Sliding door system

Description

BACKGROUND AND SUMMARY OF THE INVENTION

The invention relates to a sliding door system with at least one motor drive sliding door wing, and comprising a running mechanism with a drive motor, control devices, circulating drive belt guided over deflection rollers, drivers for the connection of the drive belt and wing, a latching system, and motion sensors and the like.

Known door drives, such as, for example, the automatic sliding door drive described in DE-OS 36 02 567, are put together from a plurality of components, such as electrical motor, electronic control unit, carrier with running mechanism, latching device etc. The individual components are arranged alongside one another on a spatially fixed horizontal beam. The arrangement takes place essentially in a common vertical plane in the vicinity of the beam. Thus, a relatively large constructional height results. Furthermore, the cost of installation is mainly relatively high, because the individual components must each be arranged individually on the carrier via their own mounting devices.

DE-OS 38 23 188 describes a sliding door system with an electrical drive motor, which is secured on the housing of the running rail. For this purpose, a dove-tail section is formed on the upper side of the running rail housing, into which the drive and control devices can be slid and can be fixed via a clamped mounting. In this known design the drive motor is in each case arranged vertically above the drive rail, whereby in practice only restricted possibilities of installation offer themselves.

In DE GM 93 02 490, the installation of the drive motor takes place in a similar manner via an adapter section for the optional mounting vertically above the running rail or horizontally at the side thereof. The adapter section can be fixed with clamping screws in the dove-tail arranged at the upper side of the running rail housing.

The object of the invention is to develop a sliding door system which has a drive with a compact construction and a low constructional height.

The object is satisfied in accordance with the invention by providing an arrangement wherein the drive and control devices are arranged in a receiving space which adjoins the running mechanism at the front side, with the receiving space and the running mechanism forming an assembled, substantially parallelepiped shaped body, the lower edge of which extends up to or engages over the upper edge of the wing, and the vertical constructional height of which is determined by the cross-section of the drive motor and/or by the vertical constructional height of the running mechanism and the horizontal constructional depth of which is at least twice as large as the vertical construction height. The drive is thus a compact, parallelepiped-shaped body with a low constructional height. It consists of a running mechanism and a receiving space, with drive and control devices arranged therein. All drive and control devices of the drive, i.e. of the sliding door system, are preferably arranged in the receiving space. In this respect the receiving space has approximately the same-sized cross-section as the running mechanism and both preferably have the same axial length, which extends over the entire door width. This drive can, as a result of its compactness and low constructional height, be built into a facade, for example a post/transom design, with optical advantages. The drive designed as a body in the shape of a parallelepiped preferably has approximately the same or identical constructional height as the cross-beam of the facade design, i.e. the transom. In preferred embodiments the constructional height of the drive amounts to 7 cm. Customary transoms are mainly 6 to 7 cm high.

The vertical constructional height of the parallelepiped shaped body forming the drive is preferably of the same size as the vertical constructional height of the running mechanism or of a section forming the housing of the running mechanism. This vertical constructional height can alternatively or additionally be of the same size as the diameter of the drive motor, preferably with the transmission and the drive pulley at the output side.

The running mechanism can be formed as an overhung element or can also be secured to a beam. In particular, when mounted on a beam, the running mechanism can also be divided into two in its axial extent. One sliding wing is guided via roller carriages in each of the two parts, with a cutout for the insertion of the roller carriages preferably remaining at the centre between the two parts.

The running mechanism or the carrier is secured to posts of a post/transom design, or to a transom of a facade. In this respect the running mechanism, i.e. the carrier, has approximately the same height as the transom, or can also be of fractionally greater height. The installation is made easier when the running mechanism or the carrier has a horizontal limb which lies on the transom. In an alternative embodiment, the running mechanism, i.e. the carrier, can also replace the transom.

In a preferred embodiment, the running mechanism has a box-like running mechanism section with two vertical limbs. The one vertical limb is hung into a carrier via a hanging device and is connected to the latter via a clamping device. The running mechanism and the carrier are in this design arranged behind one another when viewed from the front side of the door and lie with their respective front surfaces contacting. The other front side of the vertical limb has a horizontally extending, longitudinal groove of C- or T-like form, in which the drive and control elements are secured by clamping blocks with clamping screws. The mounting apparatus is designed in such a way that the drive and control devices can be variably placed therein, individually or in constructional groups. The clamping blocks are inserted from the side into the mounting groove, or are inserted into corresponding cutouts. The groove preferably extends at half the height of the running mechanism section. In alternative embodiments a plurality of mounting grooves can be arranged in parallel and/or displaced relative to one another in the longitudinal direction of the running mechanism section.

The receiving region in which the drive and control elements are located is surrounded by a cover hood, the upper edge of which is aligned with the upper edge of the running mechanism section and the lower edge of which lies beneath the upper edge of the sliding wing. Thus, a very compact housing arises, which is box-like on the whole, with a width which is approximately 2 to 3 times the height, consisting of a running mechanism section and the receiving region attached thereto, with at least the receiving region being covered over by the cover hood.

A driver, which connects the wing to a drive belt driven by the motor, is passed through between the running mechanism section and the receiving region for the drive and control elements. For this purpose the front side vertical limb of the running mechanism section is preferably of shorter design when compared to the second vertical limb. The drive belt driven by the motor is guided in a horizontal plane beneath the remaining drive units via deflection rolls with a vertical axis of rotation. In this arrangement the drivers likewise extend in a horizontal plane from the upper edge of the wing to the drive belts, with the upper edge of the wing lying at least approximately in the same horizontal plane as the drive belts.

