FEDERALLY SPONSORED RESEARCH
Not Applicable
SEQUENCE LISTING OR PROGRAM
Not Applicable
BACKGROUND
The invention relates to a device for opening the cabinet door of a cabinet body as defined by the preamble to claims 1 and 7.
In conventional devices on the market, the cabinet door is mounted on the cabinet body via self-retracting hinges. This type of mounting has the advantage that precisely in the terminal angle of the closing motion of the cabinet door, a secure closure of the cabinet body is effected. The hinges also ensure that in the closed position, the cabinet door assumes a slight spacing x from the front of the cabinet body. However, the disadvantage of this device is that in order to be opened, the cabinet door must be provided with handles, handle fittings, and the like.
It is the object of the invention to develop a device for opening the cabinet door of a cabinet body that makes do without such handle elements, and in which the self-retraction of the hinges between the cabinet door and the cabinet body is unhindered.
This object is attained by means of the features of claim 1.
SUMMARY
A unit comprising an ejection piston, having a compression spring and a locking unit, and a tension rod, having an extension spring, is disposed in the cabinet body. The ejection piston and the tension rod are coupled together via a control device that acts only upon the extension of the tension rod with the cabinet door and displaces the ejection piston out of the cabinet body counter to the tensile force of the extension spring. In the closed position of the cabinet door, the ejection bolt and the tension rod are jacked into the cabinet body, and the locking unit locks the jacked-in position of the ejection piston. When the cabinet door is tapped, the spacing between the cabinet door and the cabinet body is eliminated and the locking unit disengages. After the cabinet door has been tapped, the compression spring of the ejection piston displaces the ejection piston from the cabinet body, whereupon the tension rod is also pulled out of the cabinet body, counter to the tensile force of the tension rod, by a retaining element on the inside of the cabinet door. After this intermediate position has been manually undone, the tension rod is extended farther outward, since the retaining element maintains the connection with the cabinet door, and the ejection piston can be returned into the cabinet body and locked in the retracted position via the locking unit. After the cabinet door is opened farther manually, the tension rod is released and is returned via the extension spring into the retracted outset position. In this way, it becomes possible for the cabinet door, set in the closed position, to open far enough merely by being tapped so that it can be grasped with one's hand and opened farther. When the cabinet door is closed again, the ejection piston and the tension rod are automatically put into their closed positions. The cabinet door therefore does not need to have any handle elements, and the function of the self-retracting hinges is unhindered.
This device can also be used in the same manner for drawers and the like that can be pulled out from a compartment of a cabinet body.
In a further embodiment, the unit can additionally have a damper unit that damps or brakes the impact of the cabinet door on the cabinet body.
The control unit can be embodied as a freewheeling gear wheel, which ensures the coupling of the tension rod with the ejection piston only upon retraction of the tension rod into the cabinet body.
The unit is fastened to the inside of the side wall of the cabinet body that faces away from the hinges of the cabinet door. The face ends of the ejection piston and of the tension rod, in the closed position of the cabinet door, protrude by the spacing from the front of the cabinet body. This spacing x is specified by the self-retracting hinge.
The face end of the tension rod can be provided with a magnetically conductive damping lining.
A further embodiment can be learned from coordinate claim 7 and dependent claims 8-11.
DRAWINGS
The invention will be described in further detail in conjunction with the drawings. In them:
FIG. 1 schematically shows the mounting of the unit in the cabinet body with a retaining element of the cabinet door;
FIG. 2 schematically shows the closed position of the cabinet door on the cabinet body;
FIG. 3 schematically shows the intermediate position of the cabinet door after the cabinet door has been tapped;
FIG. 4 schematically shows the cabinet door being opened farther manually;
FIG. 5 shows details of a unit fastened in the cabinet body;
FIG. 6 shows the elements of the unit in the closed position of the cabinet door;
FIG. 7 shows the elements of the unit in an opened intermediate position;
FIG. 8 shows the elements when the cabinet door in the intermediate position is being grasped, with the control unit in action between the tension rod and the ejection piston;
FIG. 9 shows the elements of the unit as the cabinet door is opened still farther manually (motion d);
FIG. 10 shows another version of the device, which has an ejection piston, a tension spring and a tension element and is controlled by two gear wheels and a connection element, in the outset position;
FIG. 11 shows the initiation of the motions when the cabinet door is tapped;
FIG. 12 shows the device in the intermediate position;
FIG. 13 shows the device upon further manual extension past the intermediate position;
FIG. 14 shows the device after the cabinet door is let go;
FIG. 15 shows the latching of the ejection rod with the retaining element mounted on the cabinet door; and
FIG. 16 shows the building in of the retaining element into the inside of the cabinet door.
