JPS6220616B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a tape recorder, and more particularly to a tape recorder in which the rotational force of a motor is used to rotate a reel stand at high speed and run a magnetic tape at high speed.

Conventionally, in tape recorders that can run a magnetic tape at high speed by rotating a reel stand at high speed, the high-speed running means is directly controlled by an operating member to run the magnetic tape at high speed, which requires a large operating force. There were drawbacks such as loud operation noise. There are also systems in which the above-mentioned high-speed traveling means is controlled by electromagnetic drive means such as solenoids, but this requires a large-capacity electromagnetic drive means and has problems such as high power consumption, large device size, and large noise. There were flaws.

Furthermore, when the magnetic head is in deep contact with the magnetic tape during playback, it is moved back to a shallow contact position and the tape is moved at high speed to detect the position of the tape. This had the disadvantage that a large amount of power was required, as the vehicle was forced to move from a position where it was in shallow contact to a position where it was in shallow contact, against the bias of a spring, etc., and at the same time traveled at high speed. In order to solve this problem, a means for moving the magnetic head,
Some vehicles have separate means for high-speed running and are driven by each vehicle, but this has disadvantages such as the complexity of the device, the larger size of the device, and the higher cost.

The present invention provides a tape recorder which eliminates these drawbacks at once and improves the precision of tape position detection operation.Examples of the present invention will be described below with reference to the drawings.

In the figure, 1 is a base plate, 2 is a first capstan, and has a first small gear, a first large gear 4, and a first flywheel 5 concentrically and integrally.

A second capstan 6 has a second small gear 7, a second large gear 8, and a second flywheel 9 concentrically and integrally.

The counterclockwise rotation of the motor 11 is transmitted to the first and second flywheels 5 and 9 via the belt 10, with the first flywheel 5 clockwise and the second flywheel 9 It is designed to be rotated counterclockwise.

Reference numeral 12 denotes a first reel stand, which is rotatably provided on the shaft 13 and has a first large reel gear 14 and a first small reel gear 15.

A second reel stand 16 is rotatably mounted on the shaft 17 and has a second large reel gear 18 and a second small reel gear 19.

The first and second large reel gears 14 and 18 are provided with a slip mechanism (not shown), and the first and second reel stands 1 are connected to each other via the slip mechanism.
2 and 16, these use a well-known configuration and will not be described in detail here.

Reference numeral 20 designates a first head board on which a first magnetic head 21 is mounted, and has a pin 22. The shaft 23 is connected to the board 1 through a long hole (not shown) in the board 1 that guides the pin 22. It is slidably provided.

24 is a second head board on which a second magnetic head 25 is placed, has a pin 26, and is connected to a shaft 27 of the board 1 and a long hole (not shown) in the board 1 that guides the pin 26. It is slidably provided.

28 is a drive rod, a pin 29 provided at one end is slidably provided in a long hole (not shown) in the substrate 1, and a pin 30 provided at the other end is a power lever 31.
It is connected to one end 31a of , and the whole is biased in the direction of arrow A by a spring 32.

The T-shaped lever 33 is a right-reverse lever, and is swingably attached to the pin 29 at one end of the drive rod 28, and has pins 34 and 35 at both ends.
a has a long groove 33b and inclined surfaces 33c and 33d, and the first and second head substrates 20 and 24
Holes 33e, 33 into which the pins 22, 26 are inserted
It has f.

36 is a first pinch roller lever, which is swingably provided on a shaft 37, and which is connected to a first pinch roller 38,
It has a pressure spring 39 and is engaged with the pin 34 of the opposite lever 33.

40 is a second pinch roller lever, which is swingably provided on a shaft 41, and which is connected to a second pinch roller 42,
It has a press-contact spring 43 and is engaged with the pin 35 of the opposite lever 33.

The spring 44 is connected to the pin 2 at one end of the drive rod 28.
9, and the first and second head substrates 2
0 and 24 pins 22 and 26 are biased in the direction of arrow B.

A winding lever 45 is swingably mounted on a shaft 46, and a pin 47 at one end is engaged with a control hole 28a of the drive rod 28.

