Patent Grant
8484895
This application claims Paris Convention priority of DE 10 2008 020 729.2 filed Apr. 25, 2008 the complete disclosure of which is hereby incorporated by reference.
The invention concerns a door configuration, comprising a door for opening and closing an access, wherein the door can be pivoted about an axis S relative to a main frame of the door configuration, wherein the door has a sliding door that is disposed on a casement of the door such that it can be displaced in a direction V, and wherein the casement can be pivoted about the axis S relative to the main frame.
Door configurations of this type are known e.g. from doors with sliding windows (see http:/www.woelfleder.at/tuere.htm, April 2008).
Door configurations are generally used to reversibly close an access, in particular, block, cover or seal it. A door configuration thereby comprises a movable part, in the present case called door, and a non-movable part, in the present case called main frame. The door is thereby movably disposed on the main frame. An access that can be closed by a door may e.g. be a passage into a room of a building, or also an engagement opening into a cabinet or a housing.
Folding doors are widely used, which are disposed on the main frame (e.g. a door frame or a wall unit) such that they can be pivoted about a (usually vertical) axis. The overall access that is covered by the door can be opened by pivoting the folding door. The door may be simply borne via hinges or joints. When a folding door is opened, a relatively large amount of space is required in front of the access as a pivoting area for the door.
In practice, it is often not required or not desired to open the entire access that can be closed by a door. In such cases, another, smaller door is conventionally integrated in a folding door. In former times, for example, town or castle gates often had so-called “manholes”. Such a manhole is merely a head-high folding door that is inserted into a door wing, through which individuals could pass. To allow passage of vehicles, the town or castle gate was completely opened. The further smaller door only opens part of the access that can be closed by the entire door. Operation of the further, smaller door is generally easier than opening the entire gate, and also requires a smaller amount of free space in front of the access.
The above-mentioned doors having sliding windows basically represent doors on which, in turn, a sliding door is supported for opening part of the access that can be closed by the entire door. The sliding door can be used without requiring any free space in front of the access, and can therefore be used, in particular, when space is limited.
The pivotable part of the door, on which the sliding door is disposed and with respect to which the sliding door can be moved, is called a casement in the present case.
Door configurations having a double function, i.e. a casement and sliding door function, conventionally have independent operating and locking mechanisms for each function. This results in a relatively complex construction, and frequent change between the functions makes handling complicated.
It is therefore the object of the present invention to improve the operating and locking mechanism of a door configuration of the above-mentioned kind having a casement and sliding door function and, in particular, simplify the construction and handling.
This object is achieved by a door configuration of the above-mentioned type, which is characterized in that a latch is provided for locking and unlocking the casement in its closed state with respect to the main frame, an operating element is disposed on the sliding door, which can be moved with the sliding door and can be switched over between a first position and a second position, wherein, in the first position of the operating element, the operating element does not obstruct movement of the sliding door on the casement, and movement of the sliding door does not influence the latch position, and wherein, in the second position of the operating element, the operating element engages in the latch or a carrier that is rigidly connected or hinged to the latch, such that, when the casement is closed, the latch is operated by moving the sliding door in the second position of the operating element.
The invention provides simple and reliable operation both of the casement function (pivoting or swinging open the casement or the entire door) and of the sliding frame function (movement of the sliding door when the casement is closed). The sliding door has an operating element that is preferably integrated in a handle that is supported on the sliding door. The operating element can be switched over between the first and the second position by a human operator (at least and preferably only when the casement is closed), e.g. by exerting a pressure onto the operating element.
In order to be able to operate the sliding door function, the operating element is in the first position. In this first position, the latch locks the casement such that it is maintained in the closed position. By manually laterally pulling the sliding door (or an associated handle), the sliding door can be moved with respect to the casement in order to open part of the access opening. The first position is the standard position for the operating element. The operating element is typically pretensioned in this first position.
