FR2534725A1 - Automatic cassette ejection for tape recorder - Google Patents

Abstract

When the cassette is inserted into the swivelling frame of the tape recorder through a cassette guide it compresses a spring which is linked to a rocking lever with a cam guide edge. An ejection element linked to a lever which forms part of the ejection mechanism is connected with the cassette guide and the swivelling frame. The latter is formed so that part engages with the cam guide edge of the rocking lever. The ejection mechanism is brought into engagement with an actuating element linked to a reversing element which has a cam following organ in contact with a cam guide piece arranged on a contact breaker wheel. The latter has an interrupt section which, as time elapses, engages with the instrument's motor driven wheel.

Description

 The present invention relates to a new self-ejecting mechanism for a tape recorder, which mechanism makes it possible to perform an automatic ejection operation always regularly, in a tape recorder, in an appropriate time.

 For a tape recorder, operations such as an eject operation at the end of the tape and so on, are inevitable when in use, and nowadays, a self-eject mechanism is increasingly more widely used, in which such an ejection operation is carried out automatically by using the rotational force of a motor.

 Indeed, instead of a manual operation usually carried out until now by means of a finger, a slight operation such as the touch of a feather makes it possible to carry out such a switching operation.

As a result, significant merit can be obtained, which facilitates the use of the tape recorder.

 However, in this type of tape recorder where the ejection operation takes place automatically, the switch arranged in the motor drive circuit tends to open before the ejection operation ends. and to stop the drive mechanism, and it is difficult to obtain a good delay when the engine switch is open. In the event that the ejection does not occur in time, in particular if the ejection operation is stopped in progress, the ejection operation must be terminated either by removing the cassette by hand or by pushing the eject button after pushing the cassette in the opposite direction until the bottom is established, the mode of restitution. As these operations must be carried out in a narrow region from which the cassette is loaded, they are very difficult and tedious , and remarkably reduce the merit of the self-ejecting mechanism, which must above all be advantageous for the use of tape recorders.

 The present invention relates to a self-ejection mechanism for a tape recorder making it possible to eliminate the above-mentioned drawbacks of the mechanism according to the prior art.

 In order to achieve this objective, a self-ejection mechanism for a tape recorder according to the invention comprises a motor; a driving gear driven by said motor; an intermediate pinion having an intermediate part arranged to engage said driving pinion; a cam portion disposed on said intermediate gear, a switching element having a roller which is in contact with said cam portion; an operating rod integral with said switching element; an ejection rod arranged so as to be able to engage said operating rod; an ejection lever connected to said ejection rod; an ejection element integral with said ejection lever; a cassette guide; a pivoting frame receiving a cassette inserted by the guide; an oscillating lever having a cam edge at its end and pivotally mounted, said ejection element being connected to said guide of the cassette and to said pivoting frame, where a part engaging said cam edge is formed; and a # spring connected to said oscillating lever , said res # comes out storing the ejection energy when the cassette is inserted.

The invention will be better understood, and other objects, characteristics, details and advantages thereof will appear more clearly during the explanatory description which follows, made with reference to the appended schematic drawings given solely by way of example illustrating a embodiment of the invention and in which
- Figure 1 is a plan view showing the general arrangement of various elements arranged in the frame, where the head plate has been advanced;
- Figure 2 is a plan view showing the arrangement of the swing lever, the cassette guide and so on the chassis;
- Figure 3 is a plan view showing the position of the switching element, of the plate. lock, lock arm and ejector lever #, when the head plate has been advanced and the operating rod has been turned;
- Figure 4 is a plan view which corresponds to that shown in Figure 3, but which shows the arrangement when the head plate has been pulled back;
- Figure 5 is a plan view showing the arrangement of the same elements, where the operating rod has been further rotated;
- Figure 6 is a plan view showing the arrangement of the same elements when a cassette has been inserted into the guide;
- Figure 7 is a side view showing the movement of the elements moved by the operation of the auto-ejection switch;
- Figure 8 is a plan view showing the arrangement of the main elements, where-the head plate has been pulled back;
- Figure 9 is a plan view showing the return mode, where the motor switch has been closed by the cam portion by the switching element;
- Figure 10 is a cross-sectional view of the mechanism of Figure 9;
- Figure 11 is a plan view showing the ejection mode; and
FIG. 12 is a cross-sectional view of the mechanism of FIG. 11.