For the guidance of the roller carriage the sectional housing of the running mechanism has a web on one or on both vertical limbs, which subdivides the sectional housing into an upper and lower region. In this respect the roller carriage is guided in the upper region on the webs formed as running surfaces, and the sliding wing engages into the lower region, at least in the region of the upper edge of the sliding wing. Alternatively, at least the essential vertical extent of the suspension device connecting the sliding wing to the roller carriage engages into the lower region.

The axles of rotation of the roller carriage can be arranged both horizontally and also vertically or angled to the horizontal. In a preferred embodiment, each rotational axle carries two running rollers with differently shaped running surfaces. Advantages in the guidance of the roller carriage result when one of the running surfaces is convex or concave, and the other running surface is of planar design. The running surfaces of the webs are in this case made complementary hereto.

One of the running rollers can have a cutout in the running surface, into which a resilient pull is received. The latter serves as an energy store for an emergency opening procedure.

The invention will be explained in more detail in the figures, in which are shown:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

a front view of a post/transom design with an overhung sliding door system;

FIGS. 2

a

to

d

a section along the line II—II in

FIG. 1

, with a representation of different possibilities of attaching the sliding door system to the transom;

FIG. 3

a sectional view of an automatic sliding door system built up modularly in the region of the drive and a not-installed, U-shaped cover hood;

FIG. 4

a sectional view of a further embodiment of an automatic sliding door system of modular design, without representation of the roller carriage;

FIG. 5

an enlarged, detailed view of the running mechanism in

FIG. 4

with representation of the roller carriage;

FIG. 6

a schematic, sectional illustration of a roller carriage of a modified running mechanism module;

FIG. 7

a schematic sectional representation of a further modified running mechanism module with running balls;

FIG. 8

a schematic sectional illustration of a further modified running mechanism module with an L-shaped roller carriage;

FIG. 9

a sectional illustration of a modified embodiment relative to

FIG. 4

, sectioned in the region of the control device of the drive;

FIG. 10

a sectional illustration corresponding to

FIG. 9

, sectioned in the region of the accumulator pack and of the cable holder/cable channel;

FIG. 11

a sectional illustration in accordance with

FIG. 9

, sectioned in the region of the deflection roller;

FIG. 12

a sectional illustration in accordance with

FIG. 9

, sectioned in the region of the control sensor;

FIG. 13

a sectional illustration of the side part of the embodiment of

FIG. 9

;

FIG. 14

a sectional illustration corresponding to

FIG. 9

, sectioned in the region of the transformer;

FIG. 15

a representation of the drive unit of the embodiment in

FIG. 9

, with motor and drive pulley in three views; (a): view from below, (b): front view, (C): sectional view along the line XV in

15

a;

FIG. 16

a schematic, overall illustration of the embodiment in

FIG. 9

in plan view;

FIG. 17

a sectional illustration of a running mechanism module with a cover hood in manual sliding doors, without illustration of the roller carriage.

FIG. 1

shows a front view of the sliding door system within a post/transom construction

8

. The vertical posts

84

are supported on the floor and bound in at the ceiling, and are connected to one another via a horizontal transom

81

. A sliding door drive is secured to this transom

81

at the front side. The sliding door drive is formed as a body in the shape of a parallelepiped, which extends over the entire door width. The body comprises a running mechanism

1

and a receiving space

55

with drive and control devices, such as, for example, drive motor, control unit and motion sensor. Two sliding wings

10

are guided via roller carriages in the running mechanism

1

. The sliding wings

10

are moved by the drive motor. As can be recognised in

FIG. 2

, the running mechanism

1

is secured via the intermediately disposed carrier

3

to the transom

81

. The carrier

3

and the transom

81

are located in

FIG. 1

behind the running mechanism, whereas the receiving space

55

shown in

FIG. 9

together with the drive and control devices is located in front of the running mechanism

1

. The two sliding wings

10

are shown in closed position. Fixed field wings

12

are arranged to the side of the sliding wings

10

, and are framed in at their sides by boundary posts

86

and posts

84

.

DETAILED DESCRIPTION OF THE DRAWINGS

In order to simplify the description, the terms running mechanism and running mechanism module and also carrier and carrier module will be used synonymously in the following. Whenever the talk is of running mechanism and carrier, this can accordingly also be a running mechanism module or carrier module.

In

FIG. 2

the possibilities of mounting the running mechanism

1

, or the optionally present carrier

3

, to the transom

81

or to the post

84

are shown in four embodiments. In this respect the one vertical limb of the running mechanism section

63

in each case contacts the front side of the transom

81

or of a carrier

3

interposed therebetween.

FIG. 2

a

shows a direct screwed embodiment

1

e

of the running mechanism

1

with the transom

81

, as corresponds also to the illustration in FIG.

3

. To increase the stiffness, a reinforcing section

81

b

shown dark is incorporated in the transom

81

.

