Abstract:
A locking apparatus locks a moving body to a housing against an urging force applied to the moving body. The locking apparatus includes a cam provided on one of the moving body and the housing, and having an engagement groove and a releasing groove, and a swivel body provided on the other of the moving body and the housing. The swivel body has a trace pin moving along the grooves and a balancer for balancing the trace pin. Thus, upon receiving a sudden load when the trace pin is in an engaging condition with the engagement groove, the trace pin is prevented from moving from the engagement groove to the releasing groove to thereby lock the moving body.

Description:
BACKGROUND OF THE INVENTION AND RELATED ART STATEMENT 
     The present invention relates to a locking apparatus, in particular a locking apparatus with safety function, the subject of which is a so-called push—push engagement mechanism that engages a moving body by a push operation and releases the engagement by a subsequent push operation, as well as a storage apparatus for vehicle. 
     Among locking apparatuses that comprise push—push engagement mechanisms, there is one that is constituted by a cam part with heart-shaped cam groove provided on one of a moving body and a housing, and a swivel body that is provided on the other side and has a trace pin that moves on the inside of the cam groove. FIGS.  10 ( a )- 10 ( c ) show one of the conventional structures. In this example, a moving body in a housing, i.e. a storage tray, is moved against the force of forcing means toward the direction of symbol C to close an opening of the housing, and is moved toward the direction of symbol O by that force to become in the open state. The swivel body  100  having a leaf-shaped arm is attached to the housing inside the vehicle compartment so as to be able to move via a pivot  103 , and it has a trace pin  102  on the tip. The cam part  104  is provided on the moving body, and it has a raised cam part  105  whose periphery forms a heart-shaped cam groove  106 , and a guide groove  107 . 
     The engagement operation of the push—push engagement mechanism is as follows. FIG.  10 ( a ) shows the engagement released state, where the moving body has moved in the direction of arrow O by the forcing means, and it is pulled out from the housing. In this open state, when the moving body is pushed back into the housing against the force of the forcing means toward the direction of arrow C in FIG.  10 ( a ), the trace pin  102  first meets the engagement guide cam surface  107   a  of the guide groove  107 , and the swivel body  100  rotates counter-clockwise. Upon further movement, after contacting the engagement guide cam groove  106   a  of the cam groove  106 , the trace pin  102  collides with the stopper cam surface  104   a  at the front of the cam part. The moving body is pushed in up to that collision. When the pushing force is released, the moving body is pushed back by the force of the forcing means, and the trace pin  102  engages the engagement groove  106   b  of the cam groove  106  as in FIG.  10 ( b ). The moving body is stopped by that engagement (that is, the push engagement operation is completed), and it is held in the housing. 
     In the next operation of the mechanism, when the moving body is pushed toward the direction of arrow C 1  in FIG.  10 ( b ), the trace pin  102  meets the stopper surface guide cam surface  104   b  at the front of the cam part, and is led from that guide cam surface  104   b  up to the neighboring stopper cam surface  104   c  accompanying the rotation of the swivel body  100 . When the pushing force is released, the moving body is pushed toward the direction of arrow C in FIG.  10 ( a ) by the force of the forcing means. As a result, the trace pin  102  returns from the stopper cam surface  104   c  to the original position through the contact of the cam groove  106 , the guide cam groove  106   c , the guide cam surface  107   b  on the side of the guide groove  17  along the way, and becomes in the open state. 
     From the fact that the above push—push engagement mechanism is constituted by the swivel body  100  with the trace pin  102  and the cam part  104 , as opposed to the type published in Japanese Utility Model publication No. H5-91964, in which a pair of engagement pieces engages and releases a tab of the other member, it is simpler as it does not require a dedicated spring member. Additionally, it is superior in terms of operating quality in that there is less noise when engaging and releasing. However, with this structure in FIG.  10 ( b ) in which the moving body is engaged, when an abrupt load (this load is an unanticipated load that would make a small movement of the moving body toward the direction opposite to the force pressure of the forcing means and roll the swivel body  100 ) is applied, i.e. by a sudden stop or collision while driving, a condition identical to the push release operation can occur. If this happens, the trace pin  102  meets the guide cam surface  104   b , and it easily moves from the stopper cam surface  104   c  to the releasing guide cam groove  106   c  of the cam groove  106  and the releasing guide cam surface  107   b  of the guide groove  17 . It may cause an unanticipated and sudden engagement release. 