Figure 1 shows the general layout of a tape recorder. As is well known, two capstans 51 are arranged on the chassis 50. A pinion 52, which is arranged coaxially with respect to one of these capstans 51, is placed so that it is also coaxial with the one of the flywheels 82 driven by a belt 81, which, in turn, is driven at its other end by a pulley 83 of a motor 80. The pinion 52 engages an intermediate portion formed on a part of the periphery # of a intermediate gear 10
When the pinion 52 is in the intermediate part 1a as indicated in FIG. 1, the engagement is intercepted between the pinion 52 and the intermediate pinion 1.

In addition, a cam portion 2 is formed in one piece on an intermediate pinion 1 and a staggered portion 2a and a thrust portion 2b are arranged on the switching part of the peripheral cam. Another switching part 5 engages by slots Sa in the longitudinal direction, ~ guide pins 58 arranged on the frame 50 so that the switching operations can be carried out to the right and to the left.

Furthermore, a roller 4 disposed in the switching part 5 is pushed by a spring 15 located between the switching part 5 and the frame 50 and it follows the cam part 2 above mentioned.

 The intermediate pinion 1 described above has an engagement part 1b close to the intermediate part 1a mentioned above. The end part 62b of a stop element 62 is placed against the engaging part lb. This stop element 62 is pivotally supported by one of the guide pins 58 mentioned above and its base part is linked to a core 63b of a piston 63. Furthermore, a spring 64 is mounted between the frame 50 and the stop element 62 and when the piston 63 is not energized, its end part 62b comes into the region of rotation of the engagement part lb in the pivoting intermediate pinion I and stops the pivoting movement - in a predetermined position. Thus, a state is established where the engagement after the pinion 52 and the intermediate pinion I is intercepted, as shown in FIG. 1. When the piston 63 is excited, the stopping relation between the engagement part 1b and the end part 62b is released. Thus, the head plate 10 comes into engagement with pins 67 in the guide slots 68 on the chassis 50 and can slide up and down in the figure over a limit determined by the length of stroke offered by the slots 68. On the head plate 10 is disposed a head 19, a pressure roller (not shown) which is pushed against the capstan 51 and so on, and a spring 20 disposed between the frame 50 and the head plate 10 excites the head plate 10 so that the head 19 is normally removed in the released position. A rectangular engagement hole 21 is formed on one side of the head plate 10 and the pivot point 23 formed in the central part of a control piece. 22 is inserted into this engagement hole 21 so that the control panel can move up and down in the figure. The control piece 22 has a tapered portion 24 at one of its ends and another tapered portion 25 and a stop step 26 at the other end.

Furthermore, an excitation spring 27 is mounted on the pivot point 23 and since the tension force of the excitation spring 27 is greater than that of the above-mentioned spring 20, the pivot point 23 of the workpiece control 22 touches the upper end of the engagement hole 21.

 A sector member 28 is mounted on the chassis 50 near the motor 80 using a pivot 29. An engagement part 30 formed with one side of the free end engages the fork-shaped part 5b of the switching 5 mentioned above, and the sector member 28 pivots around the pivot 29 by sliding action of the switching part 5. On the other side of the free end is mounted an engagement protuberance 31 which is placed so as to be able to engage the tapered part 24 of the control part 22 described above and to disengage it Another engagement protrusion 34 formed in the central part of the blocking part 32, which is mounted on the chassis 50 at a pivot point 33, is placed against the stop step 26 of the tapered portion 25 of the control piece 22. An engagement portion 35 is formed from a cat of said blocking piece 32, and by elsewhere, an additional engagement part 37, which engages the engagement part 35, is available. placed at the end of a holding member 36 formed so as to be able to slide at the bottom of the chassis 50.

Furthermore, a spring 38 is disposed between the engagement part 35 and the frame, and provides a force, to the holding member 36 to the right in the figure.

An attracted part 39 is mounted on the base part of the retaining member 36 and a retaining piston 40 is placed on this attracted part 39. In addition, a spring 41 is placed on this retaining member and it excites the part drawn 39 in the direction of action of the piston 40.

Furthermore, the tensile force of the above-mentioned spring is greater than that of the spring 41. Consequently, as indicated in FIG. 1, the spring 38 maintains the locked state, to which the attracted part 39 is attracted by the piston 40 and the engagement protrusion 34 of the locking piece 32 engages the tapered portion 25, preventing an upward movement, in the figure, of the control piece 22. When the piston 40 is deactivated, the state blocked is removed by rotation of the blocking piece 3-2 anticlockwise against the tensile force of the spring 41.

