DE69400926T2 - Preservation device with a safety function - Google Patents

Description

This invention relates to a storage device of the so-called push-on type to be installed in the instrument panel of a motor vehicle, and more particularly to a storage device with a safety function according to the preamble of claim 1 or 2. Such a storage device is disclosed, for example, in US-A-5,052,728.

In general, conventional slide-on type storage devices of this type comprise a storage case which is openably supported in a housing provided on the side of the instrument panels of an automobile and is constantly biased in the opening direction thereof by the biasing force of a spring, a cam member provided with a cam recess therein having a guide inlet, a locking member and a guide outlet and which is rotatably arranged on the side of the housing, and a bolt member adapted to move within the cam recess of the cam member and arranged on the side of the storage case, whereby the storage case can be locked in its closing position within the housing against the biasing force of the spring by causing the bolt member to be engaged with the locking member of the cam recess by the storage case is caused to be pushed further into the housing, whereby the bolt member can be released from engagement with the locking part of the cam recess and the storage case can thus be automatically moved in the opening direction thereof through the opening of the housing.

A typical form of the conventional storage devices is shown in Figs. 1 and 2, wherein a cam element 21, the is an integrally molded article made of plastic, is rotatably mounted on a rotation shaft 27 on the side of a case (not shown) by a torsion spring 28, and is constantly biased by the biasing force of the torsion spring 28 in the direction of an adjusting wall 29 until it comes under the control of the adjusting wall part 29. In the specific construction of this cam member 21, a locking part 24 and a guide outlet 25 are formed in extreme proximity to each other on one edge surface of the cam member 21 defining a cam recess 22, and meanwhile, a guide wall 26 adapted to guide a bolt member on the side of a storage case (not shown) is formed to project from the other edge surface opposite to the aforementioned one edge surface.

Since the cam member 21 is designed for the sole purpose of guiding the bolt member exclusively in the direction of the guide outlet 25 by the action of an inner edge 26a of the guide wall 26, the guide end of the guide wall 26 is formed to protrude from the closure member 24 namely in a compressed state in the direction of a guide inlet 23 of the cam recess 22 and the closure member 24 serves to engage the bolt member at the location positioned within the guide end of the guide wall 26.

Therefore, when the storage case is pushed into the housing, the bolt member 26 disposed at the rear end of the storage case collides with an outer peripheral guide surface 21a of the cam member 21 and possibly reaches the guide inlet 23 of the cam recess 22 when the cam member 21 is rotated in the direction opposite to the direction in which this cam member 21 is biased by the torsion spring 28. At the same time, when the bolt member 26 collides with the outer edge of the guide wall 26, the cam member 21 is rotated to a certain extent in the direction in which the cam member 21 is biased by the torsion spring 28. is rotated. As a result, the bolt member p is guided into the cam recess 22. At this time, since the storage case is retracted by the biasing force of the spring 28, the bolt member itself automatically engages with the locking member 24 positioned within the cam recess 22 as shown in Fig. 1, causing the storage case to be infallibly locked in the housing against the biasing force of the spring 28 at the closing position.

When the storage case is further pushed into the housing in the closed position, the bolt member separates from the locking part 24 of the cam recess 22 as shown in Fig. 2, collides with an inner edge 26a of the guide wall 26, and allows the cam member 21 to continue to rotate in the biasing direction (the non-locking direction). When the force for pushing the storage case thus ends, the bolt member is automatically separated from the cam recess 22 of the cam member 21 because it is continuously guided in the direction of the guide outlet 25 of the cam recess 22. As a result, the storage case is enabled to automatically move from the opening of the housing in the opening direction by the biasing force of the spring.

When a large inertia force generated by a motor vehicle having the storage device due to occurrence of a collision or sudden braking to avoid an accident is applied to the storage case which is locked in its closed position by the cooperation of the bolt member with the locking part 24, the storage case moves in the direction in which the inertia force is applied. At this time, the bolt member P synchronously separates from the inside-arranged locking part 24 in the same manner as during the opening operation shown in Fig. 2, allowing the cam member 21 to move into the non-locking position. Therefore, there is a possibility that the storage case may be inadvertently moved from the opening of the case automatically in the opening direction by the biasing force of the spring, thus causing harm to the operator or passenger of the motor vehicle.