DESCRIPTION
In FIG. 1, a cabinet body 10 is shown, which has a hinged cabinet door 11 on one vertical side at the front. The hinging is done by conventional hinges 12 with self-retraction; that is, the last, small closing angle of the cabinet door 11 is effected in a defined manner by springs of the hinges 12. A unit 20 is fastened opposite the hinges 12 and has an ejection piston 21 and a tension rod 25, which in the outset position protrude from the front of the cabinet body 10 by a spacing x. When the cabinet door 11 is closed, this spacing x is ensured by the self-retracting hinge. The fastening of the unit 20 is done on the inside 14 of the side wall 13.
FIG. 2 schematically shows the opening of the cabinet door 11 by tapping it in the direction a; the ejection piston 21 is definitive for the opening motion b of the cabinet door 11. After that, the cabinet door 11 assumes an intermediate position, as shown in FIG. 3. The cabinet door 11 is moved in the direction b by the ejection piston 21. From this intermediate position in FIG. 3, the cabinet door 11 can be opened farther by grasping it with one's hand, whereupon the ejection piston 21 and the tension rod 25 resume their outset position in the cabinet body 10, as shown in FIG. 4. The opening angle is defined by the motion d.
In FIG. 5, one exemplary embodiment of the unit 20 is shown. The unit 20 has an ejection piston 21, which is supported on the unit 20 by a compression spring 23 and has a locking unit 24. At the same time, the unit 20 has a tension rod 25, which is supported in the unit 20 by an extension spring 26. The ejection piston 21 is coupled to the tension rod 25 via a control unit 27 embodied as a freewheeling gear wheel. The control unit 27 is explained in terms of its mode of operation in conjunction with FIGS. 6-9. As FIG. 5 also shows, the unit 20 can have a damper unit 30, which from a cushioned damper 31 damps or brakes the impact of the cabinet door 11 on the front of the cabinet body 10. The cabinet door 11 has a retaining element 22, which is oriented toward the face end of the tension rod 25 and can be embodied as a magnet and which carries the tension rod 25 with it until the intermediate position of FIG. 7 is established. The face end of the tension rod 25 can be provided with a magnetically conductive damping lining 28.
FIG. 6 shows the outset closed position of the unit 20. The ejection piston 21 is subject to the tensing force of the compression spring 23 and the cooperating locking unit 24. The tension rod 25 too is retracted by the extension spring 26 correspondingly far into the cabinet body 10. The cabinet door 11 is additionally retained by the retaining element 22 on the tension rod 25. As the motion arrow a indicates, this outset position of the cabinet door 11 can be tripped and opened by tapping on the cabinet door 11 at a. In the process, the locking unit 24 is disengaged, so that the compression spring 23 can move the ejection piston 21 out of the cabinet body 10. The extension spring 26 of the tension rod 25 can follow along with this extension motion, since the retaining element 22 maintains the connection with the cabinet door 11, as FIG. 7 shows.
In this intermediate position, the cabinet door 11 can be grasped with one's hand and opened farther, as FIG. 8 shows with the motion c.
In this opening motion c, the tension rod 25 is coupled with the ejection piston 21 via the control unit 27 in such a way that the ejection piston is retracted into its outset position and locked with the locking unit 24. Finally, the tension rod 25 reaches its terminal extension position, and the retaining element 22 releases the connection with the cabinet door 11. The tension rod 25 can be retracted by the extension spring 26 into the cabinet door 10 into the outset position, as can be seen from FIG. 9.