In

FIG. 2

b

a horizontal rail if is arranged over the entire axial length of the running mechanism

1

at the upper edge of the running mechanism section

63

on the latter. In the installed state it lies on the transom

81

and is screwed to the latter. The embodiment in

FIG. 2

c

corresponds to that in

FIGS. 4 and 9

, in which an L-shaped carrier section

3

is bolted to the transom

81

, with a horizontal limb of the carrier section lying on the transom

81

. The running mechanism

1

is connected to the carrier section

3

in

FIG. 2

c

via a mounting apparatus with a dove-tail. In place of a bolted arrangement at the transom

81

, the carrier

3

or also the running mechanism

1

can also be directly secured to the vertical posts

84

. In this case one speaks of an overhung embodiment. Even with such an overhung installation, the carrier

3

can contact the transom

81

with its horizontal limb, as shown in

FIG. 2

c

. Moreover, an additional support of the carrier

3

or the running mechanism

1

by the fixed field wings

12

, or by their boundary posts

86

, is possible. Likewise not shown are possible embodiments in which the carrier

3

or the running mechanism

1

partly or fully replaces the transom

81

.

In an alternative embodiment illustrated in

FIG. 2

d

, the running mechanism

1

takes on a stiffening or carrying function in the place of the carrier section

3

. For this purpose, the running mechanism

1

is formed with two hollow chambers for the introduction of the darkly illustrated strip material

81

c

in L-shape. These are preferably steel rails which increase the stiffness of the running mechanism module

1

, in the overhung installation which is necessary in the majority of applications.

In the embodiment shown in

FIG. 3

one is concerned with a modularly built up sliding door drive comprising running mechanism module

1

, motor and control module

2

, carrier module

3

and also, furthermore, indication and/or communication module

4

. All modules

1

,

2

,

3

,

4

each have a sectional housing in the illustrated embodiment. The modules extend into the longitudinal sliding direction of the running mechanism, and preferably each extend over the entire width of the door. They are arranged behind one another parallel to one another in a common horizontal plane in the direction of viewing perpendicular to the door plane. They thereby contact each other with their respectively confronting front sides. They each have the same height H, for example 60 mm or 70 mm. They are arranged with respect to the aligned upper and lower sides, so that they form an assembled parallelepiped-shaped body of the height H.

The attachment of the modules

1

,

2

,

3

,

4

to one another takes place by in-hanging. For this purpose undercut longitudinal grooves

61

are provided in the mutually confronting front sides and complementary, longitudinal edges

62

, for example projecting longitudinal edges of hook-like cross-section, are provided which interengage. Additionally or alternatively, screw connections can be provided in the confronting front sides.

The mounting of the sliding door drive at the building side can, for example take place via a screw connection, as is shown in

FIG. 3

in the region of the vertical housing limb of the running mechanism module

1

. Alternatively, the carrier module

3

can be inserted in front of the running mechanism module

1

, and the attachment can take place to the vertical housing limb of the carrier module

3

.

The running mechanism module

1

shown in

FIG. 3

has a sliding guide, which, in the illustrated embodiment, contains running rollers

1

a

with a vertical axis of rotation. The running rollers

1

a

run on running surfaces

1

b

of fixed position, which lie opposite to one another in a common horizontal plane. They are moulded onto oppositely disposed limbs of the sectional housing

63

1

c

of the running mechanism module. The running surfaces

1

b

are convexely curved, can, however, also be concave or formed as inclined planar surfaces. A plurality of running rollers are preferably provided in series in the running direction and roll off on oppositely disposed running surfaces, i.e. the one running rollers roll on the one running surface, and the other running rollers roll off on the other running surface.

The running rollers

1

a

have a vertical, rotational thrust bearing

1

d

. The axles vertically received in the bearings carry the sliding wing

10

. For this purpose a suspension device with height adjustment is provided, which can be designed in the customary manner with a screw and nut.

The motor and control module

2

has a motor

2

a

and a non-illustrated control unit. The motor

2

a

is formed as a relatively narrow, essentially bar-like motor. The output drive pinion

2

c

is coupled for motion to the wing

10

. For this purpose a transmission device, which is not shown in more detail, is provided between the drive pinion

2

c

and the wing

10

. By way of example, a drive belt device of customary design can be provided with guide belts which circulate while being guided by deflection rollers

2

b

, with the one deflection roller

2

b

being driven by the motor

2

a

, and one run of the drive belt being connected to the wing

10

via a driver.

In the embodiment shown in

FIG. 3

a rubber cord

2

d

is, moreover, received in the motor and control module. Its one end is secured to the wing

10

, and its other end is secured to the sectional housing of the module

2

. The rubber cord is tensioned during motor closing of the wing. On power failure, the rubber cord ensures the automatic opening of the door. In this respect, provision is made in

FIGS. 4 and 5

for the rubber cord

2

d

to be guided in space-saving manner in a cutout within the running surface of the running rollers

69

a

. Moreover, a hollow section chamber, in which the electrical cables

2

e

are guided, is provided in the motor and control module

2

.

The carrier module

3

in

FIG. 3

has a sectional housing in the same manner as the previously described modules

1

and

2

. Two hollow section chambers are formed therein. A strip material can be received in both chambers for the carrying function. The dimensioning of the strip material is dependent on the stability requirements. Alternatively, an indicator and/or communication device can be introduced into one of the chambers instead of the strip material. A separate display and communication module

4

can be arranged at the outer front side of the overall unit.

The overall unit can be covered over via a cover hood

5

of U-shaped cross-section. Positions of intended fracture

5

a

or markings are provided in the U-limbs of the hood

5

in order for the dimensions of the hood

5

to be easily adapted to the overall arrangement.