48 is a winding gear lever, a first winding gear 50 is connected to a shaft 49 at one end, and a second winding gear is connected to a shaft 51 at the other end.
The winding gear 52 is rotatable, and the central long groove 48a is connected to the pin 47 at one end of the winding lever 45.
is engaged with.

Reference numeral 53 denotes a switching lever, which is swingably provided on a shaft 54, and one end of the shaft 55 is engaged with the long groove 33b of the central end 33a of the opposite lever 33, and the slanted surface 33
c, 33d, and the other end 53
a is connected to switching means 56.

Further, the hole 45 at the other end of the winding lever 45
It has a leaf spring 57 that is engaged with a. The switching means 56 is a well-known one and will not be described in detail here.

Reference numeral 58 denotes a first fast-forwarding lever, which is swingably provided on a shaft 59. A first fast-forwarding gear 61 is rotatably provided on a shaft 60 at one end, and has a pin 62 at the other end, and is supported by a spring. (not shown) to rotate counterclockwise. Reference numeral 63 denotes a second fast-forwarding lever, which is slidably provided on the shaft 64 and is connected to the shaft 6 at one end.
5 is rotatably provided with a second fast-forwarding gear 66, which has a pin 67 at the other end and is urged to rotate clockwise by a spring (not shown).

Reference numeral 68 denotes a rapid feed rod, which is swingably mounted on a shaft 69, and U-shaped tip portions 68a and 68b biased in the direction of arrow A by a spring 95 are attached to the pin 62 at the other end of the first rapid feed lever 58; and a pin 67 at the other end of the second fast-forwarding lever 63.

Furthermore, the elongated hole 68c is connected to a pin 71 at one end of the fast-forward drive lever 70.

The power lever 31 has a shaft 72,
This shaft 72 is slidably provided in the elongated hole 1a of the substrate 1, and the pin 73 at the other end 31b is connected to a cam 75a of a first drive pulley 75 rotatably provided in the shaft 74 of the substrate 1. It is adapted to be pressed into contact with the spring 76.

The first driving pulley 75 includes a gear portion 75b,
Toothless portion 75c, first and second locking portions 75d, 75
It has e.

The gear portion 75b is rotatably provided on the shaft 74 and meshed with a drive gear 79a of a power pulley 79 rotated counterclockwise by the motor 11 via a belt 78.

Reference numeral 80 denotes a first lock lever, which is swingably mounted on the shaft 81 and urged counterclockwise by a spring 76, and a convex portion 80a at one end engages the first and second lock levers of the first drive pulley 75. The other end 75b can be locked with the stop portions 75d and 75e, and the other end 75b is connected to the regeneration solenoid 82.
is connected to.

The fast-forward drive lever 70 is swingably provided on a shaft 83, the other end 70a is brought into contact with the shaft 72 of the power lever 31, and the pin 84 at the center end is rotatably provided on the shaft 85 of the base plate 1. It comes into contact with the first and second cams 86a and 86b of the second drive pulley 86, and is pressed against the second cam 86b by a spring 87.

The second drive pulley 86 has a gear portion 86c, first and second toothless portions 86d and 86e, and first and second locking portions 86f and 86g.

The gear portion 86c is adapted to mesh with a drive gear 79a of the power pulley 79.

Reference numeral 88 denotes a second lock lever, which is swingable around a shaft 89 and biased clockwise by a spring 87, and a convex portion 88a at one end is connected to the second drive pulley 86.
The other end 88b is connected to a fast-forwarding solenoid 89.

A switching rod 90 is slidably mounted on a shaft 91, one end 90a of which is connected to a switching solenoid 92, and biased by a spring 93 in the direction of arrow C.

First and second step portions 90 of the switching rod 90
b and 90c are adapted to come into contact with pins 62 and 67 at the other ends of the first and second fast-forwarding levers 58 and 63, respectively.

Next, the operation of the above configuration will be explained. First, the first constant speed running operation will be explained.