In FIGS. 10-16, a different version of the device is shown, which operates with the same functional steps. This device, which is claimed in its own coordinate claim and dependent claims 8-11, has an ejection element 30 and a tension element 40 with a tension spring 43.
The unit 20 with the housing 60 is fastened to an inner wall, which is opposite the hinges. With an end piece 34 that has retaining elements 35, the ejection element 30 protrudes from the front of the cabinet compartment, in such a way that the housing 60 is flush with the face end of the cabinet body 11.
FIG. 10 shows the device in the outset position, in which the cabinet door 11 is connected to the end piece 34 and is remote from the face end of the cabinet body 10 by the spacing x. The device has both the ejection element 30, which has a set of teeth 31, and the tension element 40, with which the tension spring 43 is associated. The ejection element 30 and the tension element 40 have sets of teeth 31 and 41, which are oriented counter to one another. The sets of teeth 31 and 41 mesh diagonally with two gear wheels 32 and 42. A connection element 50 is associated with the two gear wheels 32 and 42 and can connect the two gear wheels 32 and 42 to one another in such a way that they rotate in the same direction. If no connection is made between the two gear wheels 32 and 42, then the two gear wheels 32 and 42 are rotatable in arbitrary directions independently of one another. The bearing axes of the gear wheels are offset from one another. The bearing axis of the gear wheel 32 is offset by a small spacing in the direction of the back wall 61 of the housing 60, so that differences when the two gear wheels are rotating in the same direction can be better compensated for.
In the outset position, the tension spring 43 is tensed. The tension element 40 rests against the back wall 61 of the housing 60. A rotatably supported locking element 44 locks the tension element 40 and the tension spring 43.
When one taps on the cabinet door 11, the end piece 34 of the ejection element 30 is thrust into the unit 20. The locking element 44 will then release the tension spring 43, so that as FIG. 11 shows, both the tension element 40 and the ejection element 30 execute a motion in the direction of the arrow a. The cabinet door 11 is now firmly held in the intermediate position (FIG. 12), and the tension spring 43 is relaxed and the tension element 40 rests on the front wall 62 of the housing 50. Upon this displacement, the two gear wheels 32 and 42 are connected to one another via the connection element 50.
If the cabinet door 11 in the intermediate position (FIG. 12) is grasped manually, then the ejection element 30 also follows along for a short displacement distance, as can be seen from FIG. 13. The gear wheel 32 is rotated, as is the gear wheel 42, both clockwise. This causes tensing of the tension spring 43 and causes it to be locked in the tensing position by the locking element 44. After that, the ejection element 30 releases the cabinet door 11. The ejection element 30 can be brought from this terminal position upon closure of the cabinet door 11 into the outset position, since when the gear wheels 32 and 42 are not connected to one another, the tension element 40 and the tension spring 43 are unaffected. Only once the final displacement distance defined by the spacing x is brought about by tapping on the cabinet door 11 is the tension spring 43 unlocked and can then be relaxed. The device has then returned to the outset position of FIG. 10.
A special feature here is also the connection between the cabinet door 11 and the end piece 34 of the ejection element 30. This end piece on the end of the ejection element 30 has detent elements 35, which latch with counterpart detent elements 51 of the retaining element 22. The retaining element 22 is preferably secured in a round receptacle 70 on the inside of the cabinet door 11. The terminal position of the extension motion of the ejection element 30 is determined by impacts of the ejection element 30 on the front wall 61 of the housing 60. The end piece 34 is still displaceable out of this position of the ejection element 30 to a limited extent; this displacement is determined by impacts on the end piece 34 and the ejection element 30. With this displacement, the detent elements 35 can also be pivoted, so that the latching is undone and the cabinet door 11 can be fully opened. The detent elements 35 latch to the counterpart detent elements 51 of the retaining element 22 whenever the end piece 34 is introduced back into the retaining element 22.