DE3504691C2 - - Google Patents

Description

The present invention relates to a train lock mecha with

• a) a fixed bearing with an inwardly projecting sleeve,
• b) an attachment that is in the bearing and coaxial to the Lagerman chain is rotatably mounted,
• c) a shaft that is rotatable and coaxial to the bearing sleeve in is stored in the bearing and protrudes from it,
• d) a motion control bushing that is inside the bearing sleeve is attached, a pair of diametrically opposite, axially or transversely running motion control grooves in the motion control socket,
• e) wherein the axially extending motion control grooves on one End in one end of the transverse motion control grooves pass at a movement transition point, and with
• f) a cross pin attached to the shaft and itself extends transversely in opposite directions, the opposite ends of the cross pin in one of the motion control grooves protrudes.

Such a draw lock mechanism is from US-PS 33 97 000 known.

Locks with a pulling mechanism of a similar type are shown in U.S. Patents 28 60 904, 33 02 964 and 34 02 958 disclosed.

The locks shown in the aforementioned patents Pull mechanism can be used as "lift and turn" locks be characterized. One of the disadvantages of the "lifting and Rotary "locks of the type used in the two  mentioned U.S. Patents 28 60 904 and 33 02 964 shown is that when you open the lock It is possible to turn the handle before lifting it and vice versa that it is possible to close push the handle in before turning it. These Opportunities can cause problems.

The last of the above four patents, namely the US-PS 34 02 958, represents an improvement over the "Lift and turn" locks of the two previously mentioned Patent specifications by adding extensions to the sides of the Handle are provided. Enclose these extensions the square head of a sleeve, causing a turning of the Handle in the latched position is prevented. However, if sufficient torque is applied, it is possible to break off the extensions from the handle if it is rotated before lifting. If the Handle is in the open position, ensure the interacting surfaces on the handle and sleeve for a locking operation. Even with these improvements it is still possible to use the closure device in to lock the pawl in the wrong position.

The present application relates to and describes an amendment to our pending U.S. patent application serial number 5 74 041 dated January 26, 1984 with the title "Building a lock with a pull mechanism", for one Late registration with the German on January 23, 1985 Patent office has been filed (P 35 02 418.6).

In the lock known from the aforementioned US-PS 33 97 000 the control button carries the axial movement of the shaft out. In order to close the solid togetherness To ensure eating parts, the second part must also be provided with a special counterholder that is on ner has one side cam surfaces to the desired  To achieve a tightening effect. Doing the required rotation force on the shaft due to the torsional action of a spring aims. To unlock the button with the shaft be rotated against the torsional force of the spring, whereupon the torsion spring, which is also under axial pressure Shaft and actuating button again in the axial direction outside presses.

In contrast, the present invention the task of creating a train lock mechanism, in which the shaft is caused solely by the rotation of a bet tigungselementes in a desired order one after the other performs a rotary and an axial movement.

Another object of the present invention is also there rin to create a lock with a pull mechanism, the opposite the lock from our aforementioned patent application changed and improved.

In particular, one goal is a second Embodiment of a lock with pull mechanism create that similar to our aforementioned patent registration is, but differs from this. In In both forms the closing process is in contrast to the two-stage lifting and rotating movement for locks after State of the art by a single rotary movement leads.

Another goal is to build a castle with a train chanism to create that outside the door not so far protrudes like the handle of the lock in our above mentioned patent application.

Another goal is to build a castle with a train mecha creating a tool instead of a tool rotatable handle is closable.

This problem is solved by the mechanism mentioned at the beginning mus, which is characterized by  

• g) a rotatable driving sleeve which is coaxial to the shaft and the motion control bush arranged in the bearing sleeve and has diametrically opposed driver grooves, the both axially and in the circumferential direction Kom have components, whereby
• h) the cross pin attached to the shaft is in the driver splines,
• i) a device for connecting the attachment and the entrainment merhülse, whereby the application of a rotary movement on the Attachment rotates the driver sleeve, in which
• k) due to the rotational movement of the top of the shaft over the so probably in the driver grooves as well as in the motor control led cross pin successive rotary and axial movements be issued, depending on the direction of rotation of the Essay in this order or in the opposite order.