When the regeneration solenoid 82 is operated in the stopped state shown in FIGS. 1 and 2 and with the switching lever 53 in the position shown in FIG. The first locking portion 75d of the first drive pulley 75 and the convex portion 80a at one end of the first lock lever 80 are unlocked from each other.
At this time, the first driving pulley 75
c is located on the drive gear 79a, the spring 76 biases the pin 73 at the other end of the power lever 31 toward the first inclined portion 75a' of the cam 75a, and the first drive pulley 75 is urged to rotate clockwise, so the gear portion 75b of the first drive pulley 75 and the drive gear 79a mesh with each other, causing the first drive pulley 75 to rotate clockwise.

When the first drive pulley 75 is rotated clockwise, the power lever 31 is rotated counterclockwise by the cam 75a about the shaft 72 that abuts the other end 70a of the fast-forward drive lever 70,
The drive rod 28 is slid in the direction of arrow B against the spring 32.

Further, when the first driving pulley 75 is rotated clockwise, the driving gear 79a and the gear portion 75d
The meshing is released by the toothless portion 75c, and at the same time, the pin 73 at the other end of the power lever 31 is located at the second inclined portion 75a'' of the cam 75a, and the pin 73 is biased by the spring 76. Furthermore, since the power lever 31 is biased clockwise by the spring 32 of the drive rod 28, the first drive pulley 75 is biased clockwise.
Convex portion 80a at one end of the first lock lever 80
is the second locking portion 75 of the first drive pulley 75
e is locked, so it is held in the state shown in Fig. 3.

When the drive rod 28 is slid in the direction of arrow B, the take-up lever 45 becomes swingable under the control of the hole 28a of the drive rod 28, and is moved counterclockwise by the leaf spring 57 of the switching lever 53. It is biased and rotated as shown in FIG.

When the winding lever 45 is rotated as shown in FIG. 3, the winding gear lever 48 is engaged with the pin 47 at one end of the winding lever 45, so it moves as shown in FIG. The first take-up gear 50 meshes with the first small gear 3 and the first large reel gear 14, and controls the clockwise rotation of the first small gear 3 from the first large reel gear 14. , that is, it is transmitted to the first reel stand 12.

At the same time, when the drive rod 28 is moved in the direction of arrow B, the opposite lever 33 is also moved in the same direction.

When the opposite lever 33 is moved in the direction of the arrow B, the long groove 33b of the central end 33a is engaged with the shaft 55 at one end of the switching lever 53 via the inclined surface 33c, and as shown in FIG. It is placed in a state where it is rotated slightly in the direction.

When the opposite lever 33 is moved as shown in FIG. 4, the pressure spring 39 of the first pinch roller lever 36 is operated by the pin 34, and the first pinch roller 38 is pressed against the first capstan 2. The reel hub (not shown), which is stored in the tape cassette 94 and is engaged with the first reel stand 12, and the second
Magnetic tapes (not shown) each having both ends fixed to a reel hub (not shown) engaged with the reel stand 16 are run in a first direction (direction of arrow C). Furthermore, the first head board 20 is also slid in the direction of arrow B by the spring 44, resulting in the state shown in FIG. 3, and the first magnetic head 21 is brought into deep contact with the magnetic tape to perform a reproducing operation. At this time, the second head board 24 is also slid in the direction of the arrow B, but the pin 26 is controlled by the hole 33f of the opposite lever 33, and the second magnetic head 25 is shallowly moved relative to the magnetic tape. Back tension is applied to make contact with the magnetic tape and stabilize the running of the magnetic tape.
Further, the second pinch roller lever 40 is configured to separate the second pinch roller 42 from the second capstan 6 by the pin 35 of the forward/reverse lever 33, thereby performing the first constant speed running operation.

Next, the second constant speed running operation will be explained. When the switching means 56 is operated from the first constant speed traveling operation state shown in FIGS. 3 and 4, the switching lever 53 is rotated clockwise to the state shown in FIG. 6. When the switching lever 53 is in the position shown in FIG. 6, the normal/reverse lever 33 is rotated counterclockwise to the position shown in FIG. 34 is rotated clockwise to separate the first pinch roller 38 from the first capstan 2 as shown in FIG. The second pinch roller 42 is pressed against the second capstan 6 to run the magnetic tape in the second direction (direction of arrow D), thereby performing a second constant speed running operation.

