This application is a national stage application, filed under 35 U.S.C. ยง 371, of International Patent Application No. PCT/DE2019/000267, filed on Oct. 13, 2019, which claims the benefit of German Patent Application No. 10 2018 008 201.7, filed Oct. 14, 2018.
The disclosure relates to a retraction device for two end positions having two driving elements which are connected to one another by a spring energy accumulator, wherein each driving element is displaceably mounted in a respective guide housing. The disclosure further relates to a sliding door having such a retraction device and to a sliding door arrangement having such a sliding door.
Such a device is known from DE 10 2008 009 046 A1. Unique cylinder-piston units are required to accommodate sliding doors of different widths, one for each width.
The present disclosure is based on the problem of developing a retraction device for two end positions, which can be used for a range of door widths without design modifications.
This problem is resolved with the features of the main claim. For this purpose, each driving element is coupled or can be coupled to a cylinder-piston unit mounted in the respective guide housing. Both guide housings are adjustable relative to one another in the longitudinal direction of the retraction device by at least one sliding joint.
The retraction device has two cylinder-piston units and two guide housings. One cylinder-piston unit is mounted in each guide housing. Each of the two driving elements can be moved in each guide housing between a parked position and an end position. The individual driving element is coupled or can be coupled to an individual cylinder-piston unit. When the driving element moves from the parked position in the direction of the end position, such movement is decelerated or damped by the cylinder-piston unit. The deceleration or damping force is superimposed by the force of an unloading spring energy accumulator. Such spring energy accumulator is located between the two driving elements.
The two guide housings are adjustable relative to one another. For this purpose, the two guide housings are connected to one another by at least one sliding joint. Thereby the retraction device can be easily adapted to different door widths without the operator feeling any significant change in the amount of force required to operate the sliding doors.
Further details of the invention are given in the subclaims and the following description of schematically illustrated embodiments.
The retraction device (20) has a device body (40) on which, in the exemplary embodiment, a guide carriage (31; 32) is arranged at each of the two ends oriented in the longitudinal direction (25). The respective guide carriage (31; 32) may be screwed to the fixture body (40) by screws (33). The retraction device (20) can also be formed without a guide carriage (31, 32). In this case, the device body (40) may be fastened directly to a sliding door leaf (6) of the sliding door (5). It is also conceivable to form the retraction device (20) for combination with different types of guide carriages (31, 32).
Each of the guide carriages (31, 32) shown in
The device body (40) has two guide housings (41, 61), in each of which a driving element (71; 91) is guided. In the exemplary embodiment, the two guide housings (41, 61) are formed to be identical to one another. In the device body (40), they are arranged in mirror image to a vertical center transverse plane. The two driving elements (71, 91) both project upwards from the device body (40) in the illustrations of
The individual guide housing (41; 61) comprises two guide shells (42, 43), which encompass the respective driving element (71; 91) in certain areas. In the exemplary embodiment, the joint (49) of the two guide shells (42, 43) lies in a vertical central longitudinal plane. Each of the guide shells (42; 43) has a guide track (51) for guiding the driving element (71; 91). The two guide shells (42, 43) are structured to be, for example, mirror-symmetrical to one another.
A mounting profile (131; 151) is fastened to the individual guide housing (41; 61), for example by mounting screws (132). In the exemplary embodiment, this is largely formed in a U-shape. For example, it is a drawn aluminum profile. It encompasses the lower side of the respective guide housing (41; 61). In the exemplary embodiment, the respective guide carriage (31; 32) is fastened in the mounting profiles (131, 151). For example, the length of the individual mounting profile (131; 151) is 37% of the length of the device body (40).
In the exemplary embodiment, a push profile (141) is arranged between the two mounting profiles (131, 151). The cross-section of the push profile (141) corresponds, for example, to the cross-section of the mounting profiles (131, 151). In the illustrations of
In the exemplary embodiment, the tension spring (161) has an installation length in the position of the driving elements (71, 91) shown in
A cylinder-piston unit (101; 121) is further mounted in the individual guide housing (41; 61). In the exemplary embodiment, this is a hydraulic cylinder-piston unit (101; 121). However, the retraction device (20) can also have two pneumatic cylinder-piston units (101; 121). It is also conceivable to use two cylinder-piston units (101; 121) operated with different media.