The only cross pin works both as a cam follower as well as a motion control pin. A cam groove is for each end of the cross pin provided, further two under shared motion control grooves in a cuff, one of which one is axial and the other is transverse. If the The motion control pin is in the axial groove only an axial movement of the pawl possible. If the movement control pin in the transverse groove then there is only a lateral movement of the lock jack possible. The pin and the grooves are like this arranged that during a single uniform Rotary movement of the cross pin of one of the tool Control grooves merges with the other and the pawl one axial and one after the other during opening then a sideways movement and while closing first a lateral and then an axial movement executes. However, the order of the steps can be changed a changed construction of the pawl can be reversed.  

The lock in the present application contains only one single cross pin that has a double function. He namely works as a motion control pin and also as Cam follower.

Further refinements of the train lock mechanism according to the present invention result from the subclaims.

An embodiment of the invention is in the drawing shown and is described in more detail below. It shows

Fig. 1 built-in a top view of an inventive lock with the pulling mechanism, shown in a cabinet door and fully latched condition,

Fig. 2 is a cross-sectional elevation taken along the line 2-2 in Fig. 1,

Fig. 3 is a sectional view in the direction to the outside along the line 3-3 in Fig. 2,

Fig. 4 is a sectional view in the direction to the outside along the line 4-4 in Fig. 2,

Fig. 5 is a sectional view in the direction to the outside along the line 5-5 in Fig. 2,

Fig. 6 is a partially sectioned view of the lock with the pulling mechanism, in the cabinet door eingebau th and fully latched condition

Fig. 7 is a view similar to FIG. 6, but in the partially unlatched condition of the locking pawl,

Fig. 8 is a view similar to Fig. 6 and 7, but in the fully released state of the pawl.

Fig head. 9 and 10 is a view similar to Fig. 1 and 2, but with a modified form of the bearing, which has on the outer side of the door a head which is Wesent Lich narrower shown as in Fig. 1 and 2.

The main components of the lock with Zugmecha mechanism according to the present invention are a pin or attachment 10 , a bearing 30 , a rotatable, grooved driving sleeve 20 , a fixed, grooved motion control bush 40 , a shaft 50 and a pawl 70th The shaft 50 carries a cross pin 60 which plunger works both as a cam and as a motion control pin.

In the drawing, the attachment 10 is shown with a hexagonal recess 11 for receiving a hexagonal actuation tool. The recess 11 could of course have other shapes, for example a square or an octagonal.

The attachment 10 is cylindrical and has a cylindrical bore 18 which receives the outer end of the shaft 50 . The attachment 10 is rotatable within the bearing 30 , movement of the attachment 10 in the axial direction of the shaft 50 being prevented by a locking ring 14 which lies in grooves 13 which are arranged at precisely dimensioned locations in the attachment 10 and the bearing 30 . The inner end of the attachment 10 is for receiving brackets 21 and the attachment 10 and the drive sleeve 20 is provided connecting the merhülse of the Mitneh 20 protrude with a pair of grooves 16 axially outwardly. In this way, when the attachment 10 is rotated, e.g. B. by a suitable inserted into the recess 11 tes tool, the driving sleeve 20 also rotated.

The driver sleeve 20 is provided with a pair of cam grooves (driver grooves 25 ) which are arranged 180 ° apart on the circumference. Each of the driver grooves 25 runs in a direction that has both circumferential and axial components.

Coaxial between the shaft 50 and the driving sleeve 20 is a fixed motion control bushing 40 with a pair of axial motion control grooves 41 and a pair of circumferentially extending motion control grooves 42 . One groove of each pair is 180 ° apart from the other. The inner end of each axial movement control groove 41 is connected to one end of one of the circumferential movement control grooves 42 . The motion control bushing 40 is prevented from rotating with respect to the bearing 30 by a pair of brackets 44 . These brackets 44 project axially inwards into grooves in the inner ends 32 of the bearing 30 .