FIG. 4

shows a modified embodiment of the sliding door drive. As already described in

FIG. 2

c

, an L-shaped carrier

3

is secured to the posts

84

or also to the transom

81

of a post/transom construction present at the building side. In this arrangement the carrier

3

extends over the entire height of the transom

81

and has a short limb

3

a

which lies on the horizontal upper edge of the transom

81

. The lower edges of the transom

81

and of the carrier module

3

lie at the same level. The carrier module

3

is bolted by mounting bolts

1

e

to the transom

81

and to a reinforcing section

81

b

received in the interior of the transom

81

.

The attachment of the running mechanism

1

to the carrier

3

takes place by an in-hanging device

33

and a clamping device

34

. The in-hanging device

33

comprises a first, dove-tail groove

33

a

close to the upper horizontal edge at the vertical limb

3

b

of the carrier

3

. A first dove-tail section

13

, which is formed in the sectional rail

63

of the running mechanism

1

at the same height, is hung into this. After the hanging into place, the upper and lower edge of the carrier

3

and of the running mechanism

1

lie at the same level. The clamping device

34

with the clamping pieces

35

, which are respectively arranged beneath the hanging-in device

33

, preferably at the lower horizontal edge of the carrier

3

, serve for the fixing of the modules

1

and

3

, which are hooked together via the in-hanging device

33

.

The attachment of the motor and of the control module

2

to the running mechanism

1

likewise takes place by simple in-hanging and clamping at the mutually confronting front sides, with the hanging-in device

33

and the clamping device

34

.

The motor and control module

2

shown in

FIG. 4

has a sectional housing

27

, which is identical from the point of view of the dimensions to the running mechanism module

1

. In the downwardly open sectional housing

27

, a toothed belt

28

b

is guided over two deflection rollers

28

, which are respectively journalled in a rotary bearing

28

c

on vertically disposed axles of rotation

28

a

. one of the two deflection rollers

28

is driven by a bar-like motor

2

a

. Both the deflection rollers

28

and also the drive motor

2

a

can be slid into the housing

27

and fixed at the desired position with clamping bolts. For this purpose, the sectional housing

27

has at its upper horizontal limb

27

b

a sliding guide

20

c

, which extends in the longitudinal direction of the section. An advantage of this is that the position of the deflection rollers

28

can be ideally matched to the width of opening of the door on location.

The driver yoke

25

secured to the roller carriage

6

engages into the motor and control module

2

. In order to enable the passage within the housing

5

, both the vertical limb

63

b

of the running mechanism module

1

and also the vertical limb

27

a

of the motor and control module

2

are of shorter design. The driver yoke

25

, which extends essentially in a horizontal plane, is secured to the drive belt

28

b

in a customary manner via clamped connections

29

. In this arrangement the driver

25

for the first sliding wing

10

passes beneath the toothed belt

28

b

and the deflection rollers

28

and has a vertical, upwardly bent end

25

b

connected at the oppositely disposed side to the one run of the toothed belt

28

b

. A second, oppositely moving wing

10

is connected in similar manner to the other run of the toothed belt

28

b

, but without passing beneath the deflection roller

28

.

The sectional housing

27

, which is open at the front side, is provided with an L-shaped cover hood

5

, which has a vertical limb

5

b

and a horizontal limb

5

c

. The mounting takes place at the front side to the motor and control module

2

by clipping it into a horizontally extending groove

51

at the upper horizontal edge of the motor and control module

2

.

By using the same modules, drives can be produced in corresponding manner for different door types, for example for one-wing and two-wing sliding doors. Furthermore, telescopic sliding door drives can also be produced, for example in that two running mechanism modules

1

are inserted in parallel alongside one another.

FIG. 5

shows an enlarged representation of the running mechanism module in FIG.

4

. On the two vertical limbs

63

a

and

63

b

of the running mechanism section

63

there is in each case provided a horizontal central web

64

a

and

64

b

, which divides the section into an upper region

6

a

and a lower region

7

a

. At the centre an opening remains in the design for the passage of the suspension and adjustment device

7

for the non-illustrated sliding door

10

. The central webs

64

a

,

64

b

are formed as running surfaces

1

b

,

1

b

′ for the roller carriage

6

, with the one central web

64

b

having a running surface

1

b

′ with an arched cross-section, and the other central web

64

a

having a running surface

1

b

with a flattened cross-section. The webs

64

a

,

64

b

have mutually confronting receiving grooves

65

, with sealing brushes

66

arranged therein throughout.

The roller carriage

6

comprises an elongate, basic body

67

, in which two through-going horizontal axles

67

arranged in series are mounted. Each of the axles

68

carries two outwardly disposed, differently shaped running rollers

69

. The running roller

69

of the roller carriage

6

is guided in the upper region

6

a

of the sectional rail

63

on the centre web

64

a

,

64

b

. In correspondence with the design of the running surfaces

1

b

,

1

b

′, the rollers

69

a

arranged at the left side relative to the running axle, have a flattened running surface

1

b

, and the rollers

6

b

arranged at the right side have an arched running surface

1

b

′. The flattening of the running surface

1

b

serves to compensate for tolerances. In order to increase the security of guidance, an arched support section

63

c

is provided, which is complementary to the section of the guide roller

69

b

. This support section

63

c

is arranged at the upper side of the chamber

6

a

opposite to the likewise arched running surface

1

b

′ of the central web

64

b

. In this arrangement, the support section

63

c

engages into the contour of the running roller

69

b

, but does not, however, contact the running roller

69

b

. The roller carriage basic body

67

is also guided with only a small distance to the section

63

, without, however, contacting it. In this manner a “lifting off” of the roller carriage

6

, or indeed a jumping out of the guide, is prevented.

