JPH03185663A - Tape loading mechanism - Google Patents

Abstract

PURPOSE:To surely execute the positioning of a tape drawing-out member in an unloading position by providing a pressing force means which generates a pressing force in a circumference direction between a ring gear and a transmission member, and allowing the pressing force means to abut against the ring gear in the unloading direction of the circumference direction. CONSTITUTION:When unloading, when a motor 22 rotates in reverse, a transmission member 32 moves a tape drawing-out member 4A by the turning of a ring gear 24, and the tape drawing-out member 4A returns to the unloading position and reaches the unloading mode position. The ring gear 24 continues to turn after the tape drawing-out member 4A and the transmission member 32 is stopped, a lever 40 is turned by a pin 28, and cassette loading/unloading operation is executed. At this time, the transmission member 32 receives the pressing force by abutting on a spring 39 to a 1st abutting part 35, and an accurate positioning is executed by pressing and fixing the tape drawing-out member 4A to the end part of a guide groove 2A. Thus, the accurate positioning can be executed at the cassette loading/unloading mode position of the tape drawing-out member.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a tape loading mechanism for a magnetic recording/reproducing device.

[Conventional technology]

7 to 9 are rear views showing a tape loading mechanism of a conventional magnetic recording/reproducing apparatus disclosed in, for example, Japanese Patent Application Laid-Open No. 62-71048.

In the figure, (1) is the chassis, (3) is the guide groove formed in this chassis (1), (4)
, (5) is the tape drawer member slidably supported by the guide groove 12), +31, f6), (71
Tape guides 1, (8) and +91 are installed upright on the tape pull-out members (4) and +51, respectively, and are fixed to the chassis (1) to position the tape pull-out members (4) and (51) at the loading position. stopper for
(10) is the first gear, which includes the chassis (guide member (IOA) provided on 11, Cl0B), (
It is rotatably supported while being guided by the inner peripheral portion (10a) by the IOc). (11) is the first ring gear (
10) A first transmission member that is slidably supported in the ring circumferential direction by two bottles (10b) erected above, and a spring stretched between the first transmission member and the first ring gear (10). (1
2) to the first gear (10).
The ring gear (10) is biased in the rotating direction (arrow X direction in the figure) during loading, and one end of the sliding hole (lla) of the first transmission member (11) comes into contact with the bin (10b). There is. Further, this first transmission member (11) is connected to a connecting member (13).
> is connected to the tape drawer member (4).

(14) is the second ring gear, and the first ring gear (10)
Similarly, guide members (IOA), (IOB), (IOC
) and is rotatably supported while being guided by.

(15) is a second transmission member supported on the second ring gear (14) like the first transmission member (11), and the spring (15) is a second transmission member supported on the second ring gear (14).
16), this second ring gear (14) is urged in the rotating direction (arrow Y direction in the figure) during loading, and is connected to the tape drawer member (5) by a connecting member (17).

(18) is a large gear (
18a) and a small gear (18b), the gear A1 (19) is pivotally supported on the chassis (1).
Gear B, which is pivotally supported on the chassis (1) and meshes with the large gear (18a) of
20) is an arm pivotally supported by the chassis (1), and this arm (20) is equipped with a small gear (18b) of the gear A (18).
) is formed to mesh with the fan-shaped gear portion (20a).

(21A) is driven by a motor (22) via a deceleration means (23), and has one end forming a first open end (21a) and the other end forming a first concentric portion (21b).
A first cam gear (21B) having a diameter 1c) and pivotally supported by the chassis (1) is meshed with the first cam gear (21A), with one end forming a second open end (21d) and the other end forming a second open end (21d). Cam groove (21f) forming the second concentric portion (21e)
This is a second cam gear that is pivotally supported by the chassis (1).

Note that (20b) is a first protrusion that is erected on the arm (20) and engages with the cam groove (21c), and (20c) is a second protrusion that is erected on the arm (20). is in a positional relationship to engage with the cam groove (21f).

Next, the operation will be explained.

FIG. 7 shows the tape drawer member (4L (5)) in the unloading position and in another mode position before the loading operation. When the motor (22) starts rotating, the deceleration means (23) through the first cam gear (2
1A) in the direction of arrow H in the figure. At this time, whether the first cam gear (21A) or the second cam gear (21B) can drive the mode switching means (not shown) to perform the necessary mode switching, or whether the arm (20) is connected to the first protrusion (20b). )
is located in the first concentric portion (21b) and remains stopped.

When the motor (22) continues to rotate further, the first protrusion (22)
0b) begins to rotate in response to the displacement of the first cam groove (21c), and the fan-shaped gear! Is (20a) Via large gear A (18) and gear B (19), the first ring gear (lO) rotates in the direction of arrow X in the figure, and the second ring gear (14) rotates in the direction of arrow Y in the figure. and start the tape roping operation.