In order to be able to operate the casement function, the operating element is switched into the second position. The latch is operated by a manual lateral pulling action on the sliding door and the sliding door is also moved with respect to the casement, but typically only within a narrow range (“unlocking path”). As soon as the latch is unlocked, the casement can be opened by pulling forward the sliding door.
The inventive door configuration realizes the mechanical change between the two operating modes of the door mechanism in the simplest fashion (sliding door function and folding door function). Only one operating element is required to handle the sliding door (or an associated handle). Operation of the different operating modes at the same time is preferably prevented by locking and blocking mechanisms, i.e. when the sliding door is opened, the folding door cannot be unlocked, and when the casement is open, the sliding door cannot be opened. In particular, switching over of the operating element from the first position to the second position is preferably blocked when the sliding door is not closed.
In accordance with the invention, the door with pivoting function (“folding door”) has an additional sliding door function. The overall access can be opened via the pivotable casement that also pivots the sliding door. This is useful, in particular, for moving large objects or persons through the access. When only a smaller part of the access is required, e.g. for moving only relatively small objects through the access, the sliding door function can be used while the casement is closed, wherein generally only a small part of the access is opened. The sliding door does, in particular, not require any free space in front of the access, such that in case of space shortage, it is not necessary to maintain a minimum separation from any oppositely disposed devices for the sliding door function. If the sliding door is narrow in the direction of displacement V, it can be displaced only in front of the access without requiring any free space. If a wider sliding door is used, space is required only on the sides of the access, which, however, often only minimally impairs the options of using the space.
In one preferred embodiment of the inventive safety housing, the closed sliding door covers the entire access that can be closed by the door when the casement is closed. In other words, the overall door is designed as a sliding door that can also be pivoted as a folding door. The casement can then be limited to its function as a bearing for the sliding door. In this case, it is not necessary to provide (partial) covers for the access on the casement.
In another embodiment, the sliding door extends in a direction perpendicularly to the direction V over the entire height of the access that can be closed by the door. In this case, the sliding door opens a maximum part of the access without requiring additional space in front of the access.
In a particularly preferred embodiment,
a partial cover for the access is rigidly mounted to the casement, and,
when the casement is closed and the sliding door is closed,
In one preferred further development of this embodiment, the first partial area extends approximately over half the width of the access parallel to the direction V when the casement and the sliding door are closed. The second partial area also extends over approximately half the width of the access (namely its other half). This opens a maximum part of the access by opening the sliding door without requiring free space next to the access.
In another preferred embodiment, the sliding door covers the access in a border area of the access remote from the axis S, when the sliding door and the casement are closed, and the sliding door can be slid open from its closed position towards the axis S. This reduces the bearing forces that act on the suspensions (hinges, pivot joints) of the casement when the sliding door is open. This is also facilitated by combined actuation of the casement and the sliding door by means of the same handle and operating element.
In one particularly preferred embodiment, in the second position of the operating element, a latch position associated with the closed sliding door locks the casement and a locked position associated with a moved sliding door releases the casement. In this embodiment, it is sufficient to operate only one single safety locking per door (with sliding and casement function) to secure access (with respect to both functions). The safety lock only needs to check or ensure that the sliding door is closed, since in this case, the folding door is inevitably also locked.
In a preferred further embodiment, the range of movement of the sliding door away from the closed position in the second position of the operating element is defined by a mechanical stop to an unlocking path EW which is shorter than the maximum sliding path SW of the sliding door on the casement in the first position of the operating element, in particular, wherein EW≦0.2*SW, and in particular wherein EW≦5 cm. The mechanical stop marks a sliding door position in which the latch is unlocked. Any further unnecessary and tedious movement of the sliding door is avoided. When the casement is displaced, the sliding door is largely closed such that the sliding door does not obstruct opening of the casement.
