to rotate, so that a tape 1 reading command is output at time έ1 and that tape 1 is fed in the direction of the arrow. Then, the light from the light emitting element 8 is incident on the light receiving element 9 in response to the perforation of the tape 1, and the perforation information of the tape 1 is read, and the input device a

The data is transferred to the processing device 14 via the communication device 13.

When the reading of the perforation information of one block is completed at time έ2, the processing unit 14 outputs a stop instruction of tape 1 and, thereby, the output of the data output unit 12 is performed. The force signals a _} b are "0", "1" as shown in Fig. 2 (A) and (5), respectively. If the signal is "0", "1,", the transistors 10 and 11 will be in the off and on states, respectively.

Excitation of 5 is cut off, and the brake magnet net ό is excited, so that the brake armature 7 force; Loop 1 is stopped. Also, when the signal power becomes “0”, the monostable multivibrator 15 is triggered at the fall (time 2), and the output signal is output. As shown in Fig. (C), the output signal of the NAND gate 19 and the output signal of the AND gate 19 are shown in Fig. 3 (C). The output signal of the gate 21 is maintained at "1" as shown by ^ in the same figure, and accordingly, the stop command of tape 1 is output and the output signal of tape 1 is changed. The capstan motor 3 continues to rotate until a certain time Γ elapses.

A fixed time since the stop command of tape 1 was output at time έ2? At time 3 before the lapse of V, when the reading command of tape 1 is output from the processing unit ¹⁴ power, the output signals of the data output unit 12 are not shown in FIG. ^, (, As shown in the figure, they become 'Ί,,, "0", respectively, and by this, the same operation as between times 1 and 2 is performed. The drilling information is read, and when the reading of the drilling information for one block is completed at time t4, the processing device 14 issues a tape 1 stop command. As a result, the output signal a of the data output unit 12 becomes “α” and “”, respectively, as shown in FIG. Q,,, "1" As described above, the excitation of the feed magnet net 5 is cut off, and the brake magnet net <6 is excited, so that the brake magnet net is excited. A 7 Tape 1 stops when it comes into contact with tape 1. When the signal becomes "0", the monostable multivibrator 15 is retriggered at the falling edge (time 4), as shown in FIG. As shown in the figure, the output signal e is set to a fixed time Γ "1". .

Therefore, the output signal of the NAND gate 19 and the output signal of the AND gate 21 until the predetermined time ゝ elapses from the time έ4 are output as shown in FIGS. During this time, the capstan motor 3 continues to rotate due to the force held at "1". However, if the processing unit 14 does not output a reading command for tape 1 even at time 5 after a lapse of a fixed time ら from time έ4, at time έ5 The output signal of the monostable multivibrator 15 becomes "0" as shown in the figure, and the output signal of the data output section 12 becomes "0". Are "0" and "1" as shown in FIGS. 7A and 7D, respectively, so that the output signal of the NAND gate 19 and the output of the AND gate 21 are output. The signal is both "0" as shown in the figure ((^), thereby setting the transistor 23 to the power off state and the relay 24 not operating. The capstan motor 5 stops rotating because it is in the down state.

If reading of tape 1 is to be started again after time ί5 when the capstan motor 3 stops rotating, the processing unit In the same manner as described above, the control signal 14 is applied to the data output section 12 so that the capstan motor starting signal d is set to "1,", and the captive motor 5 is operated. the Ru is rotated. with its, key ya-flop is te emission M o after data start signal "1" and to whether et predetermined time, the processing equipment 1 ⁴ force Mr exits the scan command tapes 1 Thus, the same operation as described above is performed, and the hole information of Tape 1 is read.

In this embodiment, it is necessary to determine whether or not the cabinet motor 3 is stopped, but the processing device 14 is provided with a data input unit. 15 Based on the output signal of AND gate 21 which is applied via 15, the CAB motor 3 determines whether or not it is stopped. . That is, in the case of the signal daka S "1,", it is determined that the capstan motor is rotated by three powers and the motor is rotated, and in the case of "0", it is determined that the motor is stopped. O no

If the switch 18 is connected to the power side, the output signal of the NAND gate 19 will always be "1". Therefore, the capstan motor 5 rotates at all times.

The time Γ shown in FIG. 2 is usually about 30 to όα seconds.

As described above, the present invention is composed of a monostable multi-piper 15 of equal strength and detects that the feed magnet is not excited for a certain period of time. Detection means and transistors 23,

Ο ΡΙ It consists of 24 relays, and when the detection means detects that the feed magnet is not energized for a certain period of time, the capstan Since it has a control means for stopping the motor, it has the advantage that power consumption can be reduced as compared with the conventional example, and the cap is also provided. This has the advantage that the heat generation of the stan motor can be prevented. Further, the present invention provides a mechanism for stopping a cabin motor when a magnet is not magnetized for a certain period of time. However, there is an advantage that the waste time can be reduced as compared with a device that drives the capstan motor only when the tape is fed.

O PI

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Claims

The scope of the claims

When it is excited, it is brought into contact with the cabinet roller and the filter, which are rotated by the cabinet motor. Feeder to feed the tape, and a breaker which is excited when the feedmagnet is turned off to stop the tape. In a capstan drive type tape reader having a net, it is detected that the feed magnet has not been excited for a certain period of time. Detecting means for detecting that the feed magnet is not excited for a fixed time by the detecting means. A tape reader characterized by comprising a control means for stopping the tape reader.