At the same time, the pin 22 of the first head board 20 is controlled by the hole 33e of the opposite lever 33,
As shown in FIG. 5, the first magnetic head 21 is brought into shallow contact with the magnetic tape. Also, the second head board 2
4, the pin 26 is moved by the spring 44 as shown in FIG. 5, and the second magnetic head 25 is brought into deep contact with the magnetic tape to perform a reproducing operation.

Further, the switching lever 5 is operated by the switching means 56.
3 is in the position shown in Fig. 6, and in the stopped state (first
When the regeneration solenoid 82 is operated from the state shown in the figure, a second constant speed running operation is performed as shown in FIGS. 5 and 6. This operation is almost the same as the first constant speed running operation, so the explanation will be omitted.

The pressure contact spring 43 of the second pinch roller lever 40 in the first constant speed travel operation and the pressure contact spring 39 of the first pinch roller lever 36 in the second constant speed travel operation are connected to the respective blocking portions 40a, 36a, it is brought into a non-operating state, and no load is applied to the normal/reverse lever 33.

When the operation of the regeneration solenoid 82 is released from the first and second constant speed running states shown in FIGS. 3 and 4 and FIGS. 5 and 6, the first lock lever 80
is rotated counterclockwise by the spring 76, and the convex portion 80a at one end is separated from the second locking portion 75e of the first drive pulley 75. At this time, the first driving pulley 75 is attached to the second inclined portion 75a'' of the cam 75a, and the pin 7 at the other end of the power lever 31
3 is pressed together, so it is rotated clockwise,
At the same time, a convex portion 80a at one end of the lock lever 80
The second locking portion 75 of the first drive pulley 75
d is locked, the first drive pulley 75
is assumed to be in the state shown in Figures 1 and 2.

When the first driving pulley 75 is in the state shown in FIGS. 1 and 2, the power lever 31, drive rod 28, etc. are also brought into the state shown in FIGS. 1 and 2, and are stopped. Note that the stopped state in Figures 1 and 2 is
This is an operation in which the tape is running at a constant speed in the running direction.

Next, the first high-speed running operation will be explained.

When the fast-forward solenoid 89 is operated from the stopped state shown in FIGS. 1 and 2, the second lock lever 88 is rotated counterclockwise against the spring 87, and the second drive pulley 86 is rotated counterclockwise against the spring 87. The first locking portion 86f and the convex portion 8 at one end of the second lock lever 88
8a is unlocked. At this time, the second drive pulley 86 is biased by a spring 87 to the pin 84 at the center end of the rapid-forward drive lever 70 to the first slope 86b' and second slope 86b'' of the second cam 86b. As a result, the pin 71 at one end is urged to rotate clockwise and is movable within the elongated hole 68c of the fast-forwarding rod 68, so the second drive pulley 86 is rotated clockwise and The gear 79a and the gear portion 86b are engaged with each other and rotated to a state where the second toothless portion 86e faces the drive gear 79a as shown in FIG.
The locking portion 86g is locked by the convex portion 88a at one end of the second lock lever 88, and as shown in FIG. , and the rapid feed rod 68 is slid in the direction of arrow B against the spring 95.

The rapid feed rod 68 is connected to the spring 95 as shown in FIG.
When the first fast-forwarding lever 58 is slid in the direction of arrow B against the pressure, the pressure of the U-shaped tip 68a of the fast-forwarding rod 68 against the pin 62 is released, and the first fast-forwarding lever 58 is pushed back by a spring (not shown). The first fast-forwarding gear 61, which is rotated clockwise and as shown in FIG.
The first reel stand 12 is rotated clockwise. At this time, the second fast-forward lever 63 releases the U-shaped tip 68b from pressing the fast-forward rod 68 against the pin 67 at the other end, but the second step 90c of the switching rod 90 Since the pin 67 at the other end of the fast-forwarding lever 63 is prevented from being biased clockwise by a spring (not shown), the second fast-forwarding gear 66 is rotated counterclockwise. It is separated from the large gear 8 and the second small reel gear 19.
Therefore, the magnetic tape is run at high speed in the first direction (direction of arrow C).

Next, the second high-speed running operation will be explained.

In the stopped state shown in FIGS. 1 and 2, and with the switching solenoid 92 operated and the switching rod 90 sliding as shown in FIG.
9 is operated, the rapid feed rod 68 is slid in the direction of arrow B against the spring 95, as shown in FIG. 8, similarly to the first high-speed running operation.