In order to exclude the occurrence of such an erroneous situation, the present inventor has therefore already proposed a storage device equipped with a safety function in EP-A-0 561 113. However, this document was not published before the priority date of the present application and therefore consequently falls under Article 54(3) EPC.

In addition to the basic construction of the conventional device described above as a basic premise, the proposed storage device has a construction as shown in Fig. 3(A), in which a locking part 34 and a guide outlet 35 are formed to be separated by a significant distance at a first edge surface defining a cam recess 32 of a cam member 31, a holding guide wall 36 is formed to protrude between the locking part 34 and the guide outlet 35 at the other edge surface opposite to the aforementioned first edge surface, and the locking part 34 performing the function of engaging the bolt member at the location is thus allowed to be positioned further out from the holding guide wall 36.

Therefore, in normal use of the proposed storage device constructed as described above, the bolt member 31 disposed on the side of the storage case collides with the outer peripheral guide surface 31a of the cam member 31 when the storage case is pressed into the housing, and eventually reaches a guide inlet 33, locks to the locking part 34 of the cam recess 32 and allows the storage case to be in its closing position within the case against the biasing force of the spring as shown in Fig. 3(A) in much the same manner as in a conventional storage device, while simultaneously rotating the cam member 31 in a direction opposite to the direction in which the cam member 31 is biased by the torsion spring 28. When the storage case held in the closed state is further pushed into the case, the bolt member separates from the locking part 34 of the cam recess 32 and allows the cam member 31 to be rotated in the non-closing direction as shown in Fig. 3B. As a result, the storage case is enabled to be automatically moved from the opening of the case in the opening direction by means of the biasing force of the spring.

When the proposed storage device having the storage case held in the locked state in its closed position is applied with a large inertia force generated when a motor vehicle carrying the proposed storage device encounters a collision or undergoes sudden braking to avoid an accident, the result is basically that the storage case moves together with the bolt member in the same direction as that of the inertia force. Since the locking member 34 which performs the function of locking the bolt member is positioned outside the holding guide wall 36 at this time, the bolt member collides with an outer edge 36a of the holding guide wall 36 as shown in Fig. 4, and is infallibly prevented from moving in the direction of the guide outlet 35 of the cam recess 32. As a result, the cam member 31 is no longer allowed to rotate in the non-closing direction thereof, and the storage case is retained in its closing position within the case. According to the safety function, the storage case can from being inadvertently automatically moved out of the opening of the case in the opening direction thereof by the biasing force of the spring. The proposed storage device has an advantage in providing general simplification and miniaturization of the device as a whole, since the slight modification provided by the cam member 31 can easily contribute a safety function to a slide-on type storage device. However, it has been found by the present inventor that further enhancement of the safety function brings about further improvements in the following points.

When the safety function is proved, the construction of the proposed storage device described above is sufficient to cope with the inertia force of a normally predictable magnitude. When an inertia force G1 of an unimaginably large magnitude or an inertia force G2 in an oblique direction acts on the storage device as shown in Fig. 5, for example, there arises a possibility that the cam member 31 overruns to a large extent in the direction opposite to the biasing direction of the torsion spring 28 (the direction indicated by the solid arrow in Fig. 5) and the bolt member separates from the guide inlet 33 of the cam recess 32, since the center of gravity of the cam member 31 on the guide end exists according to the overall construction of the storage device.

When the storage case is locked in its closed position within the case, it is understood that the bolt member on the side of the storage case should engage the locking part 34 of the cam recess 32, as already described. When the motor vehicle carrying the storage device collides with another vehicle thereon from behind or the motor vehicle collides with an obstacle when reversing, the resulting large Impulse the housing and the body of the motor vehicle forward and meanwhile causes the storage case openably supported within the housing to remain firmly in its own position, which is promoted by the biasing force of the spring. As a result, there occurs the same phenomenon of separation as is encountered when the housing and the storage case move away from each other.

Once this mutual separation phenomenon occurs, a very large load to be absorbed is applied particularly to the locking member 34 of the cam recess 32, performing the function of locking the bolt member at one place, and as a result, the locking member 34 or the adjacent member is completely broken possibly to an extent of destroying the serviceability of the storage device with the wall thickness of the locking member 34 as a contributing factor. Even if the locking member 34 escapes breaking by the impulse, the aforementioned load causes the bolt member to tilt slightly and inevitably enables the leading end of the cam member 31 to slide upward as indicated by an indicated line in Fig. 6. As a result, there is a possibility that the bolt member completely separates from the locking part 34 of the cam member 31 and the storage case inadvertently moves out of the opening of the case according to the biasing force of the spring in the same manner as described above.