A stop 42 is mounted on the frame 50 and it limits the pivoting movement of the control piece 22 in the clockwise direction. Furthermore, a limitation portion 69 limits the pivoting movement of the control piece 22 in the counterclockwise direction, preventing a release of the stop step 26 and the engagement protrusion 34 of the locking piece 32 becomes difficult because the tapered portion 24 continues to rotate counterclockwise, following the locking piece 32 also after releasing the tapered portion 24 and the engagement protrusion 31 of the organ in sector 28
According to the invention, in addition to the construction mentioned above, another rod part 5c is formed on the other side of the switching part 5, which rod part 5c is linked to the engagement part 6c of the operating rod 6. Indeed, the rod. 6 is mounted on the lower surface of the frame 50 using a pivot 6a and a connecting element 6b in the form of a roller is placed against the connecting part 7a in the form of a step of the ejection rod 7, while the ejection rod 7 is connected by a connection rod 7b to the ejection lever 9. Furthermore, a locking arm 8 having a connection element 8b at its end is mounted on the frame 50 using a pivot 8a, and the end of the blocking arm 8 is linked to one of the ends of a blocking plate 12 by its connection element 8b. At the central part of the blocking plate 12 is formed a stop part and at the same time, a connection element 13 is mounted at the other end. The connection element 13 engages in an L-shaped blocking hole 14 which is formed in the frame 50 and furthermore the base part of a spring It is fixed to the head plate 10 at the location of the blocking part 12a of the plate blocking 12 and its free end is mounted on the axial part # l0a, which spring serves as an elastic switching element. At one end of the above-mentioned ejection lever 9 is formed the ejection operating part 9a and at the other end is arranged an extension part 9b. This extension part is partially superimposed on half of a manual ejection lever 16 disposed separately A stop part 16b formed at one end of the manual ejection lever 16- engages a connection part 9c which is a recess formed in the ejection lever 9, and when the manual lever ejection 16 is pushed, the ejection lever 9 operates at the same time. When the ejection lever 9 operates as will be explained below, the manual ejection lever 16 is kept in the non-active state. A return spring 20 is mounted on each of the ejection levers 9 and 16. An ejection operation part 16a is formed at the other end of the manual ejection lever against the operating part 9a and a part of 16c push button operation is located in the central part of the chassies 50.

 As can be seen in FIG. 2, support plates 53 and 54 are mounted respectively on the two sides of the casing 50. At the lower part of each of these support plates 53 and 54 is pivotally mounted an oscillating lever 43 and at the upper part is arranged a pivoting frame 44 for guiding the cassettes using a pivot 44a. A connection part 44b formed to be bent inwards as indicated in FIGS. 6 and 7 on the lower side of the pivoting frame 44 for guiding the cassettes, is placed against a cam edge 143 which is formed at the free end of the oscillating lever described above, as indicated in FIGS. 5 and 6. A stop part 143a is formed at the bottom of the cam edge. Furthermore, a working part 143b is formed in a position which is even higher than that of the stop part 143a, as indicated in FIG. 6 in order to pass through the direction of insertion of a cassette 60 which is inserted into a guide 46 of the cassette in the ejection state.

 A spring 55 is disposed between the central part, which is closest to the base part of the oscillating lever 43, and the chassis 50. The spring 55 is in its contracted state, of which the spring is the shortest in the state ejection as shown in Figure 6, and starting from this state, it stores energy, extending gradually, when the cassette 60 is inserted either by hand or automatically. Finally, it has the greatest tensile force in the restitution state indicated in FIG. 7.

This state is localized by stopping the connection part 44b of the pivoting frame 44 for guiding the cassette to the locking position 143c, which is located on the side of the base of the cam edge 143.

 In addition to the pivoting frame 44 for guiding the cassettes and the oscillating lever 43s which have been described previously, an end part of a pivoting support means 45 is pivotally mounted at 45a, being at the bottom of the element. pivoting 44a. At the other end of the pivoting support means 45, a connection part 46a formed at the lowest part of the bottom of the cassette guide 46 is connected to a pivoting element 45b and a spring 56 is mounted between the base part of the means pivoting support 45 and the frame 50. A connection element 46b is formed on the region where the pivoting element 45b of the guide 46 of the cassette is arranged.

The connection element 46b is pivotally connected to the end of the pivoting frame 44 for guiding the cassette and at the same time it engages a hollow part 48b which is formed in the ejection member 48, the part of which base is mounted by a pivoting element 48 on each of the support plates 53, 54. An engagement protrusion 48c disposed under the base part of the ejection member 48 is placed either against the operating part 9a of the lever d ejection 9 described above or the ejection operation part of the manual ejection lever 16
The guide 46 of the cassette has an opening 46a in the upper front part of the frame 50 and a support member 46b receiving the lower surface of a cassette is formed on each side of the guide 46 of the cassette to receive the cassette 60, as the figure shows.