     These erroneous operations damage the performance and quality of the product. As countermeasures, for example, the shape of the engagement groove  106   b  is modified such that the groove is firmly engaged with the trace pin  102 , or a setting the force pressure of the forcing means is adjusted. Nonetheless, the operating performance tends to be sacrificed, and it is still unsatisfactory. In the prior art, as in Japanese Patent Publication No. H7-266996, albeit using a different engagement mechanism, there is also known a structure that prevents in advance the occurrence of the unanticipated engagement release as above. However, the structure requires a spring member which forces the cam member on which the cam groove is formed to swivel one-way by the spring member. The larger number of parts is needed and it becomes more complicated. It is not also widely applicable as the force pressure setting of the spring member would be necessary for each product. 
     The object of the present invention is to solve the problems such as above. Specifically, it is an object of the invention to provide a push—push engagement mechanism formed of a heart-shaped cam part and a swivel body, wherein the occurrence of unanticipated engagement release of the push—push engagement mechanism can be prevented by a simple and widely usable structure. 
     Another object of the invention is to provide the push—push engagement mechanism as stated above, wherein an improvement of the reliability of the locking apparatus can be achieved, and it will be able to further expand the uses of the locking apparatus to other kinds of storage apparatuses. 
     Further objects and advantages of the invention will be apparent from the following description of the invention. 
     SUMMARY OF THE INVENTION 
     In order to achieve the above-mentioned objects, a locking apparatus has a push—push engagement mechanism and comprises a cam part with a heart-shaped cam groove provided on one of a moving body and a housing, and a swivel body provided on the other of the moving body and the housing and having a trace pin that moves on the cam groove, wherein the moving body is engaged with the housing at a fixed position by an operation of pushing the moving body opposite to the force of forcing means, and the engagement can be released by a subsequent push operation. Furthermore, the swivel body has a balancer that detects the load when an unanticipated load such as impact is received while in the engaged state, so as to make it possible to prevent the trace pin from moving from an engagement groove of the cam groove to a releasing guide cam groove. 
     In the present invention, “when an unanticipated load such as impact is received” means that when a vehicle is suddenly stopped while driving, a collision occurs, or excessive vibration is directly or indirectly received. In such cases, the moving body is slightly moved toward the direction opposite to the force of the forcing means and the swivel body moved. “Detects the load” means that the swivel body receives the load and automatically or by itself tries to allow the trace pin to move from the engagement groove of the cam groove to the releasing guide cam groove. “Cam part with a heart-shaped cam groove” means a type at least having a cam groove that is heart-shaped in the periphery of a raised cam part as the construction of the cam part. 
     The above structural characteristic is that, when the unanticipated load is received, the trace pin and the engagement groove shift positions relatively so as to release the engagement, but that shift of positions is corrected by the balance adjusting operation of the balancer of the swivel body, and the trace pin and the engagement groove are automatically moved toward engagement again, such that the releasing engagement is prevented. Accordingly, the storage apparatus for the vehicle according to this invention is particularly suitable for automobiles, trains, ships, airplanes, and so on, which tend to receive the sudden loads noted above, and the erroneous operation can be eliminated. Also, the manufacturing cost can be minimized, and the product operation, quality and safety can be improved. 
     In the first aspect of the invention, the swivel body comprises an attachment part for pivot that is attached on the side of the housing or moving body to be capable of swinging, a first arm, and a second arm. The first arm is connected to the attachment part from which the trace pin projects, and the second arm is connected to the attachment part at an angle of at least 90 degrees to the first arm to form the balancer. This materializes the present invention from the shape of the swivel body. Because this second arm is disposed at an angle of at least 90 degrees to the first arm in the engaged state, it is the optimal mode for controlling the direction of swinging of the swivel body and making it move (balance adjusting) exclusively not to disengage from the groove. 
     In the second aspect of the invention, the balancer comprises a spindle or weight that works in cooperation with the trace pin and the force of the forcing or urging means so as to return the swivel body which swings due to the load to the engagement groove. This spindle controls the rotational direction of the swivel body to the side of the engagement stopper cam surface. The urging means moves the moving body toward the direction of the engagement groove. The trace pin is moved by the movement of the moving body to the engagement groove and comes to the engaged state. The present invention utilizes this series of movements. 