In a preferred further development of this embodiment, a locking mechanism is provided on the door, which blocks movement of the sliding door out of the position of movement of the sliding door on the mechanical stop when the casement is not closed and when the operating element is located in the second position, in particular, wherein a movable locking element is provided on the casement, which is pretensioned by a spring force into a locking position, in which it blocks the movement path of the operating element or of the latch or the carrier in the second position, and is moved out of the path of movement of the operating element or the latch or the carrier in the second position when the casement is closed through interaction with a counter means that is rigidly formed on the main frame. This further development prevents operating errors of the door mechanism (in particular locking mechanism). The latch that is operated via the operating element remains in the unlocked position when the casement is opened in order to ensure smooth closing of the casement. The sliding door is typically blocked on the mechanical stop through positive fit with a locking element that is movably disposed on the casement. This positive fit may be realized in the simplest form directly with the operating element, or also with the latch or any carrier, which are respectively coupled to the operating element, thereby blocking the sliding door.
In a further development, a blocking mechanism is alternatively or additionally provided, which blocks a movement position of the sliding door on the mechanical stop. This also prevents operating errors of the door mechanism.
The blocking mechanism comprises e.g. a resilient ball in the casement, which engages in a recess on the latch to provide a resistance to movement of the sliding door, which is very easy to realize.
In another example, the blocking mechanism is provided by a third position of the operating element, in which a holding element of the casement blocks movement of the operating element, in particular, wherein the operating element is driven by the force of a spring from the second position into the third position and in particular, wherein the third position is formed between the first and the second position.
In a particularly preferred embodiment, a guidance is provided on the casement, which holds the operating element in the second position when the sliding door is moved out of its closed position, when the operating element is in the second position, and which only permits changing between the first and the second position when the sliding door is closed. This also prevents operation errors of the door mechanism (in particular locking mechanism). In particular, when the casement is open, the sliding door cannot be normally moved (i.e. as in the first position of the operating element).
In a preferred further development thereof, the guidance comprises a recessed rail along which the operating element (in the second position) can be guided within a notch in the operating element. The recessed rail has a widening through which the operating element can be displaced between a first and a second position when the sliding door is closed. The guidance can thereby be realized in a very simple mechanical fashion. The widening is typically provided at one end of the recessed rail.
In another preferred embodiment, the operating element comprises a pin that can be retracted and extended and is pretensioned by a spring force into a retracted position which corresponds to the first position of the operating element, and which can be pushed by hand into an extended position which corresponds to the second position of the operating element. This simplifies utilization of the sliding door function that is normally used more often, and inadvertent activation of the folding door function is impeded.
In another preferred embodiment, the latch is disposed on the casement such that it can be displaced in a direction R, wherein the direction R and the direction V extend parallel to each other. Bearing and guiding the latch on the casement facilitates control of the operating element by the latch.
In an alternative fashion, the latch may also be disposed on the main frame such that it can be displaced in a direction R′, wherein the direction R′ and the direction V extend parallel to each other when the casement is closed. This facilitates a particularly robust design of the latch mechanism.
In another preferred embodiment, a lock is provided on the main frame, which blocks and releases the position of movement of the sliding door when the casement and the sliding door are closed. Any opening of the door, i.e. of the casement or the sliding door, requires movement of the sliding door out of its closed position. For this reason, one single lock is sufficient (that secures the position of movement of the sliding door) for locking the entire door including both functions.
In a further preferred embodiment, the direction V, in which the sliding door can be moved with respect to the casement, extends perpendicularly to the axis S. This has turned out to be useful in practice, in particular, in that the overall motion for opening the casement is facilitated. The axis S typically extends in a vertical direction and the direction V extends in a horizontal direction.
In another preferred embodiment, the casement has the shape of a C, wherein the open side of the C-shaped frame faces away from the axis S. This improves accessibility to the working chamber, in particular, in case of a double-wing door configuration.
Finally, in another particularly preferred embodiment, two adjacent doors are provided, wherein the two doors form two opposite wings of a double door, in particular, wherein the door protection elements of the two doors overlap. The partial areas of the accesses to the working chamber, which are opened in each case by sliding door functions, can then be used together.