Figure 8 shows the tape pull-out member +4 that is moved like this.
1. (5) shows the moving state, and at this time the first
The first protruding piece (20b) guided to the first cam groove (21c) of the cam gear (21A) reaches the first open end (21a), and the second protruding piece (20c) is guided to the first cam groove (21c) of the second cam gear (21B). The second open end (21d) is reached.

Furthermore, the first cam gear (21A) and the second cam gear (21A)
As B) continues to rotate, the arm (20) continues to rotate while the second projecting piece (20c) is guided by the cam groove (21f).

Eventually, the tape drawer member +41. +5+ reaches the stop flange 81, +9), and the tape pull-out member t41. +
51, the connecting members (13), (17), the first transmitting member (11), and the second transmitting member (15) are stopped.
The cam gear (21A) and the second cam gear (21B) continue to rotate, resulting in a gap between the first ring gear (10) and the first transmission member (11) and between the second ring gear (14) and the second transmission member. (15) Each of the baffles spanned between
l(12).

(16) is extended and the bottle (10b) is inserted into the sliding hole (lla).
), the tape pull-out member +41.
+51 respectively to the stoppers 181. (9) Press and fix. When the loading completion state as shown in FIG. 9 is reached, the motor (22) stops and descends.

Next, the unloading operation will be explained.

The unloading operation is the opposite of the above description.

That is, the motor (22) rotates in the opposite direction, and the deceleration means (23) rotates in the opposite direction.
) through the Ml cam gear (21A) and the second cam gear (
21B) in the P direction and Q direction in the figure, respectively. When the arm (20) rotates while the second projecting piece (20c) is guided by the cam groove (21f), the first 'J' gear (
10)", move the second ring gear (14) in the direction opposite to
) in the direction opposite to Y. These ring gears (10
), (14) is rotated by a predetermined angle, the bottle (10b) comes into contact with the end of the sliding hole (lla), and the tape drawer member (
41, +5) is separated from the stopper (8), +91 and moves in the unloading direction. When the second protruding piece (20C) reaches the second open end (21d), the first protruding piece (20b) is guided from the first open end (21a) to the cam groove (21c) to rotate the arm (20). Continue the movement.

Eventually, the first projecting piece (20b) becomes the first concentric shaped part (21b
), and the loading operation of the tape pull-out member (4) and +51 is completed, but the motor (22) continues to rotate, and the rotation of these cam gears causes the tape to enter another mode, such as the cassette loading/unloading mode. Migration can be done. Then, the state shown in Fig. 7 is restored and the motor (2
2) is stopped.

[Problem to be solved by the invention]

Since the conventional tape loading mechanism is configured as described above, the drive source continues to rotate continuously, for example, the tape drawing member (4).

(5) moves to another mode position such as cassette attachment/detachment mode after unloading is completed. Cam gears (21A) and (21B) each have a cam groove on the γ arm, and an arm (20 ), and the mechanism becomes complicated.
This increases the number of parts and becomes a major obstacle to miniaturization and weight reduction.Also, the positioning accuracy of the tape pull-out member (+41. 5) The accumulative accuracy of parts intervening in the transmission path leading to the cassette may cause problems such as misalignment and damage to the tape when attaching and detaching the cassette.

This invention was made in order to solve the f1 problem as mentioned above.It is a simple mechanism that does not require an intermittent drive means consisting of a cam gear or an arm, and the drive source continues to rotate even after the tape drawer member has completed unloading. The tape loading mechanism allows you to move to another mode by continuing the operation, and also allows you to reliably position the tape drawer member in the cassette attachment/detachment mode position! The purpose is to obtain a structure.

[Means to solve the problem]

A tape loading mechanism for a magnetic recording and reproducing apparatus according to the present invention includes a transmission member that is slidably supported in a circumferential direction by a ring gear that rotates by a drive source and engages with a tape pull-out member; a biasing means for generating a biasing force in a circumferential direction between the transmission member and the transmission member, the transmission member having a first contact portion with which the biasing means can abut in a circumferential unloading direction; However, the ring gear continues to rotate even after the tape pull-out member reaches the unloading position.

[Effect]

In the tape loading mechanism of this invention, the transmission member is biased in the unloading direction with respect to the ring gear, so after the tape drawing member completes unloading, the ring gear rotates while bending the elastic member. By doing so, it is possible to shift to the cassette attachment/detachment mode, and the tape drawer member is reliably positioned.

〔Example〕

An embodiment of the present invention will be described below with reference to the drawings.