The running rollers

69

a

with the flattened running surface

1

b

each have a peripherally extending cutout within the running surface

1

b

. This serves to receive a rubber cord

2

d

, which brings about the opening of the sliding wing in emergency operation. The rubber cord

2

d

is connected at one end to the sliding wing

10

, and at the other end is supported at a fixed location, can, however, also be moved in pre-stressed form with the wing. It serves as an emergency drive for the emergency opening of the sliding wing

10

on failure of the motor

2

a

. In modified embodiments the rubber cord

2

d

can also be used for emergency closing.

Roller carriages can also be used which, as shown in

FIG. 6

, have a U-shaped sectional body

21

, which is open downwardly towards the wing

10

. Non-illustrated running rollers are arranged at the sides of the U-shaped limbs

22

,

23

, which face away from one another, with the mounting axles of the running rollers being clampingly received in undercut, elongate grooves

22

a

,

23

a

at the outer sides of the U-limbs. Transverse bolts

24

, which are arranged in oppositely disposed bearings in the U-limbs, are provided for the suspension of the wings

10

. The bearings have an eccentric device, so that through rotation of the transverse pin, a vertical adjustment of the wing

10

suspended on the transverse pin can take place.

Instead of running rollers with vertically or horizontally arranged axles, running rollers with axles of rotation arranged at an angle to the horizontal can also be used, preferably with cross-wise offset running rollers arranged in series in the running direction. Through the different arrangement of the running rollers, embodiments of running mechanism modules

1

with different cross-sectional dimensions are possible.

Alternatively, running mechanisms with running balls can also be designed. In the running ball mechanism shown in

FIG. 7

, the balls

36

run in a running groove

37

in the running mechanism housing

1

c

, and support a bearing plate

38

with a corresponding running groove

39

. A suspension device for the sliding wing

10

with a U-shaped receiving body

31

, which is similarly designed to the bodies

21

in the

FIGS. 3 and 6

, is suspended in the bearing plate

38

. The bearing plate

38

can form the body of a running carriage, which has three running balls at each of the two running sides. As in the previously described running mechanisms, the sliding wing also engages here into the running mechanism housing, so that the upper edge of the sliding wing is guided in hidden manner.

A further embodiment of a running mechanism

1

with one vertically and one horizontally arranged running roller

69

v

and

69

h

respectively is shown in FIG.

8

. The substantially L-shaped housing

63

of the running mechanism

1

is secured to a post

84

via an intermediate carrier element

3

. The housing

63

has a vertical limb

63

a

contacting the carrier element

3

and having a horizontal web

64

a

and an upwardly disposed elongate horizontal limb

63

d

, as well as a shorter vertical limb

63

b

arranged approximately in the middle of the horizontal limb

63

d.

The axle

68

of the vertically upright running roller

69

v

is journalled in a vertical limb

6

v

of an L-shaped roller carriage

6

. This roller

69

v

runs on the horizontal web

64

a

. A second running roller

69

h

lying horizontally, i.e. with a vertical axis of rotation, is arranged above the roller carriage

6

and the vertical running roller

69

v

. This second running roller

69

h

acts as a support roller and prevents a tilting of the roller carriage

6

with the wing

10

secured thereto. It can be braced against the limb

63

b

or the limb

63

a.

The roller carriage

6

in the form of an inverted “L” now forms, beneath its vertical limbs

6

v

, an additional receiving space for the vertical adjustment of the wing

10

. In this design the wing is connected to the horizontal limb

6

h

of the roller carriage

6

via a suspension and adjustment device

7

of customary design. Alternatively, the wing

10

can be secured via a suspension and adjusting device on the vertical limb

6

v

of the roller carriage

6

.

Close to the outer end of the horizontal limb

63

d

of the sectional housing

63

, a receiving groove

350

is present at its lower side for the attachment of drive and control elements. The front side of the sectional housing

63

is closed off by an L-shaped cover hood

5

, which is hung in at an upper horizontal front edge of the sectional housing

63

, at an upper longitudinal edge

62

. In this arrangement the lower horizontal limb of the cover hood

5

extends directly up to the sliding wing

10

and lies at the same level as the carrier element

3

and the left hand vertical limb

63

a

of the sectional housing

63

. As in the previously described running mechanisms, the sliding wing

10

also engages here into the running mechanism housing

63

, so that the upper edge of the sliding wing is guided in hidden manner.

In the embodiment shown in

FIGS. 9

to

16

, one is concerned with a modification of the embodiment in FIG.

4

. The motor and control devices, for example drive motor

2

a

, control

2

f

and also further elements shown in the subsequent Figures, such as, for example, the radar

220

, the deflection roller

28

, the transformer

240

and the latching device

9

, are arranged on the correspondingly assembled running mechanism

1

, in a receiving groove

350

arranged at the front side of the box-like running mechanism housing

63

, via clamping blocks

351

with clamping bolts

352

. In this design the additional hanging device

33

at the upper edge of the running mechanism housing, as in the embodiment of

FIG. 2

, is dispensed with here. The receiving groove

350

is substantially T- or C-shaped. It lies horizontally in the central region of the front side of the running mechanism housing

63

, at the vertical limb

63

b

thereof. The drive units and all further components can be inserted into the receiving groove

350

in series and can each be secured individually via a clamp mounting

351

,

352

, which is described in detail in FIG.