At the central upper part of such a guide 46 of the cassette is disposed an elastic piece 42 which presses down the upper surface of the inserted cassette, as shown in FIG. 2. The free end of this elastic piece 42 presses resiliently the cassette down, and thus maintains the state for a stable load of the cassette. At the bottom of the support plates 53, 54 is arranged a nose-up board 49, as shown in FIGS. 2, 6 and 7 A motor switch 47 is mounted under said wiring board 49. The contact part 47a of the motor switch 47 extends towards the pivoting base part of the pivoting frame 44 for guiding the cassettes, as shown in FIGS. 6 and 7.

The guide 46 throws the cassette 60 downwards on the chassis, and when the oscillating lever is rotated around the pivot 43a, the active part 1430 of the oscillating lever 43 comes into contact with the contact part 47a and presses it so to close the switches 47.

 The mode of operation of the mechanism described above will be explained below, in more detail.

As is well known, a power switch disposed in the region where the tape cassette is inserted, is switched on by the insertion of the cassette 60. Then, the piston 63 is excited and moves the stop member 62 and the engagement of the engagement portion 1b with the end portion 62b is eliminated. By this fact, the cam part 2 and the intermediate pinion 1 are rotated by the spring which acts on the switching element 5 of the roller 4 engaging the stepped part 2a of the cam part 2 and the intermediate pinion 1 comes in engagement with the pinion 52 which is driven by the motor. Thus, as said cam part 2 rotates automatically, the switching element 5 having the roller 4 slides along the thrust part 2b of the cam part 2. The sector member 28 is rotated by the fact that the the switching element 5 slides to the left in the figure, and moves the connection element 31 from the lower part of the tapered part 24, where the element is placed until this moment, to its upper part. The arrangement thus obtained of the various members and elements is that shown in FIG. 1. By this fact, the control piece 22 can rotate clockwise, and the locking member 32 and the member holding 36 are moved to the right in the figure by the tensile force of the spring 41 As a result, they are attracted and held by the excited holding piston 40. In addition, the roller 4, which once reached the bottom of the cam part 2, slides the switching element 5 to the right in FIG. 1 in the opposite direction by further rotation of the cam part 2. In this way, the connection element 31 of the member in sector 28 is moved down in the figure and the tapered part 24 of the control part 22 is pressed down Then the pin 67 of the head plate 10 pushes and advances, downwards, in the figure, the head plate 10 of the state in which the pin 67 is in contact with the lower end e from slot 68 to the state where it is at its upper end. Consequently, the head plate presses the head 19 and so on against the strip and the state of restitution indicated in FIG. 3 is established.

Furthermore, the connection element 34 of the blocking member 3 2 is pushed towards the tapered portion 25 and the blocking member rotates against the tensile force of the spring 38 in the counterclockwise direction. Even after the head plate 10 has reached the position for the return mode, as described above, until the roller reaches the highest position of the cam part, the control part 22 continues to be pushed down and the pivot point 23 moves downwards in the rectangular hole 21 against the tensile force of the spring 27.

The connection element 34 of the blocking member 32 leaves, upwards, the tapered part 25 and engages the stop step 26 by the tensile force of the spring 38 as indicated in the figure. When the roller 4 continues to advance from this state and passes through the highest point of the cam part 2, the pinion 52 emerges from the intermediate part 1a of the intermediate pinion 10
In the condition where the piston is not excited, the rotation of the intermediate pinion I is stopped by the end part 62b of the stop element 62, which has been brought back by the spring 64 to the stop position in a position which is exactly against the pinion 52.

Furthermore, the switching element 5 is excited by the tensile force towards the left in the figure, and the roller 4 engages the stepped part 2a at the same time, the sector member 28 receives a rotational force in the direction clockwise. The control part 22, which is free from the pushing force due to the connection element 31 of the sector member 28, is moved upwards in the figure by the pulling force of the spring 27, until that the tapered portion 25 comes into contact with the connection element 34 of the locking member 32 and thus the state which is maintained by the holding force of the holding piston 40- and the tensile force of the spring 38 is carried out by the process described above and indicated in FIG. 1.

 During the load stroke of the cassette 60 described above, the mechanism according to the invention provides an ejection force to the spring 55 mentioned above.