Furthermore, US-A-5,052,728 discloses a locking device for holding a movable locked body, which includes a cam lever and an inertia holding device. The cam lever serves to lock the movable body in a locking position by pressing the movable body inwardly into the locking position against a biasing force, and to maintain the locked state of the movable body. body by further pushing the movable body inwardly, allowing the movable body to move to an opening position. The inertia holding device serves to prevent the cam lever from being released from the locked state of the movable body when the inertia force is generated to push the movable body inwardly from the locked state.

Finally, FR-A-2 579 181 discloses another locking device which is very similar to the previously discussed state of the art.

Therefore, an object of the present invention is to provide a storage device with a safety function and for use in a motor vehicle, which is capable of effectively excluding the occurrence of such undesirable phenomena as described above, i.e. preventing an uncontrolled rotation of the cam element against its bias direction due to a very large inertial force caused by a collision of a motor vehicle.

According to the present invention, there is provided a storage device with a safety function for use in a motor vehicle, comprising a storage case openably supported in a housing having an opening; a spring provided between the storage case and the housing for constantly biasing the storage case in an opening direction thereof; a cam member rotatably biased in one direction and arranged on the side of the housing, the cam member being provided on an outer side thereof with a guide surface and on an inner side thereof with a cam recess having a guide inlet, a closure member and a guide outlet; a bolt member arranged on the side of the storage case for movement along the guide surface of the cam member which fits into the guide inlet of the cam recess and engages with the closure part of the cam recess to close the storage case in a closing position thereof in the case against the biasing force of the spring when a first compressive force is applied to the storage case; wherein the bolt member moves in the cam recess to be released from engagement with the closure part of the cam recess and brought to the guide outlet of the cam recess, the storage case automatically moving in the opening direction thereof through the opening of the case, in which a second compressive force is applied to move the closed storage case further into the case; wherein the closure member and the guide outlet of the cam recess are separated from each other at a first edge surface of the cam recess, and the other edge surface of the cam recess opposite to the first edge surface is integrally provided with a projecting holding guide wall, the storage device being characterized in that the holding guide wall is arranged in a position between the closure member and the guide outlet of the cam recess such that the closure member of the cam recess is positioned outward from the holding guide wall of the cam recess; wherein the bolt member is capable of colliding with an outer edge of the holding guide wall of the cam member and preventing the storage case from being pushed out of the case when a large inertial force is exerted on the storage device; the storage device being further characterized in that either an adjusting wall in the housing is in a position which enables a limitation of the amount of rotation of the cam element when the cam element is rotating in a direction which is opposite to the direction in which the cam element is biased, hence opposite to the direction of release of the bolt element via the guide outlet, or that the cam element has a compensating adjusting part to cause the center of gravity of the cam element and the axis of rotation of the cam element to coincide with each other.

Furthermore, a preferred embodiment of the present invention is that the cam element is thicker at the closure part than at the remaining part of the cam element.

The above and other objects, features and advantages of this invention will become more apparent when the following detailed description thereof is considered with reference to the accompanying drawings, in which:

Fig. 1 is an explanatory view showing a conventional storage device held in a state with a bolt member locked to a locking part of a cam member;

Fig. 2 is an explanatory view showing the same storage device held in a state with the bolt member separated from the locking part of the cam member;

Fig. 3(A) is an explanatory view showing the storage device previously proposed by the present inventor and held in a state with a bolt member locked to a locking part of a cam member;

Fig. 3(B) is an explanatory view showing the same storage device held in a state with the bolt member separated from the locking part of the cam member;

Fig. 4 is an explanatory view showing the same storage device held in a state allowing an inertial force to act thereon;

Fig. 5 is an explanatory view showing the same storage device, held in a condition which results in overflow of the cam element;

Fig. 6 is an explanatory view showing the same storage device held in a state that keeps the cam member raised upward;

Fig. 7 is an exploded perspective view showing the essential part of a storage device according to the first embodiment of this invention;