Figures 1 to 4 are plan views of the VH5-C cassette type VTR, and Figure 5 is a detailed assembly drawing of the main parts. The explanation will be omitted. In the figure, (2A) is a guide l as a predetermined path, (4A) is a tape pull-out member that is slidably supported in this guide groove (2A), and (8A) is a tape pull-out member that is fixed to the chassis (1). A stopper (24) is a ring gear for positioning the tape drawer member (4A) at the loading position, and gear A (25), gear B (26), and gear C (27) are pivotally supported on the chassis (1). )
It is rotatably supported while being guided by. (
28) is a pin installed upright on the ring gear (24), (
29) is the third contact part, (30) is the fourth contact part, (29a
), (30a) are convex portions formed on the third contact portion (29) and the fourth contact portion (30), respectively, and (31) are the convex portions formed on the third contact portion (29) and the fourth contact portion ( The spring guide means (32) is formed approximately in the middle of the ring gear (30), and (32) is the transmission member.
Elongated holes (24a) provided in the circumferential direction of (24), (24)
b) through the hole (32a) on this transmission member (32)
.

(32b) respectively fixed bottles (33).

(34) so as to be slidable at a predetermined angle in the circumferential direction of the ring gear (24). (35) is the first abutting part, (36) is the second abutting part, and the first abutting part (
35) and the second contact portion (36) is configured to be equal to the distance Ll between the third contact portion (29) and the fourth contact portion (30). (35a) and (36a) are the first
Convex portions formed on the contact portion (35) and the second contact portion (36), (37) are formed on the first contact portion (35) and the second contact portion (36)
The spring guide means (38) formed approximately in the middle of is an arm-shaped portion and is connected to the tape drawing member (4A) by a connecting member (13A). (39) is a spring as a biasing means, which is bent by a predetermined amount and has one end attached to the third contact portion (29).
) and the first abutting part (35) i;, and the other end is attached to the fourth abutting part (30) and the second abutting part (36). (40) is a lever as a mode switching means, which is supported by a shaft (41) on the chassis (11).
) is biased clockwise by a spring (42) stretched between. (43) is a stopper installed on the chassis (1), (44) and (45) are motors (2) as driving sources.
Gear D and Gear E are driven by Gear A (2).
5) are engaged.

Next, the operation will be explained.

Figure 1 shows the cassette loading/unloading mode position.
39) is bent by a predetermined distance and supported under pressure, and this pressing load: the tape pull-out member (4A) is pushed into the guide groove (
2A) is abutted and positioned at the end. When the loading operation starts, the motor (22) starts rotating, and gear D (44), gear E (45), gear A (25)
The driving force is transmitted to the ring gear (24) as shown by the arrow X in the figure.
The tape pull-out member (4A) starts a loading operation along the guide groove (2A). Due to this action, the amount of deflection of the spring (39) decreases,
Upon reaching the unloading mode position shown in Figure 2,
The abutting action of the tape pull-out member (4A) against the end of the guide groove (2A) is released, and the tape pull-out member (4A) moves in the loading direction along the kite groove (2A). This intermediate state is shown in FIG. When the tape drawer member (4A) reaches the stopper (8A), the tape drawer member (4A), the connecting member (13A), and the transmission member (3
Even after the transmission member (2) has stopped, the ring gear (24) continues to rotate, and as a result, the ring gear (24) has stopped the transmission member (2).
32) in the direction of the arrow X, causing a displacement between them, and therefore the splash (39) is caused by the third contact part (29) of the ring gear (24) and the second contact part of the transmission member (32). (36). At this time, the spring (39) has a convex portion (29
a), (36a) and the spring guide means (3
1) and (37), it flexes stably. At this time, the transmission member (32) receives a biasing force in the direction of the arrow X, and the connecting member (
The tape pull-out member (4A) is pressed and fixed to the nutoppa (8A) via the tape pull-out member (13A), and the motor (22) is stopped. FIG. 4 shows a state in which the loading operation has been completed in this manner, that is, a loading mode position.

Next, the unloading operation will be explained.

When the motor (zero 2) starts rotating in reverse from the state shown in FIG. 4, the ring gear (24) rotates in the direction of arrow Y. This rotation restores the mutual misalignment between the transmission member (32) and the ring gear (24) and returns them to the neutral position, and thereafter the transmission member (32) moves together with the ring gear (24).
Tape drawer member (4A) via connecting member (13A)
move in the direction of arrow Y.

