JPS59172177A - Mode switching device of vtr - Google Patents

Abstract

PURPOSE:To switch the mode of a VTR with a simple switching device, by using the sliding member of a worm coupled with a loading ring and supported slidably by the shaft of a motor as brake to both winding- and feeding-reel tables and working member of a pinch roller. CONSTITUTION:When a worm 7 is rotated, a loading ring 11 is driven through a gear and, when the loading ring 11 is stopped at the rotating end of the loading, the worm 7 slides on a shaft 6 and a sliding member 8 is moved. As the sliding member 8 moves, the braking device 4 of both winding- and feeding-reel tables 22 and 23 coupled to the sliding member 8 operates and a pinch roller driving device 5 is started to work. Therefore, by the rotation and movement in the axial direction of the worm 7, the loading ring, winding- and feeding-reel tables, and pinch roller can be controlled. Since the loading ring 11 is controlled by the rotation and movement in the axial direction of the worm 7 and the sliding member 8 which makes transversal movement in accordance with the worm works as the braking device 4 and working member of the pinch roller driving device 5, the constitution is simplified.

Description

[Detailed description of the invention] The present invention relates to a mode switching device for a VTR.

In order to reduce the weight and power consumption of VTR mode switching devices, there is a trend to adopt a motor logic mechanism instead of the conventional solenoid.

However, the conventional motor logic mechanism has a problem in that extremely complicated power transmission switching is required to control the brakes of the supply and take-up reel stands and drive the pinch rollers.

An object of the present invention is to provide a mode switching device using motor logic that does not require a complicated switching mechanism.

The mode switching device of the present invention has a loading ring (11
) is connected to the worm (7) via a gear, and the worm is supported by a rotating shaft (6) connected to the motor (3) so as to be able to rotate integrally with the shaft and to be able to slide in the axial direction.
A slide member (8) disposed movably along the rotation axis is connected to 7), and the slide member (8) takes up winding and brakes the supply side reel stand @ (to).
It also serves as the operating member for the pinch roller that presses the tape against the capstan (C).

The rotation of the worm (7) drives the loading ring (11) via the gear, and when it stops at the rotational end of loading, the worm (7) slides over the rotation shaft (6), and therefore the slide member (8) moves, and along with this, the winding and supply side reel stands (2) connected to the slide member move.
2) The brake device (4) of (23+) is activated, and the pinch roller drive device (5) is also activated.

As described above, the loading, supply and take-up reels, and pinch rollers can be controlled by the rotation and axial movement of the worm (7), so the mechanism can be simplified compared to the conventional one.

The present invention will be specifically described below based on embodiments shown in the drawings.

A stopper (13) on the chassis is placed on the bottom of the loading ring (11) that pulls out the tape (not shown) from the cassette (A) placed across both the supply and take-up reel stands @C3). A contact shaft (lla) that contacts the ring (11) to position the loading completion position, and a loading ring control lever (described later) when loading is completed.
12) and actuates the lever (1).
b) is provided protrudingly.

The gear 00) meshes with the gear surface (lie) of the loading ring (11), and the worm gear (
9) is fixed at consent.

A worm (7) meshes with the worm gear (9), and the worm (7) can rotate integrally with the rotating shaft (6) connected to the loading motor (3) and slide in the axial direction. It is movably fitted.

The worm (7) and the rotating shaft (6) are spline-fitted together, as shown in Figure 9, with a flat part (6a) on the outer periphery of the rotating shaft (6).
, and the shaft hole (7a) of the worm (7) is connected to the rotation shaft (6
) are fitted in accordance with the cross-sectional shape.

A slide member (8) is disposed on the reel stand (22) side with respect to the rotation axis (6) so as to be movable along the rotation axis,
A pair of contact pieces (8d) (8d) protruding from the slide member.
) is fitted onto the rotating shaft (6) with ample room, and is in sliding contact with both end surfaces of the worm (7) without inhibiting the rotation of the worm.