The door (i.e. the casement including sliding door) of an inventive door configuration is also preferably designed such that it can be unhinged, e.g. by means of hinges on the main frame, out of which the door can be lifted. This facilitates assembly and transport of the door configuration components.
Further advantages of the invention can be extracted from the description and the drawing. The features mentioned above and below may be used in accordance with the invention either individually or collectively in arbitrary combination. The embodiments shown and described are not to be understood as exhaustive enumeration but have exemplary character for describing the invention.
The invention is illustrated in the drawing and is explained in more detail with reference to embodiments.
a shows a schematic perspective view of a cabinet-like housing with two inventive door configurations, with two doors with closed casement and closed sliding door;
b shows the cabinet-like housing of
c shows the cabinet-like housing of
a to 3d show schematic views of the process of changing the operating modes of a door of an inventive door configuration;
e shows a schematic view similar to
a shows a schematic sectional view of a locking mechanism of a door of an inventive door configuration in a first position of the operating element;
b shows the locking mechanism of
c shows the locking mechanism of
a shows a schematic view of a further locking mechanism of a door of an inventive door configuration with an unlocked locking element with closed casement;
b shows the locking mechanism of
a through 1c each show a cabinet-like housing, on which two inventive door configurations 1a, 1b are formed. In this example, the cabinet-like housing is designed as a safety housing 1 for an X-ray apparatus, e.g. an X-ray diffractometer or an X-ray fluorescence analysis device or a different instrumental-analytical X-ray measuring means (not shown). The safety housing 1 surrounds a working chamber 2 inside the safety housing 1, in which the X-ray apparatus can be disposed. The safety housing 1 has a plurality of stationary protection elements 3a-3c, which are impermeable to X-ray radiation, e.g. lead-containing side walls 3a, ceiling plates 3b and floor plates 3c.
The working chamber 2 has a front access 4 (
The doors 6a, 6b have two functions. Each door 6a, 6b has a (in the present case C-shaped) casement 7a, 7b which is pivotably disposed on a stationary main frame 9 of the safety housing 1 via hinges 8 (see pivot axes S). Each casement 7a, 7b, in turn, bears one sliding door 10a, 10b, which can be moved on the casements 7a, 7b, respectively (see direction of movement V). Each sliding door 10a, 10b has a handle 11 that has a manually operable push button 12 of an operating element for actuating the latch. The main frame 9 can be associated with the respective door configurations 1a, 1b as far as it is used to suspend the doors 6a, 6b. The main frame 9 typically also completely surrounds the access 4.
a shows the safety housing 1 with closed sliding doors 10a, 10b and closed casements 7a, 7b, as required during X-ray measurement for shielding the X-ray radiation that is released in the working chamber 2. In order to perform minor manipulations in the working chamber 2, e.g. change the sample, it is sufficient to only open the two sliding doors 10a, 10b, thereby opening approximately half of the width of the maximum access 4 (
For lager-scale manipulation, e.g. exchange of the X-ray apparatus, in the working chamber 2, the casements 7a, 7b can be pivoted open, wherein the (largely) closed sliding doors 10a, 10b are also pivoted and the overall maximum access 4 is opened (
The door mechanism preferably permits movement of the sliding doors 10a, 10b only when the casements 7a, 7b are closed and vice versa, the casements 7a, 7b can only be pivoted when the sliding doors are (largely) closed.
In the illustrated embodiment, each door protection element 5a, 5b extends over the full width B and the full height H of the area of the access 4 that is covered by the associated door 6a, 6b.
The door 6a has a rectangular casement 7a (shown in hatched lines, the covered inner border is shown with dashed lines), which is mounted by hinges 8 to the main frame (not shown) of the door configuration 1a and can be pivoted about a vertical pivot axis S.
In this case, a door protection element (that can also be called rigid partial cover 21) is rigidly mounted to the casement 7a with rivets 22. Two rails 23 are also mounted to the casement 7a, which extend over the entire width B of the door 6a and are used as a bearing for a sliding door 10a. The sliding door 10a can be moved on the rails 23 in the direction V. The sliding door 10a has a door protection element 5a (that can also be called movable partial cover), which can be moved with the sliding door 10a. The sliding door 10a can be handled via the handle 11.