The individual cylinder-piston unit (101; 121) comprises a cylinder (102), in which a piston (104) movable by a piston rod (103) is mounted. The piston (104) has, for example, longitudinal channels, which can be at least largely closed, for example, by a throttle disk that can be lifted off and is turned towards the displacement chamber (106). In the cylinder (102), the piston (104) separates the displacement chamber (106) from a compensation chamber (108). In the compensation chamber (108), a compensation sealing element (109) is spring-loaded and displaceably mounted in the cylinder-piston unit (101; 121).
In the illustration of
The cylinder-piston unit (101; 121) can also be arranged in the guide housing (41; 61) in such a manner that the cylinder base (113) faces the driving element (71; 91). It can be connected to the driving element (71; 91). The cylinder (102) is then displaceably mounted in the guide housing (41; 61). In this case, the piston rod (103) rests against or is connected to the rear wall (44) of the guide housing (41; 61). The cylinder-piston unit (101; 121) can be designed as described above. With such an arrangement, transverse forces on the piston rod (103) can be largely avoided.
In
The individual housing shell (42; 43) has a cylinder holder (48) adjacent the rear wall (44) and a guide track (51). For example, a center line of the cylinder holder (48) oriented in the longitudinal direction (25) is aligned with a horizontal center plane of the guide track (51). In the lower area, the rear wall (44) has a rear wall opening (45).
The guide track (51) has a horizontal section (52) and a downwardly curved section (53) adjoining it. A tangent to the center line of the curved section (53) encloses an angle of, for example, 100 degrees with the center line of the horizontal area (52). The guide track (51) embossed in the housing shell (42; 43), for example, can also be formed as a guide slot. In this case, for example, the upper limit of the guide track (51) can be omitted, at least in certain areas.
In the area turned away from the piston rod head holder (75), the driving element (71; 91) has two coaxially aligned guide sticks (77) extending on opposite sides from the driving element (71; 91). These project laterally from the driving element (71; 91). In the exemplary embodiment, both guide sticks (77) are formed to be cylindrical and have a circular cross-section.
On its upper side (78), the driving element (71; 91) has two driving hooks (79, 81). Such driving hooks (79, 81) bound a driving recess (82) located between them. The driving hook (79) turned away from the piston rod head holder (75) is referred to below as a pull hook (79). The pull hook (79) is formed to be elastically deformable for an external load. The other driving hook (81) is referred to below as a push hook (81).
The driving element (71; 91) can also be formed with a swiveling or lowerable pull hook (79). For example, the guide track (51) or the guide slot can then be designed without a curved section. The pull hook (79) then slides along a guide ramp in certain areas, for example.
On its lower side, the driving element (71; 91) has the spring holder (74; 94). This is formed in a fork shape, for example. For example, it is arranged below the piston rod head holder (75).
When assembling the retraction device (20), for example, the cylinder-piston units (101; 121) and the driving elements (71; 91) coupled to the piston rod heads (111) are initially inserted into a guide shell (42; 43). Thereby, the guide pins (112) and the guide sticks (77) are inserted into the guide tracks (51). The tension spring (161) can be hooked into the spring holder (74; 94) of a driving element (71; 91). Now, both guide housings (41, 61) can be closed by fitting the second guide shell (43; 42).
For example, in a next step, both guide housings (41, 61) are inserted into the push profile (141) in such a manner that the rear walls (44) face one another. The tension spring (161) can now be guided within the push profile (141) to the second driving element (91; 71). There, the tension spring (161) is hooked into the spring holder (94; 74) of the second driving element (91; 71).
Next, the mounting profiles (131; 151) are pushed onto the guide housings (41; 61), for example from the outside, and fastened by means of the mounting screws (132). A guide carriage (31; 32) is inserted into each mounting profile (131; 151) and fastened by the screws (33). Another sequence of assembly is also conceivable.
Fastening bolts, for example, are inserted into the fastening apertures (36) of the guide carriages (31; 32). The retraction device (20) prepared in this way is then inserted, for example, into a door guide rail (7) on the frame side, such that the fastening bolts project downwards. The sliding door leaf (6) is attached to the fastening bolts. This, for example, has a mass between 120 kilograms and 160 kilograms. If the distance between the fastening bolts is shorter than the distance between the bolt receptacles provided on the sliding door leaf (6), the retraction device (20) can be pulled apart telescopically for adjustment, see
Together with the two guide housings (41; 61), the push profile (141) forms two sliding joints (142, 143).