The bearing 30 generally consists of a Hohlzylin which is fixed by screws 56 to the cabinet door D. These screws 56 are inserted in eyelets 38 of an outer part of the bearing 30 arranged on the outside of the door D, while a sleeve part 31 protrudes inwards through an opening in the door D. The inner end 32 of the bearing 30 is closed except for a central hole through which the shaft 50 passes. The inner ends of the fixed motion control bushing 40 and the rotatable driving sleeve 20 abut the end 32 of the bearing 30 .

The pairs of grooves in the fixed motion control bushing 40 operate accordingly as an axial and transverse motion control grooves 41 and 42 . They sequentially pick up the opposite ends of cross pin 60 in one order or another, as will be described.

The shaft 50 is an elongated shaft, the head end of which extends into the bore 18 in the attachment 10 . The shaft 50 protrudes inward through the hole in the inner end 32 of the bearing 30 and beyond, the shaft 50 being mounted so that its central axis coincides with the central axis of the motion control bushing 40 and the driving sleeve 20 . The inner end 54 of the shaft 50 is threaded and there is mounted a pawl 70 which is held in place by a pair of nuts 71 and which is adjustable in the axial direction.

The relative positions of the movement of the control sleeve 40 and the drive sleeve 20 could be reversed, ie, the loading wegungssteuerbuchse 40 could radially outside the carrier sleeve 20 rather than be disposed within the same.

On the shaft 50 , the cross pin 60 is mounted, which projects transversely in both directions over the shaft 50 and which serves as a cam follower and also as a movement control pin.

The outer end of the shaft 50 is provided with a central bore 61 in which a coil-shaped compression spring 62 is arranged. The outer end of the compression spring 62 presses against the attachment 10 . Thus, the compression spring 62 biases the shaft 50 inwards against the notched position. This preload keeps the ends of the cross pin 60 in closed contact with the inner wall 22 of the driving groove 25 . The prestressing compression spring 62 is desirable, but not essential, since even without this spring, the ends of the cross pin 60 would follow the driver grooves 25 . However, the drive grooves 25 have a width that is slightly larger than the diameter of the cross pin 60 and in this regard the biasing compression spring 62 is useful for pressing the cross pin against the inner wall 22 of the cam grooves 25 . The cross pin 60 determines whether, due to the rotation of the attachment 10, the shaft 50 and the pawl 70 are moved only in the axial direction or only at an angle thereto. That depends on whether the opposite ends of the cross pin 60 are in the axially directed movement control grooves 41 or in the transverse movement control grooves 42 .

As can best be seen in FIGS. 1 and 3, the driving sleeve 20 is driven in the direction of rotation when the attachment 10 , for. B. is rotated by a tool inserted into the hexagonal recess, as is to be expected from the cam clips (clips 21 ) projecting into the grooves 16 in the attachment 10 . When the drive sleeve 20 is rotated, the cross pin 60 is moved, but whether it is moved axially or transversely depends on whether the ends of the cross pin 60 are in the axial or in the transverse grooves of the movement control bush 40 .

In Fig. 6 the lock is shown in the fully latched position, in which the pawl 70 is in engagement with the pivot frame F of the cabinet. In the latched position, the attachment 10 is in the end position in the clockwise direction, seen from the view from the left in Fig. 6, and the two opposite ends of the cross pin 60 protrude through the axial movement control grooves 41 in the movement control bush 40 through and into closed extreme ends of the driver grooves 25 into it.

In order to release the cabinet door D from the cabinet frame F, the attachment 10 is rotated counterclockwise in the direction of the arrow in FIG. 6. When this is done, the top 10 and the driving sleeve 20 rotate as a unit. The cross pin 60 cannot rotate because its opposite ends are located diametrically opposite the axial movement control grooves 41 of the fixed movement control bush 40 . As a result of the rotation of the follower sleeve 20 counterclockwise, the force of the compression spring 62 causes the opposite ends of the cross pin 60 to follow the inner walls 22 of the opposed follower grooves 25 , and as a result the cross pin 60 and therefore also the shaft 50 and the pawl 70 inwardly toward the unlatched position until the ends of the cross pin 60 reach the transverse motion control groove 42 .