The slide member (8) is arranged parallel to the rotation axis (6),
It engages with a rail (not shown) and moves on the rail.

An arcuate cam surface (8g) is formed at the corner between the front end (8e) of the slide member (8) and the face (8f) on the reel side, and a cam groove (8a) is formed on the face (8f) on the reel side. ) has been established. The loading ring control lever (121 is the pivot (12d)) is located below the transition path of the slide member (8).
The center G can be swung in a plane parallel to the loading ring (it is pivoted).

The lever (loading ring 121 + 11) on the side (the tooth surface (12b) that can be engaged with the worm gear (9)
) is formed, and a protrusion (12a) that can engage with the arcuate cam surface (8g) of the slide member (8) is provided at the other end.

The lever (12I) is biased by a spring (12C) in a direction away from the worm gear (9).

A counter brake device (4) is provided between the slide member (8) and both reel stands @Q3), and the brake devices are arranged opposite to both supply and take-up +) -nov and @ (23), respectively. A pair of brake levers (151 (161) are installed, and a spring (17
At step 1, the blades (15a) and (16a) at one end of both renos are biased in the direction of approaching the reel stand (22+13).

Both brake levers (1) (16) and the slide member (
8) between the drive piece (141) and both brake leno<-+
15) (The drive piece (14) is arranged to be freely rotatable in a plane parallel to the rotation plane of 161, and has a cam that can be engaged with the cam groove (8a) of the slide member (8). Tube (1)
4a) and both brake levers (1ω (16)) to move the brake head (15a) (16a) to the reel stand (2).
2+ CI! 3) A contact protrusion (14b) separated from the
The drive piece (14) is urged toward the slide member (8) by a spring (14C).

An unloading brake lever (21) is swingably provided between the supply side reel stand (23) and the slide member (8), and the brake head (21C) at the tip of the lever (211) is rotated by a spring (21b). Supply side reel stand f23
It is biased in the direction away from +, and there is a slide member (
Arm plate (8) that can be secured to the protrusion (8C) provided on the rear side of
21B).

The rear end of the slide member (8) is equipped with a pinch roller drive device (
5) is provided with a protruding claw piece (8b) for activating.

The pinch roller drive device (5) is provided with a slide plate (54) movable in parallel with the slide member (8) outside the loading ring control lever αa, and has both ends of the chain plate (541) bent to form a contact portion ( 54a) (54b) are formed.

Between the vicinity of the capstan (C) and the slide plate (54J), insert the main lever (5
1) is provided, and the free end of the main lever (51) is in contact with the inner surface of the rear abutting portion (54b) of the slide plate (541).

The pivot (51a) of the main lever (51) has an auxiliary lever (5
2) is pivoted independently of the rotation of the main lever (51), and a pinch roller (53) is pivoted to the auxiliary lever (521).

The auxiliary lever (52) is attached to the pinch roller (
53) is urged away from the capstan (C), and the free end of the auxiliary lever (521) is linked to the main lever (51) by a spring (55).

In the drawing, (18) is a fixed tooth body (18) that is arranged adjacent to the worm gear (9) and can mesh with the worm (7). (19)
is a positioning stopper at the rearmost position of the slide member (8). (2) is an idler that is connected to the reel motor (1) and moves to either one of the two reel stands +221231 as necessary to rotationally drive the reel stand.

Next, the operation of the mode switching device will be explained.

Start of loading (Fig. 1) First, the worm (7) is rotated by the loading motor (3) via the rotating shaft (6). At this time, the protrusion (12a) of the loading ring control lever (121) hits the front end (8e) of the slide member (8) and
), the worm (7) rotates in a fixed position and rotates the loading ring (11) in the direction of the arrow through the worm gear (9) and gear (10). drive As a result, the tape is pulled out from the cassette (A) by the pull-out pin (not shown) on the loading ring (11), and the tape is pulled out from the cassette (A) by the pull-out pin (not shown) on the loading ring (11).
wrapped around.