Fig. 8 is an enlarged perspective view showing only the relationship of the cam member with the retaining wall;

Fig. 9 is an explanatory view showing a state in which an adjusting wall prevents the cam member from overrunning;

Fig. 10 is an explanatory view showing the cam member of a storage device according to the second embodiment of this invention;

Fig. 11 is an explanatory view showing a cam member which is thicker at the closure part than at the remaining part of the cam member, from the rear side;

Fig. 12 is a cross-sectional view of the essential part of a storage device held in a state with the bolt member locked to the locking part of the cam member shown in Fig. 11;

Fig. 13 is a cross-sectional view of the essential part of the same storage device, held in a state with the bolt member separated from the cam recess of the cam member;

Fig. 14(A) is a side view showing another example of a cam member which is thicker at the closure part than at the remaining part of the cam member; and

Fig. 14(B) is a side view showing still another example of a cam member which is thicker at the closure part than at the remaining part of the cam member.

Similar to the conventional push-on type storage devices described above, the storage device constituting the first embodiment of the present invention comprises, as a basic premise, a storage case which is openably supported in a housing disposed on the side of an instrument panel (not shown) and constantly biased in the opening direction thereof by a biasing force of a spring which will be described in detail hereinafter. A cam member 1 is rotatably disposed on the side of the housing and a bolt member is disposed at the rear end of the storage case B as shown in Fig. 7.

Thereby, the storage case can be locked in its closed position in the housing against the biasing force of the spring by causing the bolt member to be attached to the cam member 1, and the storage case can be automatically moved in the opening direction thereof from the opening of the housing by the biasing force of the spring by causing the storage case in the locked state to be pushed further into the housing. to be pressed in. The bolt element P is thereby released from engagement with the cam element 1 and the cam element 1 is allowed to rotate in the non-closing direction thereof.

The cam member 1 is an integrally formed article made of plastic. As shown in Figs. 7 to 9, a cam recess 2 is molded therein, which includes a guide inlet 3, a closure member 4 and a guide outlet 5 and is arranged at a location rotatable about a rotation axis 7 on the side of the housing. It has the closure member 4 and the guide outlet 5 separated by a significant distance on a first edge surface of the cam recess 2, and has a retaining guide wall 6 formed in the approximate shape of the inverted letter V on the other edge surface of the cam recess opposite to the aforementioned first edge surface and protruding between the closure member 4 and the guide outlet 5. The closure part 4, which fulfils the function of fastening the bolt element, is arranged outwards at a clear distance from the guide end of the retaining guide wall 6.

In this respect, therefore, this storage device allows the bolt member to move in the direction of the guide outlet 5 of the cam groove 2 by using the gap provided between the leading end of the holding guide wall 6 and the one edge of the cam groove 2 in the normal opening operation at the same time as the storage device previously proposed by the present inventor. The storage device allows the bolt member to collide with the outer edge surface 6a of the holding guide wall 6 when subjected to the action of an inertial force, and prevents the bolt member from moving in the direction of the guide outlet 5 of the cam groove 2.

In Fig. 7, reference numeral 10 designates a retaining wall for limiting the position in which the cam member 1 is biased by a torsion spring 8, numeral 11 a fixing wall adapted to fix the end of the torsion spring 8 in cooperation with an arm 1b of the cam member 1, and numeral 12 a constant pressure spring for constantly keeping the storage case under bias in the opening direction thereof. This constant pressure spring 12 is capable of acting as a means for biasing the storage case by winding the spring 12 around a winding mandrel 13 in the pulling direction thereof, fixing the winding mandrel 13 to the rear wall of the storage case by a retaining member 14, and fixing a free end 12a of the spring 12 to the bottom surface near the opening of the case by means of screws (not shown).

Besides the construction described above, the first embodiment, as shown in Fig. 8, further comprises an adjusting wall 15 adapted to limit the amount of rotation of the cam member 1 in a direction opposite to the biasing direction, namely, the amount of rotation in the direction of causing the bolt member to separate from the guide inlet 3 of the cam recess 2, and disposed on the side opposite to the retaining wall 10 which performs the function of limiting the position in which the cam member 1 is biased by the torsion spring 8. According to the presence of the adjusting wall 15 in the above-described position, even if an inertia force G1 of an unimaginably large magnitude or an inertia force G2 generated in an oblique direction as shown in Fig. 9, the storage device is able to limit the amount of rotation of the cam member 1 in the reverse direction to the smallest possible extent and to prevent the bolt member from completely separating from the guide inlet 3 of the cam recess 2.

