JPH0916930A - Rotary magnetic head device - Google Patents

Abstract

PURPOSE: To absorb deformation due to chucking by forming a groove part between a bearing press-in part where a bearing is pressed in a lower bearing holding part and the outer peripheral part of this lower bearing holding part. CONSTITUTION: The annular groove part 18 is formed between the bearing press-in part 17 of the lower bearing holding part 13 and the outer peripheral part of the lower bearing holding part 13. This groove part 18 is formed together when a fixed drum cylinder 3 is latched and has one surface perpendicular to one main part 13a of the lower bearing holding part 13 and the other surface slanted. The depth H1 of the groove part 18 is 1/2 as large as the press-in length H2 of a bearing 11 since the track surface of balls of a ball bearing is in the center of the bearing, and the internal diameter D1 of the groove 18 is nearly equal to the external diameter D2 of an upper bearing holding part 12. When the rotary drum cylinder 2 is chucked on a lathe, its deformation caused by the chucking force is absorbed by the provided groove part 18 and its influence does not extent to the bearing press-in part 17, so that the concentricity between the bearing press-in parts 14 and 17 is improved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotary magnetic head device, and more particularly to a structure of a bearing press-fitting portion of a drum cylinder into which a bearing for rotatably supporting a rotary shaft is press-fitted.

[0002]

2. Description of the Related Art For example, as a rotary magnetic head device provided in a video tape recorder (hereinafter referred to as a VTR) or the like, one having a structure as shown in FIG. 4 has been proposed. The rotary magnetic head device shown in FIG. 4 is of a so-called helical scan system in which recording and reproduction are performed obliquely with respect to a magnetic tape, and mainly includes a rotary drum cylinder 102 provided with a magnetic head 101,
The rotary drum cylinder 102 includes a fixed drum cylinder 103 provided so as to face the rotary drum cylinder 102.

The fixed drum cylinder 103 is formed as a cylindrical rotating body made of, for example, an aluminum alloy and having one open end. This fixed drum cylinder 1
On the surface of 03, a tape lead portion for running the magnetic tape obliquely so as to comply with the tape format is formed.

A motor 104 for rotating the rotary drum cylinder 102 is provided inside the fixed drum cylinder 103. Such a motor 1
The rotating shaft 105 of 04 is a bearing 10 which is a pair of ball bearings press-fitted into the fixed drum cylinder 103.
It is rotatably supported by 6, 107.

On the other hand, the rotary drum cylinder 102 is fixed to the tip end side of the rotary shaft 105 so as to rotate together with the rotary shaft 105. A magnetic head 101 for recording information signals on a magnetic tape is attached to the rotary drum cylinder 102. The magnetic head 101 is designed such that its tip portion projects from the circumferential surface of the drum with a predetermined projection amount in order to ensure a good contact with the magnetic tape.

By the way, in this rotary magnetic head device, with respect to the reference surface of the fixed drum cylinder 102,
The rotation axis 105 is required to be vertical. If the rotation axis 105 is not vertical, the pattern recorded on the magnetic tape will be different from the format, and the compatibility will be impaired.

In order to assemble the rotary shaft 105 vertically, the upper and lower bearings 106 and 107 must be pressed into the fixed drum cylinder 103 with good coaxiality. For that purpose, the bearing press-fitting portion 108 into which the bearings 106 and 107 of the fixed drum cylinder 103 shown in FIG.
109 must be processed with good concentricity and good roundness.

Generally, the fixed drum cylinder 103 has a drum outer peripheral portion 1 provided with a bearing press-fitting portion 109 on the base end side.
It is formed by chucking 10 and processing the reference surface, the bearing press-fitting portions 108 and 109, and the tape lead portion with a lathe.

The drum outer peripheral portion 110 provided with the bearing press-fitting portion 109 on the base end side is made thicker than the tip end portion 111 provided with the bearing press-fitting portion 108 on the upper end side. This is when finishing the fixed drum cylinder 103.
Since the drum outer peripheral portion 110 is chucked for cutting, if the thickness of this portion is thin, the circularity of the bearing press-fitting portion 109 is deteriorated due to the influence of the chuck. At the time of chucking, a chucking force F is applied to the drum outer peripheral portion 110 as shown in FIG.

