KR930002402B1 - Head positioning device for vtr - Google Patents

Abstract

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Description

VTR Magnetic Head Positioning Mechanism

1 to 4 show one embodiment of the present invention,

1 is a plan view of the magnetic head position adjustment mechanism of the VRT according to the present invention.

FIG. 2 is a cross sectional view along line II-II of FIG. 1;

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

4 is a cross-sectional view illustrating a fitting relationship between the annular projection of the user cylindrical portion and the head of the male screw member in the synchronous tool.

5 is a third and in-phase view showing yet another embodiment of the present invention.

6 is a plan view of a horizontal positioning member and an elastic Q peripheral portion showing another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: chassis 2: axis

4: up and down movable plate 7: user cylindrical part

1: azimuth adjustment mechanism 12: magnetic head

26: screw insertion hole 27: height position adjustment mechanism

28: Male screw member (height position adjusting screw member) 30: Horizontal position adjusting body

35: main surface 37,37a: elastic member (elastic mechanism)

The present invention relates to a magnetic head positioning mechanism of a VTR having a simple configuration in which the position of the magnetic head of the VTR (video tape recorder) and the rotating head cylinder can be easily adjusted and the assembly accuracy can be improved.

Conventionally, in the height positioning mechanism and the rotating head cylinder, the control head (hereinafter referred to collectively as the magnetic head) for controlling trekking between the audio recording reproduction head and the rotating head of the VTR and the video recording track is matched with the traveling height of the tape. The magnetic head positioning mechanism of the VTR having a horizontal positioning mechanism for adjusting the distance of the magnetic pole is disclosed in Japanese Patent Application Laid-Open No. 1-38736 to prevent the horizontal positioning mechanism from being changed even when the height positioning mechanism is adjusted. .

(1) In such a conventional height position adjusting mechanism, the head mounting plate attached to the support shaft and the up and down movement material is controlled by a pin, and the plate attached to the bearing number is applied to the shaft by one direction by the force of the compression spring. And compressing the spring force in one direction with the nut screwed to the support shaft and adjusting the height position with the nut, and simultaneously tightening the nut face of the tapered nut screwed to the plate with the compression spring and the head mounting plate. I'm trying to press. And even if the height position adjustment of the magnetic head by the said taper nut is carried out, since the head mounting plate and the plate move together in the height direction, the data between the taper nut and the head mounting plate performing horizontal positioning The change in relative position does not occur. However, this configuration was complicated.

(2) In the above-described conventional height position adjusting mechanism, a metal cylindrical member is fixed to one end of the metal head mounting plate by an automatic locking nut, and the magnetic head is attached to the other end side of the head mounting plate. Although mounting is performed, there is an unreasonable difference in the height position adjustment range of the magnetic head due to an unbalanced orthogonality between the cylindrical member and the head mounting plate caused by the automatic locking nut.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object thereof is to provide a magnetic head position adjustment mechanism of a VTR that is highly precise and can be adjusted accurately without changing the horizontal position adjustment mechanism even when the height position adjustment mechanism is adjusted. I am doing it. In order to achieve the above object, in the magnetic head positioning mechanism of the VTR of the present invention, the horizontal positioning mechanism is rotatable with respect to the chassis about an axis parallel to the support axis, so that the distance from the axis line in the plane view is rotated. And a horizontal positioning body having a main surface parallel to the axis thereof, and an elastic mechanism for elastically welding a part of the upper and lower movable plates to the main surface of the horizontal positioning body in a side view. .

The magnetic head position adjustment mechanism of the VTR of claim 2 has its height positioning mechanism compressed and refurbished between the inner bottom surface and the support shaft of the user cylindrical portion made of synthetic resin provided with the compression spring as the bearing portion on the upper and lower movable plates. And screwing the height position adjusting screw member to the support shaft through a screw insertion hole provided in the center of the bottom of the user cylindrical portion as a male screw member.

In the case of claim 1, when the horizontal position adjusting body is rotated forward and backward, the distance from the rotating head cylinder of the magnetic head changes as the forward and reverse rotation is made in the horizontal plane about the support axis of the vertical moving plate. In the case of claim 2, when the male screw member, which is the height position adjusting screw member, is rotated forward and backward, the height of the magnetic head changes as the vertical movable plate moves up and down in a direction parallel to the axis line of the support shaft. EMBODIMENT OF THE INVENTION Hereinafter, the Example of this invention is described based on drawing.

