JPH0145147B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to improvements in tape guides used in tape-using equipment such as video tape recorders.

As is well known, tape-using devices such as tape recorders and videotape recorders that use tape to record and reproduce information signals require improvements in the stability of tape running and improvements in tape running during the tape running path. Tape guides are used to change the direction of travel.

As for the above-mentioned tape guide, fixed types and rotary types are used depending on the size of the wrapping angle of the tape around the tape guide when changing the tape running direction, the size of the tape running speed, etc. There is.

By the way, with the above-mentioned fixed tape guide, not only does the tape contacting surface wear out, but especially in the case of magnetic tape, the magnetic powder may burn onto the tape contacting surface of the tape guide, and the tape may become damaged due to the effects of humidity, static electricity, etc. Undesirable situations such as wrapping around the tape guide may occur. In addition, the above-mentioned rotary tape guide uses ball bearings, oil-less metal, etc. as its rotation mechanism, so it is prone to wobbling and eccentricity due to aging, and the tape running speed may be affected. If it is no longer possible to rotate the tape smoothly, it will adversely affect the running of the tape, making stable recording and playback impossible, and causing inconveniences such as damage and breakage of the tape. Further, the rotary tape guide has a complicated structure, is difficult to manufacture, and is economically disadvantageous.

This invention was made in consideration of the above circumstances, and by making the tape rotate and stop rotating depending on the tape running speed, there is no wear or wobbling on the tape contact surface, and the tape is stable. The object of the present invention is to provide an extremely good tape guide that allows the tape to run.

Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings. In FIG. 1, reference numeral 11 denotes a support shaft, which is composed of a support shaft portion 12 formed in a substantially cylindrical shape and a base portion 13 formed in a substantially brim shape at the lower portion of the support shaft portion 12 in the figure. And this support shaft 11
, a protrusion 14 protruding from the lower end of the base 13 in the figure and a screw hole 15 formed at the center of the protrusion 14 are located at a predetermined position formed on the main chassis of a device using the tape (not shown). The main chassis is screwed into the mounting portion of the main chassis. A ring-shaped groove 16 is formed along the circumference of the platform 13 at the upper end of the platform 13 in the drawing.

On the other hand, the support shaft part 12 of the support shaft 11 has a plurality of parts along the circumference of the support shaft part 12 at predetermined intervals at the upper and lower parts of the circumferential side part 17 (in the case of illustration, Three grooves 18 are formed in the upper and lower middle portions. Further, a wide recess 19 is formed approximately at the center of the circumferential side portion 17 of the support shaft portion 12 along the circumference of the support shaft portion 12 . That is, the circumferential side portion 17 of the support shaft portion 12 is left partially in the shape of a brim. An implantable threaded portion 20 is provided in a protruding manner at the center of the upper end of the support shaft portion 12 in the drawing.

Here, a substantially cylindrical guide 21 is fitted into the support shaft portion 12 of the support shaft 11 so as to be rotatable around the axis of the support shaft portion 12 . That is,
The guide 21 has an inner peripheral portion 22 that is connected to the support shaft portion 12.
It rotates facing the circumferential side portion 17 at an interval to be described later. Furthermore, collar portions 23 and 24 are formed at the upper and lower end portions of the guide 21 in the drawing. Of these, the flange portion 24 is connected to the groove portion 16 of the base portion 13.
It is designed to block the

A groove portion 18 formed in the support shaft portion 12
Then, a substantially paste-like viscous material (for example, Teflon (registered trademark) paste, etc.) is sealed in the groove portion 16 of the base portion 13 . At this time, if the particle diameter of the viscous material is, for example, 20 [μm], the support shaft portion 1
It is desirable that the distance between the circumferential side portion 17 of the guide 21 and the inner circumferential portion 22 of the guide 21 be approximately 10 to 15 [μm].

At this point, the cap 25 is screwed onto the implanted threaded portion 20 that projects from the support shaft portion 12 . This prevents the guide 21 from coming off. Then, the lower surface of the cap 25 in the figure and the guide 21
When the particle size of the viscous material is as described above, the distance between the flange portion 23 and the flange portion 23 is desirably about 10 to 20 [μm].