The individual sliding joint (142; 143) can also have a cylindrical cross-section. It is also conceivable to couple both guide housings (41; 61) to one another in a sliding joint (142; 143). With one such embodiment, the telescoping retraction device (20) can be formed with an individual sliding joint (142; 143).
The individual sliding joint (142; 143) can be lockable in the longitudinal direction (25). Thereby, the sliding joint (142; 143) can be fixed in steps or in stepless form at least secondarily. In the case of locking in steps, the individual prism (144; 145) can engage in recesses in the joint partner (145; 144), for example, by means of a spring-loaded ball, latching elements, etc. In the case of stepless adjustment of the sliding joint (142; 143), this can be locked, for example, by a wedge-shaped mounting aid, a friction surface, molded-on ribs or by means of a screw drive. It is also conceivable to fix the sliding joint (142; 143), for example, by a fixing screw screwed into the push profile (141). For example, a pair of cylindrically shaped elements can be fixed in place by a clamping nut overlapping the hollow prism (144). The use of clamping elements, bayonet connections, quick-locking elements, intermediate buffers, etc. is also conceivable.
With such an embodiment, the length of the retraction device (20) can be adapted to the length of the sliding door leaf (6) before it is mounted in the frame. After inserting the retraction device (20) into the door guide rail (7) on the frame side, the sliding door leaf (6) can be attached to the retraction device (20) and fastened without any further adjustment work.
It is also conceivable to insert the sliding door leaf (6) together with the retraction device (20) fastened to it into the door guide rail (7) on the frame side. Due to the telescopic retraction device (20), the retraction device (20) shown in the exemplary embodiment can be used, for example, for sliding doors (5) whose length is up to 1.15 times a nominal length. Thereby, the nominal length of the sliding door (5) is determined by the basic length of the retraction device (20) in the retracted position, see
After the sliding door (5) has been mounted in the door frame (4), the driving elements (71; 91) have, for example, the position shown in
When the sliding door (5) is closed for the first time, the sliding door leaf (6) with the retraction device (20) seated on it is moved in the closing direction (11). The driving element (91; 71), which is on the right in the illustrations of
When the sliding door (5) is opened for the first time, the sliding door (5) pulls the guide housing (61; 41) relative to the driving element (91; 71) in the opening direction (12). The driving element (91; 71) moves along the guide track (51). The piston rod (103) of the cylinder-piston unit (121; 101) is extended or moves out under spring load. Thereby, for example, oil is displaced from the compensation chamber (108) into the displacement chamber (106). Due to the low spring rate of the tension spring (161), the operator experiences only slight resistance. For example, the force to be applied by the operator is less than 60 newtons. As soon as the guide sticks (77) of this driving element (91; 71) reach the curved section (53), the driving element (91; 71) is pivoted around the piston rod head (51) with the guide pins (112). The driving element (91; 71) is released from the driver (8). It is secured in a parked position (93; 73) in a force-fitting and/or positive-locking manner. Due to the low forces, the operator does not experience a jump in force.
The retraction device (20) is now in the position shown in
The sliding door (5) can now be opened further in the opening direction (12) to an open end position (3). When first opened, the driver (9) shown on the left in
When the sliding door (5) is closed again, the guide housing (41) shown on the left moves relative to the driving element (71; 91) held by the driver (9) shown on the left. The piston rod (103) of the cylinder-piston unit (101; 121) shown on the left is extended or is pushed out by the return spring. As soon as the driving element (71; 91) has reached its parked position (73; 93), the driver (9) is decoupled.
For example, during further closing, the driving element (91; 71) shown on the right contacts the driver (8) arranged adjacent to the vertical frame (13) for the closed sliding door. The driving element (91; 71) shown on the right is released from the parked position (93; 73). The driving element (91; 71) loads the piston rod (103) of the cylinder-piston unit (121; 101) shown on the right. The piston (104) is retracted, wherein, for example, oil is displaced from the displacement chamber (106) into the compensation chamber (108) in a throttled manner, for example. The closing of the sliding door (5) is delayed. At the same time, the tension spring (161) is relieved. The acceleration force of the spring energy accumulator (161) and the deceleration force of the cylinder-piston unit (121; 101) are superimposed. The sliding door (5) is slowly pulled into the closed end position (2). It stops there. In the retraction device (20), the driving element (91; 71) shown on the right is now again in the end position (92; 72), while the other driving element (71; 91) remains in the parked position (73; 93).