     In the third aspect of the invention, the swivel body is a molded resin product, and the second arm has a metal member for the spindle on at least one part thereof. This is a superior structure in terms of producing a smaller weight for the spindle, because the swivel body in the present invention is used for balance adjustment operation. There may be a construction such that a metal member is inserted in the balancer, and the second arm itself is constituted by a metal member, and the like, and either is applicable to the present invention. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a generalized external view of the storage apparatus in the present invention; 
     FIG. 2 is a partially cut generalized structural drawing showing the storage apparatus of FIG. 1 when the lid is closed; 
     FIG. 3 is a partially cut generalized structural drawing showing the storage apparatus of FIG. 1 when the lid is opened; 
     FIGS.  4 ( a ) through  4 ( e ) is a detailed drawing of the slider which is a main member of the locking apparatus of the present invention; 
     FIGS.  5 ( a ) through  5 ( c ) is a detailed drawing of the swivel body which is a main member of the locking apparatus of the present invention; 
     FIGS.  6 ( a ) and  6 ( b ) are drawings showing the relation between the above slider and swivel body; 
     FIGS.  7 ( a ) through  7 ( c ) is a an operation drawing showing the operation of the above locking apparatus; 
     FIG. 8 is a drawing showing another example of the above swivel body; 
     FIGS.  9 ( a ) and  9 ( b ) are drawings showing yet another example of the above swivel body; and 
     FIGS.  10 ( a ) through  10 ( c ) is a drawing of a locking apparatus in the prior art. 
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     Hereunder, embodiments of the invention will be explained with reference to the accompanied drawings. 
     FIG.  1  through FIG. 3 shows a storage apparatus that incorporates a locking apparatus according to the present invention. FIG.  4 ( a ) through FIG.  5 ( c ) shows the constituent members of the push—push engagement mechanism. FIGS.  6 ( a ) and  6 ( b ) show the relationship between the slider and the swivel body when the push—push engagement mechanism is engaged, and FIGS.  7 ( a ) to  7 ( c ) show the operation of the push—push engagement mechanism. FIG.  8  through FIG.  9 ( b ) shows modified examples of the swivel body. In the explanation below, first, the storage apparatus that uses the locking apparatus of the present invention is explained, and then the locking apparatus is explained in detail, so that the operating characteristics and advantages are made clear. 
     FIG. 1 is a generalized external view of the storage apparatus applying the locking apparatus of the present invention; FIG. 2 is a partially exploded typical structural drawing showing the essential components when the push—push engagement mechanism is engaged; and FIG. 3 is a partially cut typical structural drawing showing the essential components when the push—push engagement mechanism is released. 
     As for the storage apparatus  1  of the embodiment, a housing  2  has an opening, and a lid  3  opens and closes the opening. The opening and closing operation of the lid  3  is accomplished by using a push—push engagement mechanism (the locking apparatus of the present invention) comprising a slider  4  that moves in the forward and backward directions of the housing  2 , forcing means  6  that forces the slider  4  toward the front of the housing  2 , damping means  9  that adjusts the speed of the slider  4 , a cam part  20 , and a swivel body  30 . This storage apparatus  1  is designed to be installed in the dashboard DP (its recessed place) in the vehicle compartment, but it may be other than the dashboard DP, for example it can also be incorporated into a part of an instrument panel or center console and so on. 
     The housing  2  forms a container shape having an opening at the front side. In the present invention, the member placement part including the lid  3 , the slider  4 , the forcing means  6 , the damping means  9 , and the swivel body  30  constitutes essential parts of the invention, while the internal structure and the external appearances of the housing  2  are optional. As shown in FIG. 2, the lid attachment part is located near the opening of the housing  2  and includes a pair of attachment pieces  2   a  that project forward the upper two sides. The lid  3  is attached at its inner parts to the two attachment pieces  2   a  via pivots  5   a , and it is pivotally supported to be capable of rotation between a closed position (FIG. 2) and an opened position (FIG.  3 ). The member placement part is provided along the external side surface of the housing  2 , and it comprises a front holding part  2   b  and a rear holding part  2   c . The front holding part  2   b  is attached roughly between the front and the middle of the housing  2 , and includes the end of the forcing means  6  and the slider  4  and damping means  9 . The rear holding part  2   c  positioned a little to the rear of the front holding part  2   b  has the swivel body  30 . 
     The front holding part  2   b  has a tab part  2   h  provided on the front upper side, a guide hole  11  that penetrates from front to back, a depressed part  12  provided on the outer side surface partitioned by that guide hole  11 , and an engagement surface  13  provided on the rear side of the guide hole part  11 . The tab part  2   h  defines the position of one end of the forcing means  6 . The forcing means  6 , which is attached to the inner surface of the lid at one end and is positioned by the tab part at the other end, is a spring member supported around the pivot  5   a , and always pushes the lid  3  toward the open position. On the back surface of the lid  3 , a connecting rib  3   a  that connects the slider  4  is placed to protrude outward as in FIG.  3 . 