In this way, the tape pull-out member (4A) reaches the end of the guide groove (2A), and the tape pull-out member (4A) returns to the unloading position and reaches the unloading mode position. Tape drawer member (4A), connection member (
13A), the ring gear (24) continues to rotate even after the transmission member (32) stops, and as a result, the spring (39) connects the fourth contact portion (30) of the ring gear (24) with the transmission member (32). )
The ring gear (
24) moves with respect to the stopped transmission member (32) in the direction of arrow Y with a mutual deviation between them, and eventually the pin (28) rotates the lever (40) in the direction of arrow R to perform cassette attachment/detachment operation (details). (omitted)>, the motor (22) stops, and reaches the state shown in Fig. 1, that is, the cassette attachment/detachment mode position.At this time, the transmission member (32) has a spring (39) that is connected to the first contact portion (3).
5) receives a biasing force in the direction of arrow Y, presses and fixes the tape pull-out member (4A) to the end of the guide groove (2A) and positions it accurately, preventing tape damage when attaching or removing the cassette. There are no words to give.

Incidentally, in the above embodiment, the biasing means is composed of one spring (39), and the biasing means is composed of one spring (39).
The biasing means and the second biasing means may be provided independently. 6th
In the figure, spring A (39A), which is the first biasing means, is
The first contact portion (35) has one end provided on the transmission member (32).
) The fifth contact portion (46) provided on the ring gear (24)
), and the other end is abutted against a third abutting portion (29) provided on the ring gear (24) and is bent by a predetermined amount. Spring B (39B), which is the second biasing means, has one end connected to a second contact part (36) provided on the transmission member (32) and a sixth contact part (47) provided on the ring gear (24). ), and the other end is abutted against a fourth abutting portion (30) provided on the ring gear (24) and is bent by a predetermined amount.

In the loading mode position, that is, when the ring gear (24> is moving in the direction of arrow X with respect to the transmission member (32) and there is a misalignment between them, the spring B (39B) is connected to the second contact portion (36). and the fourth contact portion (30), and the transmission member (32) receives a biasing force in the direction of arrow X. At this time, nB (39B)
It is positioned in a) and flexes stably. Also, spring A (39
A) is positioned by the convex portions (30a) and (46a), and is held at an initial predetermined deflection by contacting the third contact portion (29) and the fifth contact portion (46). Next, in the cassette attachment/detachment mode position, if the ring gear (24) moves in the direction of arrow Y with respect to the transmission member (32) and causes a misalignment between them, the first spring A (39A) The transmission member (32) is deflected between the contact portion (35) and the third contact portion (29), and receives a biasing force in the direction of arrow Y.

At this time, spring A (39A) is a convex portion (30a).

It is positioned at (35a) and deflects stably. Also, spring B
(39B) is positioned by the convex portions (29a) and (47a) and is held in its initial predetermined deflection by contacting the fourth contact portion (30) and the sixth contact portion (47).

〔Effect of the invention〕

As described above, according to the present invention, the biasing means for generating a biasing force in the circumferential direction is provided between the ring gear and the transmission member, and the biasing means is applied to the ring gear in the unloading direction in the circumferential direction. Since it is configured to have a first abutting portion that can be brought into contact with the first abutting portion, a simple mechanism that does not require an intermittent drive means consisting of a cam gear or an arm can shift to the cassette loading/unloading mode after the tape pulling member completes unloading. This has the effect of providing a tape loading mechanism that can reliably position the tape drawer member at the unloading position.

[Brief explanation of drawings]

FIGS. 1 to 4 show an embodiment of the present invention (this is a tape loading mechanism), and are plan views of various states of operation,
5 is an assembly diagram showing details of the main parts of FIG. 1, FIG. 6 is the same view as FIG. 5 showing another embodiment of the present invention, and FIGS. 7 to 9
The figure shows a conventional tape loading mechanism, and is a rear view of the tape loading mechanism in various states of operation. In the figure, (1) is the chassis, (2A) is the guide groove,
(4A) is a tape pull-out member, (6), +71 is a tape guide, (8A) is a stopper, (24) is a ring gear, (32) is a transmission member, (39) is a spring, (29), (
30), (35), and (36) indicate contact portions. Note that the same reference numerals in the figures indicate the same or equivalent parts.

Claims (1)

[Claims] (1) A ring gear rotated by a drive source, a tape drawer member that reciprocates between a loading position and an unloading position along a predetermined path according to forward and reverse rotation of the ring gear, and this tape drawer. In a tape loading mechanism of a magnetic recording and reproducing device having a tape guide installed upright on a member, the transmission member is slidably supported by the ring gear in a circumferential direction and engages with the tape draw-out member; and a biasing means that generates a biasing force in the circumferential direction between the transmitting member and the transmitting member, and the transmitting member includes a first contact portion with which the biasing means can abut in the unloading direction in the circumferential direction. A tape loading mechanism characterized in that the ring gear rotates even after the tape pull-out member reaches an unloading position.