When opening in the direction of the open end position (3), in a partial stroke of the total stroke (15) of the sliding door (5) adjacent to the open end position (3), the driving element (71; 91) shown on the left engages with the driver (9) adjacent to the vertical frame (14) for the open sliding door (5). When this open end position (3) is approached, the sliding door (5) is braked in the same way as when the closed end position (2) is approached. It thus moves in a controlled manner to the open end position (3).
The retraction device (20) can also be arranged on the frame side. Two drivers are then arranged on the sliding door, for example. In this case, for example, the guide housings (41: 61) face one another with their end faces turned away from the rear wall (44). In the cylinder-piston units (101, 121), the displacement chamber (106) is located between the piston (104) and the cylinder head (114). The tension spring (161) is guided, for example, around two deflection rollers arranged on the rear walls (44). Thus, the respective parked positions (73; 93) of the retraction device (20) are on the inside and the end positions (72; 92) are on the outside. The function of such a retraction device is as described above.
The sliding door (5) can also be electrically driven or can have an assisting electric drive. This can be used both when opening and closing the sliding door (5).
Combinations of the individual exemplary embodiments are also conceivable.
2 Closed end position
3 Open end position
4 Door frame
5 Sliding door
6 Sliding door leaf
7 Guide rail, door guide rail
8 Driver
9 Driver
11 Closing direction
12 Opening direction
13 Vertical frame for the closed sliding door
14 Vertical frame for the open sliding door
15 Door stroke
20 Retraction device
25 Longitudinal direction
26 Transverse direction
27 Height direction
31 Guide carriage
32 Guide carriage
33 Screws
34 Carrier part
35 Pair of rollers
36 Fastening aperture
40 Device body
41 Guide housing
42 Guide shell, housing shell
43 Guide shell, housing shell
44 Rear wall
45 Rear wall opening
46 Lower side
47 Fastening holes
48 Cylinder holder
49 Joint
51 Guide track
52 Horizontal section
53 Curved section
61 Guide housing
71 Driving element
72 End position
73 Parked position
74 Spring holder
75 Piston rod holder, piston rod head holder
76 End face
77 Guide pins
78 Upper side
79 Driving hook, pull hook
81 Driving hook, push hook
82 Driving recess
83 Outer side of (79)
91 Driving element
92 End position
93 Parked position
94 Spring holder
101 Cylinder-piston unit
102 Cylinder
103 Piston rod
104 Piston
106 Displacement chamber
108 Compensation chamber
109 Compensation sealing element
111 Piston rod head
112 Guide pin
113 Cylinder base
114 Cylinder head
121 Second cylinder-piston unit
131 Mounting profile
132 Mounting screws
133 Gaps
141 Push profile
142 Sliding joint
143 Sliding joint
144 Hollow prism, part of a pair of prisms
145 Solid prism, part of a pair of prisms
151 Mounting profile
161 Spring energy accumulator, tension spring
Number | Date | Country | Kind |
---|---|---|---|
10 2018 008 201.7 | Oct 2018 | DE | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/DE2019/000267 | 10/13/2019 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/078496 | 4/23/2020 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
10151130 | Wang | Dec 2018 | B2 |
10738523 | Wang | Aug 2020 | B2 |
20100037525 | Sato | Feb 2010 | A1 |
20110023370 | Zimmer et al. | Feb 2011 | A1 |
20160369547 | Sato | Dec 2016 | A1 |
20170051548 | Wang | Feb 2017 | A1 |
Number | Date | Country |
---|---|---|
202170702 | Mar 2012 | CN |
102008009046 | Sep 2009 | DE |
202017100244 | Mar 2017 | DE |
102017100250 | Jul 2018 | DE |
2008190275 | Aug 2008 | JP |
2017014761 | Jan 2017 | JP |
Number | Date | Country | |
---|---|---|---|
20210381293 A1 | Dec 2021 | US |