[0010]

However, if the thickness of the drum outer peripheral portion 110 is made thicker than the thickness of the tip portion 111, if the inner diameter dimensions of the upper and lower bearing press-fitting portions 108 and 109 are the same, the base end side The press-fitting force of the bearing press-fitting portion becomes large, and press-fitting of the bearing becomes difficult. Therefore, it is conceivable to change the inner diameters of the bearing press-fitting portions 108 and 109 in order to make the pressure inputs of the upper and lower bearing press-fitting portions 108 and 109 the same, but production control such as two types of bearings is required. It is not preferable.

On the other hand, the interference between the bearing and the bearing press-fitting portion is
It is determined from the reliability including the pressure input of the bearing and the temperature characteristics of the drum cylinder and the bearing. Generally, aluminum is used for the drum cylinder and stainless steel is used for the bearing. Therefore, when the temperature is high, the coefficient of thermal expansion of aluminum is larger than that of stainless steel, so that a gap may be formed between the bearing and the bearing press-fitting portion. Therefore, it is necessary to design the inner diameter of the bearing press-fitting portion so that a sufficient fitting allowance is secured in the bearing press-fitting portion even at high temperature.

However, if all of these requirements are to be satisfied, there is a risk that the pressure input becomes too high and the bearing is deformed because the drum outer peripheral portion 110 of the bearing press-fitting portion 109 on the base end side is thick. is there. If the bearing is deformed, proper rotation of the rotary drum cylinder cannot be obtained, or noise is generated when the drum rotates, which causes a problem.

From the above, up to now, all the above requirements cannot be satisfied, and the design is compromised somewhere.

Therefore, the present invention has been proposed in order to solve the problems of the prior art, and is a rotation that can satisfy all of the high accuracy of the drum cylinder, the reliability at high temperature, and the appropriate pressure input. An object is to provide a magnetic head device.

[0015]

According to the present invention, a rotating shaft is rotatably supported by an upper bearing holding portion provided inside a drum and a lower bearing holding portion provided outside a drum. Is a rotary magnetic head device including a first drum cylinder into which a bearing is press-fitted, and a second drum cylinder that is provided coaxially with the rotation shaft and that faces the first drum cylinder. In this rotary magnetic head device, in order to solve the above-mentioned problems, a groove is formed between a bearing press-fitting portion into which the bearing is press-fitted in the lower bearing holding portion and an outer peripheral portion of the lower bearing holding portion.

Further, the outer diameter of the upper bearing holding portion and the outer diameter of the bearing press-fitted portion remaining by forming the groove in the lower bearing holding portion are made substantially the same. The groove portion at this time is an annular groove.

[0017]

In the present invention, since the groove portion is provided between the bearing press-fitting portion of the lower bearing holding portion and the outer peripheral portion of the lower bearing holding portion, the deformation due to chucking of the lathe is caused by the groove portion. It is absorbed by and does not affect the bearing press-fitting part.

Particularly, by making the outer diameter dimension of the bearing press-fitting portion provided in the lower bearing holding portion substantially the same as the outer diameter dimension of the upper bearing holding portion, the pressure inputs in the upper and lower bearing pressing portions become substantially equal. . Therefore, even if the press-fitting margin is designed in consideration of the temperature characteristics, the press-fitting does not become excessive and the bearing is not deformed.

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Specific embodiments to which the present invention is applied will be described in detail below with reference to the drawings.

The present embodiment is an application of the present invention to a so-called helical scan type rotary magnetic head device in which recording and reproduction are performed obliquely on a magnetic tape.
Moreover, this is an example of a so-called upper drive type rotary magnetic head device in which an upper drum cylinder provided with a magnetic head rotates.

As shown in FIG. 1, this rotary magnetic head device is mainly composed of a rotary drum cylinder 2 provided with a magnetic head 1 and a fixed drum cylinder 3 provided facing the rotary drum cylinder 2.

As shown in FIG. 2, the fixed drum cylinder 3 is formed as a rotating body which is made of, for example, an aluminum alloy or the like and has a cylindrical shape with one open. On the surface of the fixed drum cylinder 3, a tape lead portion 3a for obliquely running the magnetic tape so as to comply with the tape format is formed.