In
When the sliding door 10a is moved to the left out of the closed position, the access to the working chamber is opened in the right-hand partial area RTB. Towards this end, the sliding door 10a does not require any free space on the side of the door (e.g. on the left-hand side of the door) or in front of the door 6a, since the sliding door 10a can be easily moved in front of the rigid door protection element 21. When full access via both partial areas RTB, LTB is required, the casement 7a can be pivoted open.
a-3d schematically explain a door mechanism, in particular a latch mechanism, which is used in accordance with the invention in an inventive door configuration 1a. Different operating states are thereby schematically shown in cross section.
a shows in a first operating mode (sliding door function) a door with a casement 7a, which is pivotably mounted by means of hinges (pivot joints) 8 to a main frame 9 (shown in dashed lines). A sliding door 10a is disposed (borne) on the casement 7a, which can be displaced in the direction V parallel to the casement 7a. An operating element 31 in a first (extended) position does thereby not impair the movement of the sliding door 10a. The sliding door 10a can be moved by a maximum path of displacement SW (in
The casement 7a, however, is locked. A latch 32, which is disposed on the casement 7a such that it can be displaced in a direction R, engages at its right end in a (schematically shown) lug 33 of the main frame 9 such that the casement 7a cannot be pivoted open.
b shows a first phase of switching over the operating modes. When the sliding door 10a is closed (i.e. the sliding door 10 is on the very right) the operating element 31 is inserted. The operating element 31 penetrates through the casement 7a in this second position and engages in a recess 32a of the latch 32 such that the movement of the latch 32 is coupled to the movement of the sliding door 10a.
c shows the second phase of switching over the operating modes. When the operating element 31 is inserted, the sliding door 10a including operating element 31 is slightly moved to the left by the amount EW (unlocking path) until the latch 32 contacts the mechanical stop 34. The carried-along latch 32 is thereby removed from the lug 33, thereby unlocking the casement 7a. It must be noted that the unlocking path EW thereby amounts to approximately ⅕ of the maximum sliding path SW.
d shows the second operating mode (folding door function) of the door. The casement 7a can be pivoted about the hinge 8. The operating element 31 thereby typically remains in the second position and the sliding door 10a is preferably locked in the movement position on the mechanical stop 34 when the casement 7a is opened (
e shows an alternative inventive door mechanism similar to
a through 4c show the door locking mechanism of an inventive door configuration in greater detail, which is inserted into a safety housing similar to
Each section shows one sliding door 10a, to which a handle 11 with an inserted substantially pin-shaped operating element 31 (with push button 12) is mounted. The sliding door 10a is displaceably disposed on a casement 7a by means of a rail (linear guidance) 23. The casement 7a abuts a main frame 9 that is stationary during all door operations. A carrier 41 is disposed in the casement 7a, which can be displaced in a direction R. The carrier 41 is rigidly connected to a latch 32 that can engage behind a hook (only indicated by reference numeral 42) that is fixed to the main frame 9. The carrier 41 has a recess 41a for engagement of the operating element 31. An actuator 43 is moreover rigidly connected to the sliding door 10a and can engage in a lock (in the present case a safety module) 44.
a initially shows the sliding door function. The operating element 31 is in a first position in which it does not engage in the recess 41a. The operating element 31 is thereby pretensioned into this first position by a pressure spring 45. The sliding door 10a can then be freely moved on the casement 7a in the direction V.
The latch 32 engages behind the hook 42, such that the casement 7a is locked on the main frame 9 and, in particular, cannot be pivoted open to the front.