FIG. 1 is a plan view of the magnetic head positioning mechanism of the VTR showing one embodiment of the present invention, and FIG. 2 is a sectional view taken along the line II-II of FIG. 1, where 1 is the chassis of the VTR, and the upper surface is a predetermined location. A support shaft 2 of a circular cross section is installed in the spring, and a spring fitting recess 3 is provided at an upper end of the support shaft 2. The up and down movable plate 4 is attached to the support shaft 2 about the axis L1 of this support axis 2 freely, and is mounted up and down in the direction parallel to the axis line L1.

The vertical movable plate 4 is made from the main plate 5 made of synthetic resin and the sub plate 6 made of metal. The user cylindrical part 7 which protrudes in the up-down direction is integrally formed in the substantially center part of the main plate 5. The user cylindrical portion 7 also serves as a bearing portion, and its inner circumferential surface is polygonal (for example, regular hexagonal) as shown in FIG. 3 so as to be in point contact with the outer circumferential surface of the support shaft 2.

On the outer circumferential surface of the user cylindrical portion 7 is located above a predetermined dimension (plate thickness of the subplate 6) than the upper surface of the main plate 5, a plurality of (eg four) tongue pieces 8 are spaced equally in the peripheral direction. So as to be integral with the radial. The subplate 6 has a circular fitting hole 9 at one end thereof, and a cut-out insertion hole 10 in which the tongue piece 8 is inserted into the periphery of the fitting hole 9 has a tongue piece 8. It is installed correspondingly.

Then, the user cylindrical portion 7 of the main plate 5 is fitted into the fitting hole 9 of the subplate 6, and the tongue piece 8 of the user cylindrical portion 7 is inserted into the insertion plate 10 of the subplate 6. ), And then the main plate 5 and subplate 6 are rotated relative to each other to change the tongue piece 8 and the insertion hole 10 in the circumferential direction. ), The upper surface polymerization of the main plate (5) is in close contact. The user cylindrical portion 7 is fitted to the support shaft 2 by rotation materials and vertical movement materials. In the previous state where the user cylindrical portion 7 is fitted to the support shaft 2, when the user cylindrical portion 7 is fitted to the support shaft 2, the user cylindrical portion 7 is expanded and elastically deformed as the elastic deformation occurs. It will be in the state shown by the solid line in 3 degree. Accordingly, the clearance between the outer circumferential surface of the support shaft 2 and the inner circumferential surface of the user cylindrical portion 7 serving as the bearing portion becomes zero, so that the vertical movable plate 4 can be kept in a stable state with respect to the support shaft 2.

The magnetic head 12 is attached to the vertical movable plate 4 via the orientation adjustment mechanism 11. The azimuth adjustment mechanism 11 has the base plate 13 which fixed the magnetic head 12 to the upper surface. The base plate l3 is mounted on the upper side of the subplate 6 by a mounting screw 14 and a first adjusting screw 15 in both up and down movable materials.

That is, the mounting screw 14 is screwed into the first threaded hole 16 of the subplate 6 and is forcibly tightened by the method of cutting the tab into the hole l7 of the main plate 5. Relaxation of the mounting screw 14 is prohibited. Moreover, relative rotation between the main plate 5 and the subplate 6 is inhibited by the takeoff screw l4. The first threaded hole 18 of the large plate 13 is inserted into the mounting screw 14 by a steel sheet. The first adjusting screw 15 is screwed into the second screw hole 19 of the subplate 6. Now, the second insertion hole 20 of the base plate 13 is inserted into the first adjustment screw 15.

A spring 2l is opened between the head of the first adjusting screw l5 and the base plate 13, and the base plate 13 is biased downward by this spring 2l. In addition, a second adjustment screw 23 is screwed into the screw hole 22 of the base plate 13 and abuts the upper surface of the subplate 6 on the lower end surface of the second adjustment screw 23.

The azimuth adjusting mechanism 11 configured as described above rotates the second adjusting screw 23 forward and reverse to rotate the tape receiving surface direction of the magnetic head 12 in the forward and reverse direction of the first adjusting screw 15. The tape receiving surface and orthogonal direction direction of can be adjusted, respectively. Guide pins 24 protrude from the upper surface of the subplate 6, and the guide pins 24 are regrettable in the fitting holes 25 of the base plate 13. As a result, the alignment of the holes when the base plate 13 is mounted on the upper surface of the subplate 6 can be easily performed.