In fact, when the cassette 60 is inserted either by hand or automatically from the ejection state indicated in FIG. 6, the passive part 1430 of the oscillating lever 43 is pushed and said oscillating lever 43 pivots around the pivot 430 and the spring 55 expands and stores # energy as described above. The connection part 44b of the pivoting frame 44 for guiding the cassette leaves the engagement part 143a and then it slides along the arc edge 143 in the shape of an arc.

During this sliding stroke along the cam edge 143, the pivoting frame 44 for guiding the cassette is maintained approximately in the state indicated in FIG. 6 and cannot pivot. However, when the cassette 60 is sufficiently inserted, the spring 55 stores enough energy. Thus, when the part 44b reaches the end of the cam edge 143, the end part of the pivoting support frame 44 is turned by the action of the spring 56 anticlockwise and rotates the pivoting support frame 44 anticlockwise through the guide of the cassette linked by the pivot 45b Thus , the state indicated in FIG. 7 is established where the engagement part 44b is blocked in the blocking part 143c.
In the state of restitution indicated in FIG. 1, which has been described above, when the piston 63 is still advanced, the intermediate pinion 1 is rotated in the direction indicated by the arrow A? as just explained. Consequently, provided that the roller 4 is pushed in the direction indicated by the arrow B, the connection element 66 of the operating rod 6 is turned in the direction indicated by the arrow C through the switching element 5; and the other side of the ejection rod 7 is pressed by the connection element 8b of the locking arm 8, said ejection rod 7 is pushed and the connection element 66 reaches the position shown by a supposed line in figure 1.

In this way, the ejection lever 9 advances as indicated by the arrow D in FIGS. 1 and 3 and a self-ejection action for winding and extracting the strip using the operating part 9a of the self-ejection lever 9 is carried out, as will be explained below. In this case, the manual eject lever 16 is not used.

 Figure 8 shows the action of various parts in the case where the manual ejection lever is pushed.

The ejection mechanism is controlled by the operating parts 16a and 9a when the ejection lever 9 is pushed by the connection part 16b. When an ejection operation has been completed, the two ejection levers 9 and 16 are brought back by the action of the springs 20.

 Below we will explain the action of the switching mechanism. As described above, it is in the state where the head plate is advanced that the self-ejection action takes place. In this state, the connection element 8b disposed on the blocking arm 8, which is integral with the blocking plate 12, is fixed in the position indicated in FIGS. 3 and 4 by the fact that the blocking plate 12 is rotated clockwise by the action of the switching spring II on its connection part 12a, which spring is arranged on the head plate 10 and the connection element 6b is locked in the part curved blocking the blocking hole 14 so the blocking plate 12 is blocked, and this allows to drive the ejection rod 7 in the direction indicated by the arrow in Figure 3 through the connection element 6b by rotation of the operating rod 9.

On the contrary, when the head plate 10 is pulled backwards, it returns in the direction of the arrow H as indicated in FIG. 4 and the spring Il mounted on said head plate 10 stops pushing the part of connection 12a of the locking plate 12.

Thus, the locking arm 8 is rotated in the direction of the arrow G by the spring 18 mounted on the region of the pivot 8a of the locking arm and the locking plate 12 rotates in the direction of the arrow I. Consequently, the connection element 13 is released from the blocking part of the blocking hole 14 and as indicated in FIG. 5, the operating rod 6 rotates clockwise. When the connection element 6b pushes the ejection rod 7, the locking arm 8 rotates clockwise and the ejection rod 7 does not perform an ejection action.

As the ejection lever 9 linked to this is also not actuated, no ejection action takes place.

In the self-ejection described above, as indicated in FIG. 7, by the fact that, from the state where the cassette 60 is rejected on the chassis 50, the operating part 9a of the lever d ejection 9 is moved by the motor drive in the direction of arrow K, the ejection member 43 rotates in the direction of arrow L and the cassette 60 is raised at the same time as the guide 46 in the direction arrow M. At the same time, the pivoting support frame 44 rotates in the direction of arrow N and releases the switching part 44b from the locked state in the blocking part 143c of the cam edge 143
The oscillating lever 43 rotates counterclockwise by the action of the spring 55, which has stored energy during the charging action, as explained above. working part 143b of the oscillating lever 43 pushes the front end in the loading direction of the cassette 60 and ejects the cassette 60 in the direction of the arrow P At the start of the ejection action, when the working part l43b turns a little in the direction of the arrow the pressing force due to the working part 1430 on the contact part 47a of the motor switch is suppressed
Furthermore, since the blocking action between the blocking part 143c and the connection part 44b is also eliminated by rotation of the pivoting support frame 44 described above in the direction of the arrow N, an appropriate ejection action is carried out by the energy stored in the spring 55 after disconnection of the current supply of the motor 80, which is caused by the suppression of the pressure force acting on the contact part 47a of the switch, as is described above.