After the attachment 10 and the driving sleeve 20 have been rotated as a unit by 120 ° from the position shown in FIG. 6, the cross pin 60 has moved axially inwards to the position shown in FIG. 7 and is now aligned with the opposite ones Motor control grooves 42 . A further rotation of the attachment 10 and the driving sleeve 20 now causes the cross pin 60 , the shaft 50 and the pawl 70 to rotate, since the opposite ends of the cross pin 60 move within the opposite movement control grooves 42 . In this way, the pawl 70 is moved out of alignment with the cabinet frame F, and after a rotation of 60 °, the swing door D is fully released, as shown in Fig. 8. The attachment 10 is now rotated by 180 ° with respect to the latched-in position shown in FIG. 6.

The notching process is simply the reverse of the notching process that has just been described. Since when the latch 10 is turned clockwise, the opposite ends of the cross pin 60 move transversely in the transverse motion control grooves 42 , and the shaft 50 rotates about its axis. The cross pin 60 then moves axially outward. These successive movements are effected by the walls 22 of the drive grooves 25 which drive the ends of the cross pin 60 in the transverse or circumferential direction by the transverse movement control grooves 42 until the ends of the cross pin 60 abut the edge of the axial movement control grooves 41 . The walls 22 of the driver grooves 25 then drive the ends of the cross pin 60 axially outward through the axial movement control grooves 41 . Thus, the driving sleeve 20 and the movement control grooves 41 and 41 cause the angular and axial movements in a sequence which results from a uniform rotation of the attachment 10 in the direction of the latched position.

In the embodiment of the lock mechanism according to FIGS . 1 to 8, the bearing 30 is fastened to the cabinet door D by a pair of screws 56 , which are inserted into eyes 38 of the part of the bearing 30 arranged on the outer surface of the cabinet door D. In some installations, a lock mechanism with a narrower profile on the outside of the cabinet door D is desirable. In such cases, the bearing can be given the shape shown in Figs. 9 and 10.

In FIGS. 9 and 10, the bearing, which is designated 130, on the outer surface of the cabinet door D a part 138 with a circular shape. There are no eyelets protruding in opposite directions for receiving screws. In FIGS. 9 and 10 is the machine part extending through the opening in the cabinet door D inside, the outside provided with a thread, and a nut 156 is so far screwed onto the sleeve portion until it against the inner surface of the cabinet door D bumps. A spring washer can be inserted between the nut 156 and the cabinet door D. In this way, the lock mechanism is securely attached to the cabinet door D. In all other relationships, the lock mechanism of FIGS . 9 and 10 is similar to that of FIGS. 1 to 8.

The new lock is built into a moveable cupboard door described. That is the preferred place. However, could a castle with the basic idea of the present invention also on a fixed cupboard instead of a cupboard door to be appropriate. In such a case, the wave and The pawl can be moved at an angle to one at the Intervene inside the door-mounted bracket and then the door in a tightly closed position axially inwards pull. That is the reverse of the axial movement that used to hold the door in the tightly closed position pull when the lock is attached to the door.