The screw insertion hole 26 is laid in the center of the bottom part of the user cylindrical part 7. A male thread member 28, which is a height position adjusting screw member of the height position adjusting mechanism 27, is loosely inserted into the screw insertion hole 26 and screwed into the screw hole 29 of the support shaft 2. As shown in FIG. As the male screw member 28 is rotated forward and backward, the vertical movable plate 4 moves up and down in parallel with the axis L2 of the support shaft 2. The vertical movable plate 4 is urged upward by the compression spring 30. The compression spring 30 is compressed and refurbished between the inner bottom face of the user cylindrical portion 7 and the inner bottom face of the spring fitting recess 3 of the support shaft 2. The spring force of the compression spring 30 compresses the thick A portion between the inner bottom surface of the user cylindrical portion 7 and the head 28a of the male thread member 28, and the creep changes this thick A by creep change. It works to thin.

However, the spring force of the compression spring 30 is not applied between the inner bottom surface of the user cylindrical portion 7 and the upper surface of the main plate 5, so that the height of the magnetic head 12 due to creep changes. The change in dimensions can be suppressed to a negligible extent.

The tapered annular projection 31 gradually becomes small on the upper end face (outer bottom face) of the user cylindrical portion 7 gradually from the lower end side to the upper end side. The inner diameter of the annular projection 31 is set smaller than the diameter of the head 28a of the male screw member 28 as shown in FIG. Then, the head 28a of the male screw member 28 is forced into the annular projection 31 so as to be enlarged, thereby forcing the male screw member 28 to be relaxed.

The horizontal position adjusting mechanism 32 is provided at the end opposite to the magnetic head l2 of the main plate 5 of the vertical movable plate 4. This horizontal position adjustment mechanism 32 has the horizontal position adjustment body 33 of a planar circular state. Since the horizontal positioning member 33 is made of a synthetic resin, the horizontal positioning member 33 is eccentrically mounted to the mounting shaft 34 placed parallel to the support shaft 2 on the upper surface of the chassis 1, and is press-fitted with a rotating material. As shown in FIG. 1, the main surface 35 of the horizontal positioning member 33 has a distance from the axis L2 of the mounting shaft 34 parallel to the axis Ll of the support shaft 2 in plan view. Gradually changes in the rotational direction, and is parallel to its axis L2 in the side view as shown in FIG. Such a horizontal positioning member 33 is engaged with a rotational material and a perturbation material in a substantially rectangular engagement hole 36 formed at the side end of the anti-magnetic head 12 side of the main plate 5. One side edge of the engagement hole 36 is made of an elastic member (elastic mechanism) 37 having a narrow width. The elastic edge of the elastic member 37 makes the peripheral edge of the engagement hole 36 of the horizontal positioning member 33 The main surface 35 is elastically press-contacted. On the upper surface of the horizontal positioning member 33, a + -shaped tool insertion hole 38 is formed. Although not shown, a rotary head cylinder is provided at a predetermined position on the upper surface of the chassis 1.

Next, the operation of the magnetic head position adjustment mechanism of the VTR having the above-described configuration will be described. When the tool is inserted into the tool insertion hole 38 and the horizontal position adjusting body 33 is rotated clockwise in the first direction, the user cylinder The vertical movable plate 4 rotates horizontally clockwise about the support shaft 2 integrally with the portion 7, and the magnetic head 12 horizontally rotates integrally with the vertical movable plate 4. On the contrary, when the horizontal position adjusting body 33 is rotated counterclockwise, the vertical movable plate 4 rotates horizontally in the counterclockwise direction about the support shaft 2 and is integrally horizontally rotated with the vertical movable plate 4. Accordingly, the horizontal position of the magnetic head 12, that is, the distance from the rotating head cylinder, changes.

On the other hand, when the tool is inserted into the tool insertion hole to rotate the male screw member 28 in the clockwise direction during the first, the up and down movable plate 4 integrally with the user cylindrical portion 7 against the opposing force of the compression spring (30) The magnetic head 12 moves in a downward direction parallel to the axis L1 of the support shaft 2 and integrally with the vertical movable plate 4. In addition, when the male screw member 28 is rotated in the counterclockwise direction, the vertically movable plate 4 integrally with the user cylindrical portion 7 by the negative force of the compression spring 30 is parallel to the axis line Ll of the support shaft 2. The magnetic head 12 moves in an upward direction and integrally with the vertical movable plate 4.