11

. Alternatively, a plurality of horizontally extending receiving grooves can also be provided in the front side.

In an alternative embodiment, the clamping blocks

351

are dispensed with. Preferably, components can be secured in a receiving groove by simple hooking in and subsequent securing, for example with a screw, or for example with a latchable bearing connection.

The drive and control devices secured by clamping in the receiving groove

350

are covered over by a U-shaped cover hood

5

, which substantially forms a parallelepiped-shaped receiving space

55

for the drive units. The parallelepiped-shaped receiving space

55

formed by the U-shaped cap

5

adjoins the box-like running mechanism section

63

of the running mechanism

1

, with the upper horizontal edge of the receiving space or cap

5

being aligned with the upper horizontal edge of the running mechanism

1

and likewise with the lower horizontal edge of the receiving space or the cap

5

being aligned with the lower edge of the vertical limb

63

a

of the running mechanism

1

and the lower edge of the vertical limb

3

b

of the carrier

3

. The cross-section of the receiving space

55

is rectangular and so arranged that the horizontal edge is longer than the vertical edge, preferably 1.5 to 2 times as long. The cross-section of the running mechanism section

63

, in which the roller carriages are arranged including the suspension and adjusting device

7

for the wing

10

is substantially square, with the vertically extended limb

63

a

being approximately as long as the horizontal edge of the running mechanism cross-section.

A cutout

7

a

is formed between the vertical limb

63

a

and the box-like housing part which receives the running carriage

6

, with the suspension and adjusting device

7

and also the upper edge of the wing

10

being engagingly arranged in the cutout

7

a

. The cutout

7

a

is open towards the receiving space

55

as a result of the shortened limb

63

b

, in the figure the right hand limb, so that the driver

25

can pass through.

The total drive comprising the carrier

3

, running mechanism

1

and drive units thus receives a rectangular shape, with the long edge being horizontal and the short edge being vertically arranged. The upper edge of the wing

10

engages into this rectangular drive box, so that the upper edge of the wing

10

is covered over, i.e. at the front side, by the front side of the drive or by the cover hood

5

.

In the sectional illustration of

FIG. 9

the control unit

2

f

can be recognised. It has an elongate box-like shape and is arranged directly above the drive belt plane. The drive belt

28

b

is guided in the receiving space

55

in a lower horizontal plane via deflection roller

28

(

FIG. 11

) and drive wheel

2

c

(FIG.

15

). The motor

2

a

, the control unit

2

f

etc. are arranged above this plane in the receiving space

55

.

The control unit

2

f

(

FIG. 9

) comprises a housing upper part

270

, which receives a non-illustrated control circuit board and is clampingly secured in the front side groove

350

, as well as an L-shaped cover

271

, which is plugged from below onto the upper part

270

. The control circuit boards are introduced from the side into two corresponding, horizontally extending insert grooves

272

within the upper part

270

.

The drive belt

28

b

is shown beneath the control unit

2

f

, and also the driver yoke

25

connected to the first door wing

10

. Since the right hand limb

63

b

of the running mechanism section

63

ends at the level of the central web

64

b

, the driver yoke

25

can be guided in a horizontal plane from the upper edge of the wing to the drive belt

28

b

. In this arrangement the upper edge of the wing lies approximately in the plane of the drive belt. The driver yoke

25

extends in this arrangement just above the lower limb of the cover hood

5

. It is screwed onto the base plate

75

, on which the suspension and adjusting device

7

is secured, and which is inserted into the upper edge of the wing. At the drive belt side, the driver yoke

25

has an upwardly bent end

25

, which is bolted to a counterpiece

28

c

, with the drive belt

28

b

, which is split at this point, being clamped between the end

25

b

of the yoke and the counterpiece

25

c

. The drive belt

28

b

is in each case split at the mounting position of the driver yoke, i.e. divided into two.

The suspension and adjusting device

7

is designed in customary manner, in that the sliding wing

10

is mounted via a yoke

74

on a vertically adjustable threaded screw

71

. The sliding wing can be lifted or lowered by rotating in or out the threaded bolt

71

, which is journalled in a counterthread within the roller carriage

6

.

In

FIG. 10

the driver yoke

25

of the second wing

10

and also the deflection roller

28

lying behind it are shown. The driver yoke

25

is passed here, starting from the upper edge of the wing, horizontally under the front drive belt

28

b

, and has a U-shaped end which engages into the plane of the drive belt. The central piece of the U-shaped end has an adjusting device

25

d

, via which the yoke length can be set. The yoke end

25

b

is also bolted here to a counterpiece

25

c

and clamps the toothed belt

28

b

, which is split at this point. In an alternative design, the driver yoke

25

can also be guided above the drive belt

28

b.

The cable channel

2

h

, which is likewise clampingly secured in the front side groove

350

of the running mechanism

1

, is arranged above the drive belt plane in FIG.