The first embodiment is intended to provide a task of selecting the position in which the rotation amount of the cam member 1 must be limited. Since the cam member 1 must be rotated in a direction opposite to the biasing direction of the torsion spring 8 and the bolt member is guided in the cam recess 2 through the guide inlet 3 for the purpose of locking the storage case in its closed position, the guide end of an outer guide surface 1a of the cam member 1 defining the guide inlet 3 is not allowed to protrude outward (to the lower side in the bearings of Fig. 9) from the path L of movement of the bolt member 1.

For the purpose of limiting the amount of rotation of the cam member 1 by means of the adjusting wall 15, it is therefore necessary to have the adjusting wall 15 arranged on the side of the housing as shown in Fig. 7 so that the cam member 1 is allowed to rotate to the invariable minimum extent in the above-mentioned opposite direction, and as a result, the leading end of the outer guide surface 1a assumes the position of the path L closest to the path L on the inside (on the upper side in the bearings of Fig. 9) along which the bolt member is smoothly guided into the guide inlet 3 of the cam recess 2.

Therefore, in normal use of the storage device of the first embodiment, when the storage case is pressed into the housing against the biasing force of the constant pressure spring 12, the bolt member 12 automatically locks to the locking part 4 of the cam recess 2 positioned outside and causes the storage case 1 to be locked in its closed position in the housing 1 against the biasing force of the constant pressure spring 12 in the same manner as described above. When the storage case 12 is further pressed into the housing in the locked state, it can automatically move in the opening direction thereof from the opening of the housing by means of the biasing force of the constant pressure spring 12, since the bolt member 12 is allowed to move away from the cam recess 2. of the cam element 1 via the guide outlet 5.

When the inertia force G1 of an unpredictably large magnitude or the inertia force G2 generated in an oblique direction acts on the storage case in the locked state in the closing position thereof, the cam member 1 in the storage device of the first embodiment rotates in a direction opposite to the direction in which the torsion spring 8 biases the storage case. However, according to the presence of the adjusting wall 15, the cam member 1 no longer suffers from colliding with the adjusting wall 15 and generating an overrun, but is able to quickly rotate back to the biasing direction by means of the biasing force of the torsion spring 8 and unfailingly accommodate the bolt member which tends to retract by means of the biasing force of the constant pressure spring 12. As a result, the storage device can be expected to manifest the safety function with a greater certainty since the otherwise possible inadvertent separation of the bolt member from the guide inlet 3 of the cam recess 2 of the cam member 1 can be effectively prevented.

Now, the storage device of the second embodiment according to this invention will be described below. While the storage device of the second embodiment has been developed with the same object as the first embodiment, it differs from the storage device of the first embodiment in that, instead of the adjustment wall 15, a balance adjustment part 16 extends integrally from the back of the cam member 1 as shown in Fig. 10 so that the center of gravity of the cam member 1 coincides with the rotation axis 7 which is determined to serve as the rotation center.

Furthermore, the compensation adjustment part 16, which fulfils the function of adjusting the centre of gravity, As far as the mold weight is concerned, it is given a desired weight by appropriate selection of the shape, area, wall thickness, etc., as shown in Fig. 10. Alternatively, the object of providing this balance adjustment member 16 can be achieved by reducing the area and wall thickness of this member and providing this member with a separate mold weight.

Therefore, when the inertia force G1 of an unpredictably large magnitude or the inertia force G2 generated in an oblique direction acts on the storage device of the second embodiment, the otherwise possible overrun of the cam member 1 in the reverse direction can be prevented since the center of gravity of the cam member 1 falls on the rotation axis 7. Thus, the possibility of the cam member 1 being inadvertently separated from the guide inlet 3 of the cam recess 2 and the possibility of the storage container B being inadvertently moved in the opening direction thereof from the opening of the housing can be effectively prevented.

The storage device will now be described according to Figs. 11 to 14 below, in which a structural detail of a preferred cam element is shown.