The rapid traverse rod 68 is connected to the spring 9 as shown in FIG.
When the second fast-forwarding lever 63 is slid in the direction of arrow B against the arrow B, the pressure of the U-shaped tip 68b of the fast-forwarding rod 68 against the pin 67 is released.
The second fast-forward gear 66 is rotated clockwise by a spring (not shown), and as shown in FIG. 8, the second large gear 8 and the second small reel gear are rotated counterclockwise. 19, and the second reel stand 16 is rotated counterclockwise. At this time, the first fast-forwarding lever 58 is released from the pressing of the U-shaped tip 68a of the fast-forwarding rod 68 against the pin 62 at the other end, but is pressed by a spring (not shown) Since the rotation bias in the counterclockwise direction is prevented by the first fast-forwarding gear 61, the first fast-forwarding gear 61 is separated from the first large gear 4 and the first small reel gear 15, which are rotated clockwise. Therefore, the magnetic tape (not shown) is run at high speed in the second direction (direction of arrow D).

When the operation of the fast-forward solenoid 89 is released from the first and second high-speed running states shown in FIGS. 7 and 8, the second lock lever 88 is
The convex portion 88a at one end engages the second locking portion 86g of the second driving pulley 86.
be separated from At this time, the second drive pulley 8
6 is the first and second inclined portions 86 of the first cam 86a.
a', 86a'', the pin 84 at the center end of the fast-forward drive lever 70 is pressed into contact with the pin 84 at the center end of the fast-forward drive lever 70 by the urging of the fast-forward rod 68 in the direction of arrow A by the spring 95, so that it is rotated clockwise. Drive pulley 8
The gear portion 86c of No. 6 is engaged with the drive gear 79a, and the second drive pulley 86 is rotated clockwise.

When the second drive pulley 86 is rotated clockwise, the fast-forward drive lever 70 is rotated clockwise by the second cam 86b of the second drive pulley 86.

Further, when the second drive pulley 86 is rotated clockwise, the drive gear 79a and the gear portion 86c
is released by the first toothless portion 86d, and at the same time the pin 8 at the center end of the rapid-forward drive lever 70 is released.
4 is the first inclined portion 86 of the second cam 86b.
b', and the pin 84 is biased by the spring 87, thereby biasing the second driving pulley 86 clockwise. Since the first locking portion 86f of the second drive pulley 86 is locked, the first
It is maintained in the state shown in Figure 2.

When the fast-forward drive lever 70 is rotated clockwise from the state shown in FIGS. 7 and 8 to the state shown in FIGS. 1 and 2, the fast-forward rod 68 is slid by the spring 95 as shown in FIG. , U-shaped tip portions 68a, 6
8b is the first and second fast-forwarding lever 58, 6.
Press the pins 62 and 67 at the other end of 3 to bring it to a stopped state as shown in FIG.

Next, the operation of detecting the position of the magnetic tape will be explained.

First, the position detection operation in the first constant speed running operation state will be explained.

When the fast-forward solenoid 89 is operated from the first constant-speed traveling operation state shown in FIGS. 3 and 4, the first
Similarly to the high speed running operation, the magnetic tape is run at high speed in the first direction. At the same time, as shown in FIG. 9, the fast-forward drive lever 70 is rotated counterclockwise, so that the shaft 72 of the power lever 31 is also released, and the power lever 31 moves around the pin 73 at the other end as a fulcrum. Although it is rotated clockwise, the position is regulated by the elongated hole 1a of the substrate 1, so that it is held in the state shown in FIG.

When the power lever 31 is brought into the state shown in FIG. 9, the drive rod 28 and the opposite lever 33 are also changed from the state shown in FIG. 3 to the state shown in FIG.
The pin 47 at one end of the winding lever 45 is brought to a neutral position by the hole 28a of the drive rod 28, and the winding gear lever 48 is also brought to a neutral position as shown in FIG. Reel stand 1
Rotation transmission to 2 is released.