     The guide hole  11  roughly corresponds to the vertical section of the slider  4  which is placed inside, and a part of the slider  4  is exposed. The front side of the slider  4  and a connecting rib  3   a  are connected via a link piece  14 . As shown in FIG. 3, one end of the link piece  14  is connected to the rib  3   a  by a shaft  5   b  (in the embodiment, the shaft part is integrally formed with the link piece  14 ), and the other end thereof is connected to the front side of the slider  4  via a shaft part  5   c , so that both can rotate freely. When the lid  3  is opened, the slider  4  is moved up to the most forward position (this position is restricted by the engagement surface  13 ) via the link piece  14 . When the lid  3  is closed, the slider  4  is moved up to the most rear position (this position is the end point of rotation of the lid  3 , and is engaged by the cam part  20  and the swivel body  30 ) via the link piece  14 . 
     The depressed part  12  has an open part that penetrates into the guide hole part  11 , and the damping means  9  is provided at a predetermined position. The damping means  9  consists of an oil damper, and the like, and it has a gear  9   a  that is installed on the side of the rotating shaft that receives the resistance of the operating oil. The gear  9   a  engages rack teeth  19   a  of the slider  4 . By this engagement, the damping means  9  can regularly be operatable when the slider  4  is moved forward and backward. 
     The rear holding part  2   c  is a place that incorporates the swivel body  30  which constitutes the locking apparatus of the present invention. In this example, the upper surface is horizontal, and it has a cylindrical boss part  2   d  that pivotally supports the swivel body  30  to rotate freely. Minimum function of the rear holding part  2   c , however, is to hold the swivel body  30  in a stable state, and to be located immediately beneath the cam part  20  of the slider  4  when the lid  3  is in the closed position. Above the rear holding part  2   c , there is provided a guide wall part  2   e  that projects from the side surface of the housing  2  and guides by contacting with the upper surface of the rear side of the slider  4 . 
     In FIG.  4 ( a ) to FIG.  5 ( c ), FIG.  4 ( a ) is a side view, FIG.  4 ( b ) is a top view, FIG.  4 ( c ) is a bottom view, FIG.  4 ( d ) is an enlarged view taken along line  4 ( d )— 4 ( d ) in FIG.  4 ( a ), and FIG.  4 ( e ) is an enlarged view of part  4 ( e ) in FIG.  4 ( c ). FIG.  5 ( a ) is a top view, FIG.  5 ( b ) is a side view, and FIG.  5 ( c ) is a sectional view taken along line  5 ( c )— 5 ( c ) in FIG.  5 ( a ). The locking apparatus  10  is an example in which the cam part  20  is provided on the slider  4 , and the swivel body  30  is attached to the rear holding part  2   c . However, as for the push—push engagement mechanism, the swivel body  30  can be attached to the slider  4 , and the cam part  20  can be provided in an analogous place on the holding part  2   c.    
     The slider  4  which has the cam part  20  is explained here. The slider  4  forms a long and slender rod shape, and functionally, it is divided into a front side  17 , a rear side  18 , and a middle part  19 . The front side  17  has two projection parts with holes  17   b  that pierce the two parts on the same axis, and an elastic piece  17   a  that is provided between the two parts and projects diagonally downward. The attachment hole  17   b  is a hole for connecting the rear side of the link piece  14  described above via a shaft part  5   c . The elastic piece  17   a  presses against the end part of the link piece and is linked to the link piece  14  to eliminate a gap. The middle part  19  has rack teeth  19   a  on one side of the part, an engagement claw  19   b  that meets the engagement end surface part  13  noted above, and a guide indentation  19   c  that is provided on the bottom surface and extends from front to back. The rack teeth  19   a  engage the gear  9   a  of the damping means  9  and enables the controlled forward and backward movements of the slider  4 . The engagement claw  19   b  is placed against the engagement end surface part  13 , and it controls the most forward position of the slider  4 . The guide indentation  19   c  engages a projected part (not shown) that is provided on the guide hole part  11  noted above, and it makes the smooth sliding of the slider  4 . The rear side has the cam part  20  on the bottom surface side. 