When a motor vehicle carrying the storage device receives an impulse at the front thereof, the inertia force which is inevitably generated easily causes the storage case 1 to move forward together with the bolt member 1 and does not impose a very large load on the cam member 1 per se. When the motor vehicle collides with any other vehicle thereof from behind or when the motor vehicle collides with an obstacle while reversing, the case 1 is caused to move forward together with the body of the motor vehicle and the storage case 1 supported in the case 1 tends to remain in its current position, which is caused by the biasing force of the constant pressure spring 12. 12. As a result, the same phenomenon of separation arises in that it occurs when the housing and the storage case are moved in opposite directions to apply a very large load particularly to the cam member 1. This adverse phenomenon has motivated the development of the cam member described in Figs. 11 to 14.

Therefore, when considering the principle of the cam member 1 of the first embodiment in detail, this cam member adopts a construction such that the strength of the cam member 1 on the side of the closure part 4 thereof is positively increased by forming a part 17 with a larger wall thickness on the underside of the closure part 4 and its immediate vicinity of the cam recess 2 of the cam member 1 through a predetermined range as shown in Fig. 11.

Therefore, in the storage device including such a cam member, when the storage case is pressed into the case against the biasing force of the constant pressure spring 12, the bolt member on the side of the storage case locks to the locking part 4 of the cam recess 2 reinforced with the larger wall thickness part 17 and locks the storage case in the closed position thereof in the case against the biasing force, as shown in Fig. 12. When the storage case is further pressed into the case in the locked state, the bolt member separates from the cam recess 2 of the cam member 1 via the cam outlet 5, as shown in Fig. 13. As a result, the storage case is automatically moved in the opening direction thereof from the opening of the case by means of the biasing force of the constant pressure spring 12.

If the motor vehicle carrying the storage device collides with any other vehicle from behind or if the motor vehicle collides with a obstacle while the storage case is in the locked state in the closing position thereof, the impulse which is inevitably generated causes the same phenomenon of separation as occurs when the case and the storage case are moved in opposite directions to each other. Since the locking part 4 which performs the function of locking the bolt member integrally includes partially therein the part 17 with greater wall thickness, the possibility of the locking part 4 or the immediate vicinity thereof being broken under a large load exerted thereon is absolutely zero. Furthermore, since the shape of the increased wall thickness of the locking member 4 ensures comprehensive engagement of the bolt member with the locking member 4 over a significantly large width, the possibility of the bolt member being inclined upwards to the extent of releasing the leading end of the cam member 1 can be effectively avoided by increasing the apparent strength of the two components, ie the bolt member and the locking member 4.

Therefore, the storage case with such a cam member can be infallibly retained in the closed position thereof in the case and prevented from being unpredictably pushed out of the case even when the motor vehicle is subjected to a high impulse acting not only on the front but also on the rear.

When the closure member 4 is to be provided with a greater wall thickness, the member 17 with the greater wall thickness is formed, if desired, on the lower side, as shown in Fig. 11. The arrangement of this member 17 need not be limited to the position just mentioned. For example, the member 17 with the greater wall thickness may be provided, if desired, on the upper side of the closure member 4 or its immediate vicinity, as shown in Fig. 14(A), or the member 17 with the greater wall thickness may be provided, if desired, on both the upper and lower sides, as shown in Fig. 14(B). Naturally, the part 17 having a larger wall thickness can be expected to produce the same operating effect regardless of the relative position thereof.

Particularly, in the construction in which the part 17 of the increased wall thickness is provided, if desired, only on the lower side as shown in Fig. 11, the depth of the bolt member P, which reaches the vicinity of the root thereof, is allowed to contact the part 17 of the larger wall thickness on the side of the closure member 4. According to this state of comprehensive contact, the construction consists in the advantage that the bolt member P is effectively prevented from slanting and the leading end of the cam member 1 is excluded from sliding upward with increased certainty.

This invention makes full use of the advantages of the present storage device previously proposed by the inventor and at the same time makes up for deficiencies thereof by providing a very simple construction as described above. The storage device of this invention can therefore be expected to obtain a reliable safety function to cope with the impulse exerted on the front of the motor vehicle.