In the position of the sliding door 10a shown in
b illustrates the first step for switching over the operating mode. When the sliding door 10a is closed, the operating element 31 is pushed in against the spring force. In this second position, the front end of the operating element 31 engages into the recess 41a of the carrier 41. A widening 46 in the recessed rail 47 is thereby penetrated, which is formed on the casement 7a (see
The engaging operating element 31 couples the motions of the sliding door 10a and the carrier 41 and thereby also of the latch 32. When the sliding door 10a is moved to the left with the operating element 31 in the second pushed-in position, the latch 32 is carried along by the carrier 41 such that the casement 7a is unlatched. The directions R and V are parallel.
c shows the door mechanism with the sliding door 10a moved to the left and retracted latch 32, i.e. with unlocked casement 7a. The notch 48 in the operating element 31 engages the recessed rail 47. The operating element 31 can be displaced along the recessed rail up to abutment with the left-hand side at the end of the recessed rail 47, which accordingly functions as a mechanical stop 49 (“unlocked position of movement”). The mechanical stop 49 delimits the unlocking path EW of the sliding door 10a (it must be noted that as an alternative or additionally, the carrier 41 or the latch 32 could also be moved to a corresponding mechanical stop). Since the recessed rail 47 engages in the notch 48, the operating element 31 cannot move back from the second pushed-in position.
In the unlocked position of movement of the sliding door 10a, the actuator (the safety bracket) 43 is completely removed from the lock (safety module) 44. For this reason, the actuator 43 no longer obstructs opening of the casement 7a. It may be required to initially unlock the lock 44 for moving the sliding door 10a into the unlocked position of movement.
The sliding door 10a is fixed in the position of movement abutting the mechanical stop 49 by a blocking mechanism. In the illustrated example, the blocking mechanism has two resilient balls 50 that are formed on the casement 7a and engage in depressions (not shown in detail) on the latch 32. In order to move the sliding door 10a (and thereby also the latch 42) with respect to the casement 7a out of the unlocked position of movement, the mechanical resistance of the resilient balls (pressure balls) 50 must be overcome. This secures handling of the handle 11 for opening and closing the casement 7a, in particular when the casement 7a is open.
After pivoting the casement, e.g. for exchanging an X-ray apparatus in the working chamber of the safety housing, the casement 7a is disposed again at the main frame 9 (is closed), and the sliding door 10a is moved from its unlocked position of movement on the left-hand side mechanical stop 49 back to the locked (completely closed) position of movement on the right-hand side mechanical auxiliary stop 49a. The latch 32 is thereby carried along, which finally locks again the casement 7a on the main frame 9. In the completely closed position of the sliding door 10a, the operating element 31 moves back into the first position due to the pressure spring 45, and thereby into the sliding door mode.
Securing the unlocked position of movement of the sliding door in the folding door mode may alternatively or additionally not only be impeded but also be mechanically locked by a locking mechanism, which is illustrated in
The casement 7a has an approximately cylindrical locking element 51, which is disposed in a depression 52a and extends through a bearing bushing (guiding bushing) 52b. The bearing bushing 52b is glued into the depression 52a or fastened in a different mechanical fashion (e.g. screwed). The locking element 51 is pretensioned by a pressure spring (not shown in detail) at an inside 53 of the locking element 51 into a position projecting towards the main frame 9 (see
When the casement is closed (i.e. applied to the main frame 9, see
In summary, the present invention describes a door configuration for locking an access with a door, wherein the door configuration has a double frame system which permits both a pivoting function and a sliding function of the door. This double function saves space in front of the access when only the sliding door function is used. Both functions can be operated via one single operating element via the sliding door, wherein slight movement of the sliding door in a second position of the operating element is used to operate a latch (or a latch system with several individual latches). This achieves high operational comfort and simple construction. In particular, no external tools or auxiliary means are required for switching over between the functions. When the sliding door function is activated, the folding door function is mechanically locked, and when the folding door function is activated, the sliding door is mechanically locked. The access can be secured by one single lock.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2008 020 729 | Apr 2008 | DE | national |
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| Number | Date | Country | |
|---|---|---|---|
| 20100107499 A1 | May 2010 | US |