     The cam part  20 , as in FIG.  4 ( c ), comprises a heart-shaped cam groove  22  that is formed by a raised cam part (a heart-shaped raised cam part)  21 , and a guide groove  23  that continues with the cam groove  22 . As for the cam groove  22  and the guide groove  23 , the two sides are partitioned by control wall parts  24  and  25  and the front side by the rear part  19   d  of the center part  19 , and the rear end is continuous with the outside. The cam groove  22  is formed along the outer periphery of the cam part  21 , and it consists of an engagement guide cam groove  22   a , an engagement groove  22   b , and a releasing guide cam groove  22   c . The engagement guide cam groove  22   a  is a sloping groove that corresponds to one side of the heart shape and extends diagonally on the front side (rear part  19   d ) from the control wall part  25  between control wall parts  24 ,  25 . The engagement groove  22   b  is positioned in roughly the center of the upper side part of the heart shape, and collapses inward between the part sloping from the apex of the guide cam groove  22   a  and the apex of the guide cam groove  22   c.    
     The control wall part  25  has a place between the cam groove  22  and the guide groove  23  bent into a mountain shape up to near halfway between the left and right of the control wall part  25 , and the entrance side of the guide groove  23  is formed as the engagement guide cam surface  25   a  and the cam groove  22  side as the releasing cam surface  25   b . On the end surface side of the rear part  19   d , that is, the front of the cam part  21 , there are provided an engaging stopper cam surface  26   a , a sloping guide cam surface  26   b , and a releasing stopper cam surface  26   c . These are substantially the same as in the past. 
     This swivel body  30  is a molded resin product comprising an attachment part  31 , a first arm  32 , and a second arm  33 . The attachment part  31  has a pivot hole  31   a  that is provided roughly in the center of both arms  32 ,  33 , and a pair of elastic wing pieces  38  that is provided on both sides roughly intersecting the first arm  32  and supports the swiveling or sliding ability of the swivel body  30 . The first arm  32  forms a roughly triangular leaf shape. On the upper side, there is provided a cutout cavity for making it lightweight, and on the tip, there is provided an installation hole  32   b.    
     The second arm  33  has a spindle  36  that serves as the main component of the balancer on the free end side. The second arm  33  is formed integrally with the attachment part  31 , and the spindle  36  is formed on the tip. The spindle  36  has a metal member  37  inserted into a molded resin part, and it is heavier than the first arm  32  by a specified value. The angle with the first arm  32  is set to 130-140 degrees. This angle, as shown by the projected line in FIG.  5 ( a ), determines the rotational direction of the swivel body  30  centered on the pivot hole  32   a . It is designed based on the load of the spindle  36  or the total weight of the second arm  32 , such that once the trace pin  35  has escaped from the position in FIG.  7 ( b ), the swivel body  30  exclusively swivels toward the direction of the solid line in FIG.  7 ( c ), as the optimum for balance adjustment. 
     The above swivel body  30  is fixed with the trace pin  35  in the installation hole  32   b  as in FIG.  6 ( b ). The trace pin  35  is a metallic pin, it is pressed upward from the bottom side into the installation hole  32   b  and it is fixed via adhesive, and the like. The tip is projected outward above the attachment part  31 . The swivel body  30  is attached to swivel or slide freely above the rear holding part  2   c . In this case, the swivel body  30  receives the boss part  2   d  in the pivot hole  31   a  as in same drawing, and it is attached by screwing a screw  40  to the boss part  2   d  via a washer  41  from the side of the pivot hole  31   a.    
     The main operation of the locking apparatus  10  is outlined together with the lid opening and closing operation of the storage apparatus  1 . FIG. 3 shows the state in which the lid  3  is fully opened up to the top horizontal position by the force of the forcing means  6 , and small objects can be put into or taken out from the housing  2  through the front open part of the housing  2 . In this opened state, the moving body  4  is moved to the most forward position, and the engagement claw  19   b  meets the engagement end surface part  13 . The trace pin  35  is at the entrance side of the guide groove  17  as shown in FIG.  7 ( a ). 
     In closing the lid  3 , when the open end of the lid  3  is pushed downward opposite to the force of the forcing means  6 , the lid  3  rotates downward with the pivots  5   a  as the pivot point, and the movement of that lid  3  is transmitted to the slider  4  via the link piece  14 . The slider moves backward in FIG. 3 accompanying the movement toward the closed position of the lid  3  at a speed damped by the damping means  9 . When the slider  4  moves backward, the pin  35  first meets the engagement guide cam surface  25   a . Doing thus, the swivel body  30  rotates counter-clockwise, then meets the engagement guide cam surface  22   a  followed by colliding with the engaging stopper cam surface  26   a . When the trace pin  35  meets the stopper cam surface  26   a , the lid  3  passes the proper closed position and is moved a little toward the open part of the housing  2 . When the pushing force on the lid  3  is released, it is returned to the proper closed position by the force of the forcing means  6 . This is consistent with when the trace pin  35  moves to the engagement groove  22   b  from the stopper cam surface  26   a  as in FIG.  7 ( b ), and it has become to the engaged state by the push operation. That is, the push operation is completed, and the lid  3  is in the closed position in FIG.  2 . 