Claims (3)

1. A storage device with a safety function and for use in a motor vehicle, comprising: a storage case ( ) openably supported in a housing ( ) having an opening; a spring (12) provided between the storage case ( ) and the housing ( ) for constantly biasing the storage case ( ) in an opening direction thereof ; a cam element (1) which is biased to rotate in one direction and is arranged on the side of the housing ( ), the cam element (1) being provided on an outer side thereof with a guide surface (1a) and on an inner side thereof with a cam recess (2) which has a guide inlet (3), a closure part (4) and a guide outlet (5); and a bolt member ( ) arranged on the side of the storage case ( ) for movement along the guide surface (1a) of the cam member (1) which enters the guide inlet (3) of the cam recess (2) and engages with the closure part (4) of the cam recess (2) to close the storage case ( ) in a closing position thereof in the case ( ) against the biasing force of the spring (12) when a first pressing force is exerted on the storage case ( ); wherein the bolt member (P) moves in the cam recess (2) to be released from engagement with the closure member (4) of the cam recess (2) and brought to the guide outlet (5) of the cam recess (2), wherein the storage case ( ) automatically moves in the opening direction thereof through the opening of the case ( ) when a second compressive force is applied to move the closed storage case ( ) further into the housing ( ); wherein the closure part (4) and the guide outlet (5) of the cam recess (2) are separated from each other at a first edge surface of the cam recess (2) and the other edge surface of the cam recess (2) opposite the first edge surface is integrally provided with a protruding holding guide wall (6), the storage device being characterized in that that the holding guide wall (6) is arranged in a position between the closure part (4) and the guide outlet (5) of the cam recess (2), such that the closure part (4) of the cam recess (2) is positioned outwardly from the holding guide wall (6) of the cam recess (2); and that the bolt member ( ) is capable of colliding with an outer edge surface (6a) of the holding guide wall (6) of the cam member (1) and preventing the storage case ( ) from being pushed out of the housing ( ) when a large inertia force is exerted on the storage device; and that an adjusting wall (15) in the housing ( ) is in a position which enables a limitation of the extent of rotation of the cam element (1) when the cam element (1) is rotating in a direction which is opposite to the direction in which the cam element (1) is prestressed, and therefore opposite to the direction of release of the bolt element ( ) via the guide outlet (5). 2. Storage device with a safety function and for use in a motor vehicle, comprising: a storage case (B) openably supported in a housing ( ) having an opening; a spring (12) provided between the storage case ( ) and the housing ( ) for constantly biasing the storage case ( ) in an opening direction thereof ; a cam element (1) which is preloaded in one direction and is mounted on the side of the housing ( ), the cam element (1) being provided on an outer side thereof with a guide surface (1a) and on an inner side thereof with a cam recess (2) which has a guide inlet (3), a closure part (4) and a guide outlet (5); and a bolt member (P) disposed on the side of the storage case ( ) for movement along the guide surface (1a) of the cam member (1) which enters the guide inlet (3) of the cam recess (2) and engages with the closure part (4) of the cam recess (2) to close the storage case ( ) in a closing position thereof in the case ( ) against the biasing force of the spring (12) when a first pressing force is applied to the storage case ( ); wherein the bolt member ( ) moves in the cam recess (2) to be released from engagement with the closure part (4) of the cam recess (2) and brought to the guide outlet (5) of the cam recess (2), wherein the storage case ( ) automatically moves in the opening direction thereof through the opening of the case ( ) when a second pressing force for moving the closed storage case ( ) further into the case ( ) is applied; wherein the closure part (4) and the guide outlet (5) of the cam recess (2) are separated from each other at a first edge surface of the cam recess (2) and the other edge surface of the cam recess (2) opposite the first edge surface is integrally provided with a protruding holding guide wall (6), the storage device being characterized in that that the holding guide wall (6) is arranged in a position between the closure part (4) and the guide outlet (5) of the cam recess (2), such that the closure part (4) of the cam recess (2) is positioned outwardly from the holding guide wall (6) of the cam recess (2); and that the bolt element ( ) is capable of colliding with an outer edge surface (6a) of the holding guide wall (6) of the cam element (1) and the storage case ( ) from a from being pushed out of the housing ( ) when a large inertial force is exerted on the storage device; and that the cam element (1) has a compensation adjustment part (16) in order to bring about a coincidence of the center of gravity of the cam element (1) and the axis of rotation (7) of the cam element (1) with one another. 3. Storage device according to claim 1 or 2, characterized in that the cam element (1) is thicker on the closure part (4) than on the remaining part of the cam element (1).