A brushless DC motor 4 for rotating the rotary drum cylinder 2 is provided inside the fixed drum cylinder 3, as shown in FIG. The motor 4 is composed of a stator 6 having a drive coil 5 provided on an iron core, and a rotor 8 having a drive magnet 7 provided so as to face the drive coil 5.

Further, in the center of the fixed drum cylinder 3, as shown in FIG. 2, an upper bearing holding portion 12 provided with bearings 10 and 11 for rotatably supporting a rotating shaft 9 of a motor 4, and a lower side. A bearing holding portion 13 is provided.

The upper bearing holding portion 12 is provided inside the fixed drum cylinder 3 so as to project as a cylindrical body. And, on the tip side of the upper bearing holding portion 12,
For example, a bearing press-fitting portion 14 for press-fitting and holding the bearing 10 made of a ball bearing or the like is provided.

The bearing press-fitting portion 14 has a sufficient fitting allowance not only when the bearing 10 is press-fitted but also when the bearing 10 is hot, by cutting a part of the inner wall surface of the through hole 15 facing the rotary shaft 9 of the motor 4 with a lathe. It has a certain size.

A stator, which is the fixed side of the rotary transformer 16, is fixed to the outer periphery of the bearing holding portion 12.

On the other hand, the lower bearing holding portion 13 is provided outside the fixed drum cylinder 3 on the side opposite to the upper bearing holding portion 12. The lower bearing holding portion 13 is
It is a portion that is chucked by a lathe, and is formed as a disk-shaped projection having a low height. In the center of the lower bearing holding portion 13, a bearing press-fitting portion 1 for press-fitting and holding a bearing 11 also made of a ball bearing or the like.
7 are provided. Like the bearing press-fitting portion 14, the bearing press-fitting portion 17 is formed by cutting a part of the inner wall surface of the through hole 15 facing the rotation shaft 9 of the motor 4 with a lathe, so that the bearing 11 is not only press-fitted but also at high temperature. Is also dimensioned so that there is a sufficient interference.

It should be noted that the bearings 10 and 11 of the same size are press-fitted into the bearing press-fitting portion 14 formed in the upper bearing holding portion 12 and the bearing press-fitting portion 17 provided in the lower bearing holding portion 13. There is.

In particular, in this embodiment, the bearing press-fitting portion 17 of the lower bearing holding portion 13 and the lower bearing holding portion 1
An annular groove portion 18 is formed between the outer peripheral portion 3 and the outer peripheral portion. The groove portion 18 is formed together when the fixed drum cylinder 3 is lathe-machined, and is formed as a groove in which one main surface 13a of the lower bearing holding portion 13 has one surface perpendicular to the other and the other surface inclined. Has been done.

Since the race surface (ball raceway surface) of the ball bearing is the center of the bearing, the depth H ₁ of the groove portion 18 is 1/2 or more of the press-fitting length H ₂ (bearing press-fitting portion 17) of the bearing 11. It is said that Also, the inner diameter dimension D ₁ of the groove portion 18, in other words, the groove portion 18 in the lower bearing holding portion 13.
The outer diameter dimension of the bearing press-fitted portion that remains due to the formation of and the outer diameter dimension D ₂ of the upper bearing holding portion 12 are substantially the same.

By providing such a groove portion 18,
When the rotary drum cylinder 2 is chucked by a lathe, the deformation due to the chucking force is absorbed by the groove portion 18 and does not affect the bearing press-fitting portion 17. Therefore, the concentricity of the bearing press-fitting portions 14 and 17 is good, and the roundness thereof can be processed well.

When the bearings 10 and 11 are press-fitted, the wall thickness of the portion of the upper bearing holding portion 12 where the bearing press-fitting portion 14 is provided and the bearing press-fitting portion 17 of the lower bearing holding portion 13 are set.
Since the thicknesses of the portions where are provided are almost equal, the press inputs are equal. For this reason, even if the press-fitting margin of the bearing press-fitting portion 17 of the lower bearing holding portion 13 is designed in consideration of temperature characteristics, the press-fitting does not become excessive and the bearing 11 is not deformed.