     In case of opening the lid  3  again, when the lid  3  is pushed (the arrow C 1  in FIG.  7 ( b )), the trace pin  35  meets the sloping guide cam surface  26   b , and is led up to the releasing stopper cam surface  26   c  accompanying the rotation of the swivel body  30 . When the pushing force is released, the lid  3  is returned forward. This slider  4  moves forward in synchronization with this while being damped. At the same time, the trace pin  35  is returned to the state in FIG.  7 ( a ) meeting the releasing guide cam surface  25   b  along the way. That is, the subsequent push operation is completed, and the lid  3  is placed in the original open position. These steps are substantially the same as in the past. 
     The operating characteristic of the present invention resides in that when the lid  3  is in the closed position and the storage apparatus  1  has received a sudden load that is forward, namely, the same as the push release operation, due to abrupt stopping of the vehicle or excessive impact. In such a circumstance, the swivel body  30  works with the balance adjustment function using the second arm  33  with the spindle  36 . Upon receiving the load, the swivel body  30  tries to rotate or roll around the screw  40 . The rotational direction is balanced to be the direction of the arrow in FIG.  7 ( c ), by the presence of the second arm  33  with the spindle  36 . As a result, even when the trace pin  35  disengages from the engagement groove  22   b , that direction is always controlled toward the engaging stopper cam surface  26   a . Accordingly, when the load no longer exists, the trace pin  35  comes to be engaged with the original engagement groove  22   b  from the engaging stopper cam surface  26   b  by the same movement as the movement from FIG.  7 ( a ) to FIG.  7 ( b ). After that, it returns to the normal operation. 
     FIG.  8  and FIG. 9 are two modified examples of the above swivel body  30 . In each modified example, the parts that are the same or similar are assigned by the same symbols, and only the points of modification are explained. The swivel body  30 A is an example when the second arm  33 A is formed separately. That is, this second arm  33 A consists of a metallic member with a weight  36  formed integrally on the side of the tip. Also, with respect to the swivel body  30 A, it is designed to be integrated by engaging the base side of the second arm  33 A in a depressed place provided on one part of the attachment part  31 . This design has an advantage because it is difficult to assure the load on the side of the second arm  33 A (the weight relative to the side of the first arm  32 ) due to a small size of the swivel body  30 A. This construction makes the load design of the second arm  33 A easier, and makes it possible to assuredly obtain the intended balance adjustment by controlling the total dimensions of the second arm part  33 A. 
     The swivel body  30 B in FIGS.  9 ( a ) and  9 ( b ) is an example having a modified structure incorporating into the side of the housing  2  or the moving body. That is, this attachment part  31  has a pair of elastic engagement parts  39  on the outer periphery, and those elastic engagement parts  39  are incorporated into an attachment part  2   f  (an attachment hole provided at this location) by insertion method. In this case, the shape of the above rear holding part  2   c  is modified, and the attachment part  2   f  and the pivot  2   g  are attached. It is possible for the parts to be attached and rotate freely without using the screw  40  and the like. In this example, the trace pin  35 A is formed integrally on the swivel body  30 B, and the number of components is further reduced. 
     Thus, the present invention, as long as the technical elements described in the claims are provided, is capable of various modifications based on the above fundamental example. Of course, the moving body  4  is not limited to the slider of the example, and it also may be a storage tray or lid that is moved with respect to the housing, furthermore a slider member, such as in Japanese Patent Application No. H11-163992, and other things. 
     As explained above, the locking apparatus of the present invention eliminates sudden release of the engaged state due to unanticipated load by sudden stopping while driving or by collision, and the like, or when excessive vibration is directly or indirectly received. Also the locking apparatus of the present invention improves the operation and quality of the products, and can expand the application thereof. 
     Also, the storage apparatus for vehicle to which the present invention is applied can improve the safety and the reliability of the apparatus over the prior art by eliminating unanticipated engagement release, that is, erroneous operation of the moving body, as well as unanticipated pop-up. 
     While the invention has been explained with reference to the specific embodiments of the invention, the explanation is illustrated and the invention is limited only by the appended claims.