In this way, the peripheral side portion 17 of the support shaft portion 12 and the guide 2
By determining the distance between the inner peripheral portion 22 of the guide 21 and the distance between the cap 25 and the flange 23 of the guide 21 according to the particle diameter of the viscous material, the guide 21 can be prevented from wobbling in the radial direction and the thrust direction. It can be held down.

In the above configuration, a tape (not shown) is made to run in contact with the guide 21. At this time, rotational force is applied to the guide 21 in accordance with the tape running. Here, the rotation speed of the guide 21 is ω, and the support shaft 12 and the guide 21 made of the above-mentioned viscous material are
Assuming that the rotational friction torque between the guide 21 and the guide 21 is T, as shown in FIG.

On the other hand, if the running speed of the tape is f and the dynamic friction force between the tape and the guide 21 is F, then the second
As shown in Figure b, the dynamic frictional force F decreases with the tape running speed f. That is, since the dynamic frictional force F between the tape and the guide 21 is a torque imparting rotation to the guide 21, as the tape running speed f increases, the torque imparting rotation to the guide 21 decreases.

Therefore, as shown in Fig. 2c, when the tape running speed f is low (speed below f ₁ in the figure),
The dynamic frictional force F between the tape and the guide 21, that is, the torque imparting rotation to the guide 21, is sufficiently larger than the rotational frictional torque T between the guide 21 and the support shaft 12, so that the guide 21 rotates and becomes a rotary tape guide.
Then, as the tape running speed f increases,
At this time, the rotational imparting torque and the rotational friction torque T are balanced (speed f ₁ in the figure). At this time, the guide 21
stops rotating, and even if the tape running speed f is increased above this speed, the guide 21 does not rotate and becomes a fixed tape guide.

Therefore, according to the configuration of the above embodiment, the tape running speed f is less than f ₁ in FIG. 2c.
Assuming that is the tape low speed running region, and the tape running speed f higher than f ₁ in the figure is the tape high speed running region,
The guide 21 is rotatable in the tape running range at low speeds, and is fixed in the tape running ranges at high speeds, so unlike conventional fixed tape guides, the tape contact surface does not wear out, burn out, wrap, etc. can be prevented from occurring. In addition, because it uses a paste-like viscous material, it is less prone to wobbling or eccentricity due to aging, unlike conventional rotary tape guides, and can fully contribute to stable and reliable recording and playback. Almost no damage occurs. Furthermore, the structure is simple and easy to manufacture, and it is economically advantageous.

In addition, conventional rotary tape guides produce abnormal tape vibrations and abnormal noises, especially when the tape is running at high speeds, but according to the embodiment described above, the guide 21 is fixed in the tape running range at high speeds. It is possible to prevent the occurrence of abnormal vibrations, abnormal sounds, etc.

Although Teflon paste is shown in the above embodiment as the viscous material, it is needless to say that the material is not limited to this, and materials having appropriate viscosity and particle size can be used depending on the actual usage conditions.

It should be noted that the present invention is not limited to the above-mentioned embodiments, and can be implemented with various modifications without departing from the gist thereof.

Therefore, as detailed above, according to the present invention, the rotating state and the rotating stopped state are made according to the tape running speed, so there is no abrasion or rattling of the tape contact surface, and the tape is stable. It is possible to provide an extremely good tape guide that allows the tape to run.

[Brief explanation of drawings]

FIG. 1 is a side sectional view showing an embodiment of the tape guide according to the present invention, and FIGS. 2a to 2c are characteristic curve diagrams for explaining the operation of the same embodiment. 11... Support shaft, 12... Support shaft part, 13... Stand part, 14
...Protrusion, 15...Threaded hole, 16...Groove, 17...Peripheral side part, 18...Groove, 19...Recess, 20...Insert screw part, 21...Guide, 22...Inner peripheral part, 23, 24...
Tsubabe, 25...cap.

Claims (1)

[Claims] 1. In a tape guide in which a substantially cylindrical guide is rotatably fitted to a support shaft, a groove is formed between the support shaft and the guide, and a paste-like viscous material is sealed in this groove. The guide is configured such that when the running speed of the tape running in contact with the guide is low, the guide is in a rotating state, and when the running speed of the tape is high, the guide is in a rotating state. A tape guide featuring