Accordingly, the height position of the magnetic head 12, that is, the height position with respect to the tape running height, changes. As described above, it is possible to adjust the height position of the magnetic head l2 as the horizontal position of the magnetic head 12 and the male screw member 28 by rotating the horizontal position adjusting member 33, respectively. same.

In the present invention, the main surface 35 of the horizontal position adjusting body 33, which is different from the conventional one, is parallel to the axis L1 of the support shaft 2 in the side view. As a result, the male screw member 28 is moved. When the height position of the magnetic head 12 is adjusted by the rotation operation, the horizontal position of the magnetic head 12 does not change at all.

In the above embodiment, the inner circumferential surface of the user cylindrical portion 7 is formed as a polygon so as to be in point contact with the outer circumferential surface of the support shaft 2, but the present invention is not limited thereto. As shown in FIG. A plurality of cross-sectional semicircular protrusions 39 are integrally formed at equal intervals in the circumferential direction on the inner circumferential surface of the portion 7, and the outer circumferential surfaces of the support shafts 2 are pressed against each of the protrusions 39 so as to contact the outer circumferential surface of the support shaft 2. The inner circumferential surface of the user cylindrical portion 7 may be brought into point contact.

Moreover, the elastic mechanism is not limited to being comprised by the narrow elastic member 37 of the one side edge of the system hole 36 integrally formed with the main plate 5 mentioned above, As shown in FIG. 6, the main plate 5 Springs (37a) may be provided separately to form an elastic mechanism. The horizontal positioning member 33 may also be press-fitted in an elliptical shape concentrically with the shaft 34 as shown in FIG.

As described above, the magnetic head positioning mechanism of the VTR of claim 1 of the present invention can be rotated with respect to the chassis about an axis parallel to the axis of the horizontal positioning mechanism so that the distance from that axis in the plane changes in the rotational direction. At the same time, in the side view, the horizontal positioning member having a main surface parallel to the axis line and a part of the vertical movable plate are elastically elastically contacted to the main surface of the horizontal positioning member.

The magnetic head position adjustment mechanism of the VTR of claim 2 has a height position adjustment mechanism at the same time that the height position adjustment mechanism is installed between the inner bottom surface and the support shaft of the user cylindrical portion made of a synthetic resin in which the compression spring is installed on the upper and lower movable plates. And the adjustment screw member is screwed to the support shaft through a screw insertion hole provided in the center of the bottom portion of the user cylindrical portion as a male screw member.

Therefore, the configuration is simple, and even when the height position adjustment mechanism is adjusted, the magnetic head position adjustment can be performed with high accuracy without changing the horizontal adjustment mechanism.

Claims (2)

Height position adjustment is provided with an up and down movable plate having a bearing part fitted to the shaft installed in the chassis, and a magnetic head mounted through an azimuth adjustment mechanism, and a compression spring biased in one direction parallel to the axis of the axis of the up and down movable plate. The magnetic head positioning mechanism of the VTR is formed by a height positioning mechanism held by a screw member, and a horizontal positioning mechanism which adjusts the distance between the magnetic head and the rotating head cylinder by rotating the vertical movable plate about the support shaft. The horizontal positioning mechanism is rotatable about the chassis about an axis parallel to the support axis, and in a plane view the distance from the axis gradually changes in the rotational direction and in the side view a principal plane parallel to the axis line. A horizontal position adjusting body having a portion of the horizontal movable plate; The VTR, characterized in that formed from the elastic mechanism that elastically pressed against the main surface magnetic head position adjusting mechanism. Movement of the vertical movable plate having a bearing part fitted to the shaft installed in the chassis and mounted by a magnetic head through an azimuth adjustment mechanism, and a compression spring squeezed in one direction parallel to the axis of the vertical axis of the vertical movable plate. Magnetic head of the VTR made of a height positioning mechanism which is held by the height positioning screw member, and a horizontal positioning mechanism which adjusts the distance from the rotating head cylinder of the magnetic head by rotating the upper and lower movable plates about the support shaft. In the position adjusting mechanism, the height adjusting mechanism compresses and replaces the compression spring between the inner bottom surface of the user cylindrical portion made of synthetic resin and the supporting shaft, wherein the compression spring is installed on the upper and lower movable plates as the bearing portion. Screw insertion hole whose adjustment screw member is installed as the male screw member at the bottom center of the user cylindrical portion. A magnetic head position adjusting mechanism of a VTR which comprises the combined or to the shaft through the.

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