 In the construction shown in Figures 6 and 7, during the load of the cassette 60, the spring 55 disposed on the oscillating lever 43 stores energy for the ejection force Indeed, it is clear that when the cassette 60 is inserted either by hand or automatically, from # the ejection state indicated in FIG. 6, the passive part 1430 of the oscillating lever 43 is pushed and said oscillating lever 43 pivots around the pivot 43b and the spring 55 expands and stores energy. The connection part 44b of the pivoting frame 44 for guiding the cassettes leaves the engagement part 143a then slides along the arc edge 143 in the form of an arc. During this sliding stroke along the cam edge 143, the pivoting frame 44 is maintained approximately in the state indicated in FIG. 6 and cannot pivot. However, when the cassette 60 is sufficiently inserted, the spring 55 stores enough energy Thus, when the engagement part 44b reaches the end of the cam rim 143, the end part of the pivoting support frame 44 is turned by the action of the spring 56 anticlockwise and rotates the pivoting frame 44 anti-clockwise via the guide of the cassette linked by the pivot 45b Thus, the state indicated in FIG. 10 is established, where the engagement part 44b is blocked in the blocking part 143c.

 In the construction and the condition of use described above, it is clear that when switching element 5 is slid to the right from the state shown in Figure 1, to that shown in Figure 3, the operating part 78 is pushed by the cam part 74 as shown in FIG. 9, and the switch 79 of the motor is closed.

When the switching element 5 is brought back as indicated in FIGS. 11 and 12, the cam element 70 rotates in the opposite direction and the switch 79 is open. By appropriately choosing the active region of the working portion 78 of the cam portion 72 in the cam member 70, it is possible to appropriately obtain the operating delay of the switch 79. it is also possible to perform a preferable ejection action, advantageously using the energy stored in the spring 55 mounted on the ejection mechanism during the load stroke of the cassette, as indicated in Figures 6 and 7, after a stop shown in figure II.

 As explained above, according to the invention, with respect to the self-ejection mechanism in such a kind of tape recorders, a spring mounted on the oscillating lever stores energy for the force of ejection during the load stroke of a cassette.

 For an eject action, the motor switch is opened by blocking the swing lever in this state with the pivoting guide frame of the cassette and removing the locked state and starting to rotate the swing lever. When the engine switch has been opened, it is possible to perform a regular ejection using the spring thus excited, as indicated above. Consequently, it is perfectly impossible for the ejection operation to be stopped in progress. it is also possible to perform the ejection action appropriately either by a simple automatic operation using an intermediate pinion driven intermittently by a motor or by hand.

Claims (4)

 said spring storing the energy of ejection by insertion of the cassette.  a spring (55) connected to said oscillating lever;  an oscillating lever (43) having a cam edge (143) at its end and pivotally mounted, said ejection element being connected to said guide of the cassette and to said pivoting frame, where a part engaging said cam edge is formed; and  a pivoting frame (44) receiving a cassette (60) inserted by said guide;  a cassette guide (46) ;;  an ejection element (48) integral with said ejection lever;  an ejection lever (9) connected to said ejection rod;  an ejection rod (7) arranged so as to be able to engage said operating rod;  an operating rod (6) integral with said switching element;  a switching element (5) having a roller (4) in contact with said cam portion;  a cam portion (2) disposed on said intermediate gear;  an intermediate pinion (1) having an intermediate part (la) arranged so as to engage said driving pinion;  a driving gear (52) driven by said motor;  a motor (80);  1. Self-ejection mechanism for a tape recorder, characterized in that it comprises  2.- Mechanism according to claim 1, characterized in that a manual ejection lever (16) is also arranged, which lever is removably mounted on the aforementioned ejection lever.  3.- Mechanism according to claim 1, characterized in that a locking arm (8) pivotally mounted and a locking plate (12) connected to said arm are also arranged, said arm being formed so as to be able to engage the rod d ejection above.  4. A mechanism according to claim I, characterized in that it further comprises a cam operating part formed in the switching element, a cam element (70) pivoted by said operating part and a switch (79 ) controlled by said cam element to open and close the motor drive circuit.