Loading completed (Figures 2 and 3) The abutting shaft (lla) of the loading ring (11) hits the stopper (13) and loading is completed.

At this time, the operating shaft (llb) of the loading ring (11)
Push the loading ring control lever f12+ a little toward the worm gear (9) against the spring (12e),
Slide the protrusion (12a) of the lever (12) onto the slide member (8).
(Figure 2).

Even if the motor (3) rotates further, the loading ring (
11) does not move when it hits the stopper (13), and the rotation of the worm gear (9) is prevented, so the worm (7) moves to the right on the rotation axis (6), and the slide member ( 8) follows. Due to the lateral movement of the slide member (8), the protrusion (12) of the loading ring control lever (12)
a) slides over the cam surface (8g) and rides on the right surface (8f) of the slide member (8), and the lever (121) rotates slightly clockwise, causing the tooth surface (12b) to mesh with the worm gear (9). (Figure 3).

The position of the protrusion (12a) that has climbed onto the face (8f) of the slide member (8) does not change even if the slide member (8) moves further laterally, so that the lever (12a) does not change its position during subsequent setting operations.
The contact meshes with the worm gear (9) to prevent movement of the loading ring (11).

Stop mode (Fig. 4) As the loading motor (3) continues to rotate, the worm (7), which moves by sliding on the rotating shaft (6), comes off the worm gear (9) and moves to the fixed gear (18). mesh with.

At this time, the cam protrusion (14a) of the drive piece (141) of the brake device (4) fits into the cam groove (8a) of the slide member (8), and the abutment protrusion (14b) of the drive piece fits into the brake lever (15). ) Release the pressure on the base end of 061.This releases both brake levers (151 (head (15a) of 161).
(16a) is a reel stand (22+ (
Press 23+ to apply the brakes to the reel stand (22+23).

When the above state is reached, a detector such as a limit switch (not shown) placed at an appropriate location such as the transition path of the slide member (8)
The completion of loading is detected by , and the loading motor (3) is stopped to enter the stop mode.

FF or REW mode (Figure 5) When the FF or REW mode is selected, the loading motor (3) rotates in the opposite direction to that during loading, the slide member (8) returns slightly to the left from the stop mode, and the brake device The cam protrusion (14a) of the drive ring (4) escapes from the cam groove (8a) of the slide member (8) and rides on the face (8f) ic, and the contact protrusion (14b) touches the brake lever (15). Press the base end of (16) to release the brakes on both reel stands □□□ (23), and
REW operation becomes possible.

When the stop mode is selected from the above FF@REW mode, the state returns to the state shown in Fig. 4, but the reel stand (22)
Slide member (8) to activate the brake at 0731
The front end side surface (80) of the cam groove (8a) is connected to the slide member (
8) is preferably perpendicular to the straight plane (8f).

Possible mode (Fig. 6) When the possible mode is selected from the stop mode, the loading motor (3) rotates in the same direction as in the loading mode, and the worm (7) and slide member (8)
moves to the right, and the cam protrusion (14a) of the drive piece 04 of the brake device (4) escapes from the cam groove (8a) and rides on the rear face (8f) of the slide member (8).

As a result, the contact protrusion (14b) of the drive piece (141) presses the base end of the brake lever 09 (16), and the reel stand (
22) (Release the brake on 23+.

Further, as the slide member (8) moves, the claw piece (8b) of the member (8) catches the abutting part (54a) of the slide plate 17)+ of the pinch roller drive device (5) and moves it to the right. As a result, the pinch roller (53) presses the tape (not shown) against the capstan (C) via the main lever (51) and the auxiliary lever (5), and the mode becomes ready.

Even when the FF-REW mode is selected from the FF-REW mode, the cam protrusion (14a) of the drive piece (14) is always inserted into the cam groove (8a) of the slide member (8), as is clear from the shape of the slide member. In order to enter the stop mode, a brake is applied to the reel stands (22) and (23) at the time of mode switching to prevent the tape from loosening.