At the same time, the first and second head substrates 20, 24
is also slid in the direction of arrow A as shown in FIG. 9 through the holes 33e and 33f of the opposite lever 33. At this time, the long groove 33 of the center end 33a of the above-mentioned right-reverse lever 33
b remains engaged with the shaft 55 at one end of the switching lever 53, so the first magnetic head 24 is brought into shallow contact with the magnetic tape, and the second magnetic head 25 is spaced apart. It is said to be in a state of

Further, the first pinch roller 38 is also connected to the first capstan 2 by the pin 34 of the opposite lever 33.
The position detecting operation is performed by moving the vehicle at high speed in the first direction (direction of arrow C) in the first constant speed running state.

The position detection operation by running at high speed in the second direction (direction of arrow D) can be performed by starting from the first constant speed running operation to the second high speed running operation.

Next, the position detection operation in the second constant speed traveling operation state will be explained.

When the switching solenoid 92 is operated from the second constant speed running state shown in FIGS. 5 and 6, and the fast forward solenoid 89 is further operated, the second direction (arrow The magnetic tape is run at high speed in the direction D). At the same time, the fast-forward drive lever 70 is rotated counterclockwise as shown in FIG.
is also released, and when the power lever 31 is rotated clockwise about the pin 73 at the other end, its position is regulated by the elongated hole 1a of the base plate 1, so it is held in the state shown in FIG. be done.

When the power lever 31 is brought into the state shown in FIG. 11, the drive rod 28 and the opposite lever 33 are also slightly slid in the direction of arrow A from the state shown in FIG. 5 to the state shown in FIG. The pin 47 at one end of the take lever 45 is inserted into the hole 28a of the drive rod 28.
The winding gear lever 4 is set to the neutral position.
8 is also set at the neutral position as shown in FIG. 11, and rotation transmission to the second reel stand 16 is released.

At the same time, the first and second head substrates 20, 24
is also slid in the direction of arrow A as shown in FIG. 11 through the holes 33e and 33f of the opposite lever 33. At this time, the long groove 33a of the center end of the above-mentioned right-reverse lever 33
3b remains engaged with the shaft 55 at one end of the switching lever 53, so that the second magnetic head 25 is brought into shallow contact with the magnetic tape.
The first magnetic head 21 is kept separated.

Further, the second pinch roller 42 is also separated from the second capstan 6 by the pin 35 of the forward/reverse lever 33, and position detection is performed when the second pinch roller 42 is moved at high speed in the second direction (arrow D direction) in the second constant speed running state. perform an action.

The position detection operation by running at high speed in the first direction (direction of arrow C) can be performed by starting from the second constant speed running operation and then performing the above-mentioned first high speed running operation.

As explained above, the tape recorder of the present invention can operate at high speed using the rotational force of the motor, can be operated with small operating force, can operate quietly and smoothly, can operate with low power consumption, and can be There are effects such as miniaturization.

Further, since the tape position detection operation can be performed with a simple configuration and the high-speed running operation can be stopped at the same time as the tape position detection, the accuracy of cueing etc. is high.

[Brief explanation of the drawing]

FIG. 1 is a schematic plan view showing the stopped state of the tape constant speed running means of a cassette type tape recorder according to an embodiment of the present invention, and FIG. 2 shows the stopped state of the constant speed running means switching means and the high speed running means. FIGS. 3 and 4 are schematic plan views showing the constant speed running operation in the first direction, and FIGS. 5 and 6 are schematic plan views showing the constant speed running operation in the second direction. A plan view, FIG. 7 is a schematic plan view showing high-speed running operation in the first direction, FIG. 8 is a schematic plan view showing high-speed running operation in the second direction,
9 and 10 are schematic plan views showing a state in which the tape position detection operation is performed when the tape is running at high speed in the first direction from a constant speed running state in the first direction, and FIGS. 11 and 12 are the same. FIG. 7 is a schematic plan view showing a state in which the tape is moved from a constant speed running state in a second direction to a high speed running state in a second direction and a tape position detection operation is performed. 2, 6... Capstan, 20, 24... Head board, 21, 25... Head, 28... Drive rod, 33... Right-reverse lever, 45... Winding lever, 48... Winding gear lever, 56 ...Switching means, 58, 63...Fast forward lever, 61, 66...
...Rapid gear, 79...Power pulley, 79a...
... Drive gear, 80, 88 ... Lock lever, 82
... Regeneration solenoid, 86 ... Drive pulley, 86
d, 86e... Toothless portion, 86f, 86g... Locking portion, 89... Rapid feed solenoid, 90... Switching rod, 92... Switching solenoid.