10

. It has, on the whole, a rectangular shape and has a functional division into two. The left hand half

250

is closed on all sides, apart from an insertion opening

251

at the vertical front side and serves for the guidance of loose cables. The right hand half

252

is open downwardly and has insertion grooves

253

, extending in the longitudinal direction at the upper side to receive functional components. Illustrated are, for example an accumulator pack

2

gh

, which is secured via a bolted arrangement

261

to a yoke

260

, which was introduced horizontally into the insertion grooves

253

of the cable channel

2

h.

The accumulator pack

2

g

serves for the emergency opening or closing of the door in the event of power failure, in particular for escape and rescue doors.

FIG. 11

shows a sectional illustration of the receiving space

55

, bounded by the cover hood

5

in the plane of the deflection roller

28

. A downwardly pointing, almost L-shaped holding arm

28

d

, which carries the deflection roller

28

, is clampingly secured at its vertical limb by clamping screws

352

in the front side groove

350

on the running mechanism module

1

. The horizontal limb of the holding arm carries the vertical axle of rotation

28

a

of the horizontally disposed deflection roller

28

. The deflection roller

28

is journalled on its axle rotation

28

a

via a rotary bearing

28

c

. The toothed belt

28

b

guided on the deflection roller

28

is also shown.

The horizontally extending, T-shaped groove

350

is approximately centrally arranged on the front side of the vertical limb

63

b

of the running mechanism housing

63

, with it extending over the full length of the sectional housing

63

. The groove bounding strips

354

are formed on the vertical limbs

63

b

on both sides of the groove

350

. The T-shaped clamping block

351

, which is likewise received in the groove

350

, has a threaded bore

353

, and projects out of the T-groove

350

. The holding arm

28

d

, which carries the deflection roller

28

, lies areally on the groove bounding strips

354

, with the end of the clamping block

351

projecting out of the groove

350

, being received in a cutout of the holding arm

28

d

. A clamping bolt

352

is passed through the holding arm

28

d

, and engages into the threaded bore

353

of the clamping block

351

, and its screw head

352

contacts the holding arm

28

d.

Through the clamping bolt

352

, the T-shaped end of the clamping block

351

is drawn from the rear side against the projection

354

, which closes off the groove

350

at the front side, and simultaneously the holding arm

28

d

is pressed from the front against the groove bounding strips

354

. The clamping blocks

351

and the holding arm

28

d

are thus firmly connected to one another and secured against further displacement. All further drive and control elements are also clampingly secured in the groove

350

in the same manner.

The radar movement sensor

220

for the control of the door is depicted in the sectional illustration of FIG.

12

. The housing

222

of the radar movement sensor

220

is in this arrangement secured to the lower side of the vertical limb of an upwardly pointing, almost L-shaped holding arm

221

via a bolted connection

224

. The holding arm

221

is likewise clampingly secured in the front side groove

350

at the running mechanism module

1

.

The sensor

223

, which is pivotable around a horizontal axis, is arranged on the housing

222

and engages between the two toothed belts

28

b

into the drive belt plane. In order to enable the sensor to have free sight of the door vestibule, the cover hood

5

has a cutout

500

beneath the radar

220

.

The holding arm

221

for the radar

220

can, moreover, serve as a support for the cover hood

5

contacting the holding arm

221

. The additional holding arm

520

shown in

FIG. 16

can thus be omitted. It is of particular advantage if the holding arm

221

simultaneously serves as a cable guide. For this purpose cables can be inserted from above into the cutout between the holding arm

221

and the running mechanism

1

.

The left hand outer end of the door drive

3

with the side part

510

is shown in section in FIG.

13

. The side part

510

is secured via a first bolt

511

to the side of the running mechanism

1

and via a second bolt

512

to the carrier

3

. When seen from the side, the side part

510

covers over both the receiving space

55

and also the carrier

3

and the running mechanism section

63

. The height of the side part

510

is identical to the height of the running mechanism

1

, of the carrier

3

and of the cover hood

5

. The side part

510

simultaneously serves as a seat for the cover hood

5

.

A socket

230

for the connection to the power supply of the sliding door system is also shown in

FIG. 13

, as well as the left hand elastic buffer

610

, which prevents the roller carriage

6

running out onto the side part

510

. The socket

230

is secured in the front side groove

350

at the running mechanism

1

. The buffer

610

is secured via a screw fitting

611

within the running mechanism section

63

.

FIG. 14

shows a section in the region of one of the two transformers

240

. The transformer

240

is arranged on an L-shaped base plate

242

in front of the running mechanism

1

. In this arrangement the vertical limb

242

b

of the base plate

242

is clampingly secured in the front side groove

350

. As can be recognised in

FIG. 16

in plan view, two transformers

240

are arranged alongside one another on the base plate. By using two transformers, their constructional height is reduced. Alternatively, only a single transformer

240

can be used with special dimensions, for example with a slender overall shape through suitable winding.

FIG. 15

a

shows a view from below onto the right hand end of the running mechanism

1

with the motor

2

a

, which is arranged there, with the transmission

2

i

and with the drive pulley

2

c

for the drive belt

28

b

, which is directly coupled to the transmission

2

i

of the motor

2

a

. Since the drive wheel

2

c

is directly mounted on the output drive shaft of the transmission

2

i

, a separate bearing block can be spared. The illustrated right hand side part

510

, which covers over the running mechanism

1

and the carrier

3

from the side, is identically designed to the left hand side part

510

already described in FIG.