Claims (15)

1. Pull lock mechanism with

• a) a fixed bearing ( 30 ) with an inwardly projecting bearing sleeve ( 31 ),
• b) an attachment ( 10 ) which is rotatably mounted in the bearing ( 30 ) and coaxially to the bearing sleeve ( 31 ),
• c) a shaft ( 50 ) which is rotatably and coaxially mounted to the bearing sleeve ( 31 ) in the bearing ( 30 ) and projects inward therefrom,
• d) a motion control bushing ( 40 ) which is fastened within the bearing sleeve ( 31 ), a pair of diametrically opposite, axially or transversely running motion control grooves ( 41, 42 ) in the motion control bushing ( 40 ),
• e) wherein the axially extending movement control grooves ( 41 ) at one end pass into an end of the transverse movement control grooves ( 42 ) at a movement transition point, and with
• f) a cross pin ( 60 ) attached to the shaft ( 50 ) and extending transversely in opposite directions therefrom, the opposite ends of the cross pin ( 60 ) projecting into each of the motion control grooves ( 41, 42 ),

marked by

• g) a rotatable driver sleeve ( 20 ) which is arranged coaxially to the shaft ( 50 ) and the movement control bushing ( 40 ) in the bearing sleeve ( 31 ) and has diametrically opposed driver grooves ( 25 ) which have both axial and circumferential components , in which
• h) the transverse pin ( 60 ) attached to the shaft ( 50 ) extends into the driving grooves ( 25 ),
• i) a device ( 16, 21 ) for connecting the attachment ( 10 ) and the driving sleeve ( 20 ), whereby the application of a rotational movement on the attachment ( 10 ) sets the driving sleeve ( 20 ) in a rotating movement, wherein
• k) due to the rotary movement of the attachment ( 10 ) of the shaft ( 50 ) over the transverse pin ( 60 ) guided both in the driver grooves ( 25 ) and in the movement control grooves ( 41, 42 ), rotary and axial movements are issued one after the other, depending on of the direction of rotation of the attachment in this or in the opposite order.

2. Pull lock mechanism according to claim 1, characterized in that a pawl ( 70 ) on the shaft ( 50 ) is attached. 3. Pull lock mechanism according to claim 1 or 2, characterized in that a biasing means is provided to bias the shaft ( 50 ) in one direction to keep the cross pin ( 60 ) with a wall of each cam groove in contact. 4. Pull lock mechanism according to claim 3, characterized in that the biasing device drives the shaft ( 50 ) inwards towards the unlatched position. 5. Pull lock mechanism according to one of claims 1 to 4, characterized in that the fixed bearing ( 30 ) is fixed to a closure part and the bearing sleeve ( 31 ) protrudes through an opening in the closure part inwards. 6. Pull lock mechanism according to one of claims 1 to 5, characterized in that the attachment ( 70 ) is provided with a non-circular recess ( 11 ) for receiving a non-circular head of a turning tool. 7. Pull lock mechanism according to one of claims 1 to 6, characterized in that a locking ring is provided to prevent relative axial movement between the bearing ( 30 ) and the attachment ( 10 ). 8. Pull lock mechanism according to one of claims 1 to 7, characterized in that the attachment ( 10 ) and the driving sleeve ( 20 ) connecting device contains chambers ( 21 ) which protrude from one into incisions in the other. 9. Pull lock mechanism according to claim 8, characterized in that the brackets ( 21 ) project axially outwards from the driving sleeve ( 20 ) into incisions in the attachment ( 10 ). 10. Pull lock mechanism according to claim 8, characterized in that the movement control bushing ( 40 ) is secured against rotation in relation to the bearing sleeve ( 31 ) by brackets ( 44 ) which, from one side, cut into the other's recesses. 11. Pull lock mechanism according to claim 10, characterized in that the brackets ( 44 ) project axially inwards from the movement control bushing ( 40 ) into incisions in the bearing sleeve ( 31 ). 12. Pull lock mechanism according to one of claims 1 to 11, characterized in that the rotatable driving sleeve ( 20 ) between the fixed movement control bushing ( 40 ) and the Lagerman sleeve ( 31 ) is arranged. 13. Pull lock mechanism according to one of claims 1 to 12, characterized in that the fixed bearing ( 30 ) eyelets ( 38 ) for receiving screws ( 56 ) for fastening the bearing ( 30 ) to the closure part. 14. Pull lock mechanism according to one of claims 1 to 13, characterized in that the bearing sleeve ( 31 ) carries a thread on the outside and is fastened to the closure part by a screw screwed onto this sleeve.