As a specific example, a calculation example of the bearing pressure input when a bearing having an outer diameter of 12 mm is used will be shown. The calculation formula is as follows, and the coefficient used in this calculation formula is shown in FIG. 3 in which the bearing outer 20 is press-fitted into the lower drum 19.

[0035]

[Equation 1]

Using this equation, the lower bearing holding portion 13
Of the outer diameter is 27 mm, and the bearing press-fit length H ₂ is 3 m.
m, the depth H ₁ of the groove 18 is 2.5 mm, and the inner diameter dimension D ₁ is 16 mm, the bearing pressure input is calculated as follows.
The pressure input when the groove 18 is formed is about 60% of the pressure input when the groove 18 is not formed.

In this embodiment, the bearing is press-fitted into the fixed drum cylinder, but conversely, the same effect can be obtained even if the bearing is press-fitted into the rotary drum cylinder. Further, according to the present invention, not only the rotary magnetic head device of the upper drive type, but also the rotary magnetic head device of the lower drive type in which the lower drum cylinder rotates, both the upper drum cylinder and the lower drum cylinder are fixed, and the magnetic head is attached. The present invention can also be applied to a rotary magnetic head device of a medium drum type in which a medium drum cylinder is rotated.

[0038]

As is apparent from the above description, according to the rotary magnetic head device of the present invention, between the bearing press-fitting portion of the lower bearing holding portion and the outer peripheral portion of the lower bearing holding portion, By forming the groove, when the rotary drum cylinder is chucked by a lathe, the deformation of the chucking force can be absorbed by the groove. Therefore, the upper and lower bearing press-fitting portions into which the bearings that support the rotary shaft are press-fitted can have good concentricity, and the roundness can be highly accurate.

Further, in the rotary magnetic head device according to the present invention, the outer diameter dimension of the upper bearing holding portion is substantially the same as the outer diameter dimension of the bearing press-fitting portion remaining by forming the groove portion in the lower bearing holding portion. Therefore, the pressure inputs when press-fitting the upper and lower bearings become equal. Therefore, even if the press-fitting margin of the bearing press-fitting portion of the lower bearing holding portion is designed in consideration of the temperature characteristic, the press-fitting force is not excessive and the deformation of the bearing can be prevented.

As described above, according to the present invention, the drum cylinder can be machined with high accuracy, and reliability at high temperature and proper pressure input of the bearing can be satisfied without contradictory rotation with high accuracy. A magnetic head device can be provided.

[Brief description of the drawings]

FIG. 1 is a sectional view of a rotary magnetic head device to which the present invention is applied.

FIG. 2 is a sectional view of a fixed drum cylinder of a rotary magnetic head device to which the present invention is applied.

FIG. 3 is a schematic diagram showing a relationship between a drum and a bearing used for calculating a bearing pressure input.

FIG. 4 is a cross-sectional view of a conventional rotary magnetic head device.

FIG. 5 is a sectional view of a fixed drum cylinder of a conventional rotary magnetic head device.

[Explanation of symbols]

 3 Fixed Drum Cylinder 12 Upper Bearing Holding Part 13 Lower Bearing Holding Part 14, 17 Bearing Press-fitting Part 18 Groove Part

Claims (3)

[Claims] 1. A first bearing in which a bearing for rotatably supporting a rotary shaft is press-fitted into an upper bearing holding portion provided inside the drum and a lower bearing holding portion provided outside the drum, respectively. And a second drum cylinder that is provided coaxially with the rotating shaft and that is provided so as to face the first drum cylinder and that has a bearing press-fitting portion into which the bearing is press-fitted into the lower bearing holding portion. A rotary magnetic head device, wherein a groove is formed between the lower bearing holding portion and an outer peripheral portion of the lower bearing holding portion. 2. The outer diameter dimension of the upper bearing holding portion is substantially the same as the outer diameter dimension of the bearing press-fitted portion remaining by forming the groove portion in the lower bearing holding portion. Rotating magnetic head device. 3. The rotary magnetic head device according to claim 2, wherein the groove portion is an annular groove.