Claims (1)

[Claims] 1. High-speed running in which the high-speed feed gear, which has been separated from the reel stand by a spring member, is meshed with the reel stand by releasing the spring force of the spring member, thereby rotating the reel stand at high speed and causing the magnetic tape to run at high speed. a first position corresponding to a stop mode in which the magnetic head is far away from the magnetic tape and a second position corresponding to a reproduction mode in which the magnetic head is brought into pressure contact with the magnetic tape; A constant speed running means includes a head member always applied with a spring biasing force in the direction of the first position, and a constant speed running means rotates the reel stand at a low speed to run the magnetic tape at a constant speed, and the high speed running means is connected to the spring member. an actuating member that is actuated from a non-actuating position to an actuating position against a spring force; an internal cam part that controls the actuating member from the non-actuating position to the actuating position; and an external cam part controlling the actuating member from the actuating position to the non-actuating position. an operating gear having a first tooth-missing portion corresponding to the non-operating position of the operating member and a second tooth-missing portion corresponding to the operating position of the operating member; a drive gear that meshes with the operating gear and is rotated by a motor; A holding member that maintains a state in which the first and second tooth-missing portions of the working gear face the driving gear so that the working gear and the driving gear are not meshed, and this holding member is used as a first locking member of the working gear. The first
the holding member from a state in which the first toothless portion of the operating gear faces the driving gear; When the drive member moves the drive member to the second position, the first locking portion is unlocked and the actuation gear is engaged with the drive gear, and the actuation gear is moved to the second toothed portion by the drive gear. are operated until they are opposed and locked by the second locking part, and the actuating member that operates the high-speed traveling means is controlled by the internal cam part by the operation of the operating gear to perform high-speed tape traveling operation. get the state,
When the holding member is actuated to the first position by the driving member from this high-speed traveling operating state, the locking of the second locking portion is released, and at the same time, the above-mentioned high-speed traveling means is urged to the non-operating position. A high-speed operating means for instantly releasing the high-speed traveling means by releasing the operating member from the internal cam portion by a biasing force of a spring member, and an engagement capable of engaging the high-speed operating means with the above-mentioned operating member. a swingable movable member having a mating portion, when the actuating member is in a non-actuating position, the engaging portion rotates about the engaging portion with the actuating member to move the head of the constant speed traveling means; Although the member is advanced from the first position to the second position against the biasing force of the spring, when the actuating member shifts to the actuating position, the engagement of the engaging portion is released and the head member is moved. a constant speed actuating means associated with the high speed actuating means so as to cause the actuator to retreat to the first and second intermediate positions by the spring biasing force; When the holding member is actuated to the second position by the driving member from a state in which the magnetic head is brought into deep contact with the magnetic tape by the constant-speed actuating means and the magnetic tape is run at a constant speed, with the two parts facing each other, The first locking portion is released and the actuating member is controlled by the internal cam portion, and the magnetic head is moved back to make shallow contact with the magnetic tape, and the constant speed running operation is canceled, and the actuating gear is The actuating gear is engaged with a driving gear and is operated until the second toothless portion of the operating gear is opposed to the driving gear and is locked by the second locking portion, and the internal cam portion engages the high speed traveling means. When the operating member to be operated is controlled to perform a tape position detection operation in a high-speed traveling operation, and the holding member is operated to the first position by the drive member from this tape position detection operation state, the second At the same time as the locking of the locking part is released, the actuating member is released from the internal cam part by the biasing force of the spring member, and the high-speed traveling operation is instantly released, and the actuating gear meshes with the drive gear. is operated by the driving gear until the first tooth-missing portion faces the driving gear and is locked by the first locking portion, and the circumferential cam portion controls the operating member and magnetizes it again. 1. A tape recorder characterized in that the head is brought into deep contact with the magnetic tape to cause the magnetic tape to run at a constant speed.