When you select stop mode from possible mode, the motor (
By rotating 3), the worm (7) reaches the state shown in Figure 4.
, the slide member (8) returns, releasing the pressure on the pinch roller (53) and applying a brake to the reel stand @C3).

Unloading When the unloading mode is selected from the stop state shown in Fig. 4, the motor (3) rotates in the opposite direction to that in the loading mode, passes through the FF-REW mode shown in Fig. 5, and reaches the state shown in Fig. 2. By moving the worm (7) and the slide member (8) to the left, the loading ring control lever (one protrusion (12a) passes through the cam surface (8g) of the slide member (8) ) on the front end (8e).

As a result, the tooth surface (12a) of the loading link control lever 02 is disengaged from the worm gear (9), and the loading ring (11) is unlocked.

Furthermore, as the motor (3) rotates, the load on the worm (7) is greater than the load of the axial movement of the fixed tooth (7), so the worm gear (9) and therefore the loading ring (11) do not reverse rotation, and the worm (7) ) further moves to the left on the rotating shaft (6) and enters the unloading brake state.

Unloading brake state (FIG. 7) In this embodiment, tape winding during unloading is performed by driving the take-up reel stand (2) to the idler (2) as shown in FIG. Therefore, if the supply reel 23+ is free when the idler (2) is driving to take up the tape, the tape is pulled out from the supply reel and the tape advances each time it is unloaded, which is inconvenient.

, Also, when loading, the tape is not wound on one reel, that is, the tape is starting to wind.

Since there is a state at the end of the reel, it is necessary that both reels be in a free state.

Considering the above two conditions, it is necessary to have a brake that acts on the supply reel only during unloading.

Therefore, when the slide member (8) moves further to the left from the state shown in FIG. Apply the brakes to the side reel growth.

In the above state, the slide member (8) is prevented from moving backward, and the worm (7) only rotates without sliding sideways, and reversely rotates the loading ring +11) via the worm gear (9) and gear 00). , unloading.

The unloading brake remains in operation during unroping ink, but at the time of the next loading operation, the load of the axial movement of the worm (7) will be greater than the rotational load of the loading ring (1). Because the worm is small (7), the worm moves to the state shown in Figure 1, and then the loading ring is driven by the worm, so the unloading brake (21+) does not work during loading.

As described above, the present invention uses the rotation and axial movement of the worm (7) to control the loading ring (11) and the slide member (8) that moves laterally following the worm to drive the brake device (4) and the pinch roller. Since it also serves as an operating member of the device (5), the configuration can be simplified.

The present invention is not limited to the structure of the above-described embodiment, and various modifications can be made within the scope of the claims.

[Brief explanation of drawings]

Fig. 1 is an explanatory diagram during loading, Fig. 2 is an explanatory diagram when loading is completed, Fig. 3 is an explanatory diagram immediately after loading is completed, Fig. 4 is an explanatory diagram of stop mode, and Fig. 5 is an explanatory diagram of F
An explanatory diagram of F@REW, Fig. 6 is an explanatory diagram of the possible mode, Fig. 7 is an explanatory diagram of the unloading mode, Fig. 8 is an oblique view of the main part, and Fig. 9 is a cross-sectional view of the rotating shaft and worm. be. (3)...Motor (6)...Rotating shaft (7
)...Worm (8)...Slide member (
4) Brake device (5) Pinch roller drive device Applicant: Sanyo Electric Co., Ltd.

Claims (1)

[Claims] ■ A worm (7) is connected to the loading ring (11) via a gear, and the worm (7) can rotate integrally with the rotating shaft (6) connected to the motor (3) and in the axial direction. A slide member (8) is connected to the worm (7) and movably disposed along the rotation axis (6), and the slide member (8) is slidably supported by the worm (7). Winding and supply side reel stand (brake device (4) and pinch roller drive device (5) of 22H23+ are arranged, slide member (8) is connected to these devices f4) (51
VTR mode switching device that regulates the operation of the VTR.