13

. The motor

2

a

is of substantially bar-shaped design and is aligned in the longitudinal direction of the running mechanism

1

, preferably at an acute angle to the longitudinal direction of the running mechanism. Including the drive pulley

2

c

, the motor

2

a

takes up the entire cross-section of the receiving space

55

, as can be recognised from the plan view of

FIG. 15

b

, and the sectional illustration of

FIG. 15

c

along the line XV in

FIG. 15

a

, i.e. the constructional space between the running mechanism

1

and the cover hood

5

. The drive rail

2

is horizontally aligned and arranged beneath the motor

2

a.

The drive unit with the motor

2

a

and the drive disc

2

c

is secured onto a clamping device

370

, which enables a tensioning of the toothed belt

28

b

, by shifting the complete drive unit in the longitudinal direction of the running mechanism on the clamping device

370

. The drive unit is clampingly secured in the front side groove

350

via the clamping device

370

.

FIG. 16

shows an overall view of the components of the sliding door system shown in

FIGS. 9

to

15

. From the left to the right there can be seen: left hand side part

510

, socket

230

, transformer

240

, deflection roller

28

, cable holder

2

h

with accumulator pack

2

g

, locking device

9

, radar

220

, holding yoke

520

, control unit

2

f

, clamping device

370

, drive pulley

2

c

, motor

2

a

and right hand side part

510

. In the running mechanism

1

secured to the carrier

3

there can be seen four buffers

610

and the central cutout

620

for the insertion of the roller carriages

6

.

In place of a continuous running mechanism section

63

with a central cutout

620

, a splitting into two of the running mechanism section

63

at its axial centre is also possible as an alternative, i.e. that a left and right hand part section is separately present for the left hand and the right hand wing. The two part sections are separately secured to the carrier

3

. In doing so, a cutout for the insertion of the roller carriage

6

likewise remains free at the centre, as is illustrated in broken lines in FIG.

16

.

The placing of the individual components on the running mechanism

1

preferably takes place independently of the total width and width of opening of the drive.

FIG. 17

shows a cover screen

530

, with which the running mechanism

1

is hidden, provided no drive and control elements are to be installed, which is, for example, the case with manual sliding doors. The cover screen

530

has a convexely shaped front side and is secured in the front groove

350

of the running mechanism

1

by means of clamping blocks

351

and clamping bolts

352

. In this arrangement the upper horizontal edge of the cover screen

530

finishes flush with the front upper horizontal edge of the running mechanism

1

and the lower horizontal edge of the cover screen

530

lies at the level of the lower edge of the vertical limb

63

a

of the running mechanism

1

, so that the wing upper edge is covered over. The width of the cover screen

530

corresponds to the width of the running mechanism

LIST OF THE REFERENCE NUMERALS

1

running mechanism

1

a

running roller

1

b

,

1

b

′ running surface

1

c

sectional housing limb

1

d

rotary thrust bearing

1

e

screw mounting

1

f

rail

10

wing

12

fixed field wing

13

dove-tail section

14

,

15

dove-tail groove

21

U-shaped sectional body

22

,

23

U-limbs

22

a

,

23

a

longitudinal grooves

24

transverse pin

31

receiving plate

36

running ball

37

running groove housing

38

bearing plate

39

running groove bearing plate

9

latching device

2

motor and control module

2

a

motor

2

b

deflection roller

2

c

drive pinion

2

d

rubber cord

2

e

electric cable

2

f

control unit

2

g

accumulator pack

2

h

cable channel/cable holder

2

i

transmission

25

driver yoke

25

a

,

25

b

end of yoke

25

c

counterpiece

25

d

adjustment device

25

e

bolted arrangement

25

f

screw mounting

26

bolted arrangement

27

sectional housing

27

a

vertical limb

27

b

horizontal limb

27

c

sliding guide

28

deflection roller

28

a

vertical axis of rotation

28

b

toothed belt

28

c

rotary bearing

29

clamped connection

220

radar

221

holding arm

222

housing

223

sensor

224

screw mounting

230

socket

231

screw mounting

232

base plate

233

mains plug

234

on/off switch

240

transformer

270

upper part of the housing

271

cover

272

insert groove

273

cooling body

3

carrier module

3

a

horizontal limb

3

b

vertical limb

3

c

cutout

32

point of intended breakage

33

in-hanging device

33

a

dove-tail groove

34

clamping device

34

a

mount

35

clamping piece

35

a

base surface

35

b

dove-tail section

35

c

wedge surface

35

d

clamping screw

35

e

strip

350

receiving groove

351

clamping block

352

clamping bolt

352

a

bolt head

353

threaded bore

354

groove bounding strips

370

clamping device

371

abutment

372

carriage

373

threaded pin

374

clamping screw

375

threaded bore

376

clamping claw

4

indication/communication module

5

cover hood

5

a

point of intended breakage

5

b

vertical limb

5

c

horizontal limb

51

groove

55

receiving space

510

side part

511

,

512

bolt

513

holding head

514

pin

515

cutout

520

holding yoke

530

cover screen

6

roller carriage

6

a

upper chamber

6

h

horizontal limb

6

v

vertical limb

61

longitudinal grooves

62

longitudinal edges

63

U-section

63

a

,

63

b

vertical limb

63

c

support section

63

d

horizontal limb

64

a

,

64

b

central webs

65

receiving grooves

66

sealing brush

67

base body

67

a

cutout

68

axle

69

running roller

69

a, b

running roller

69

h, v

running roller

600

receiving grooves

610

buffer

611

bolted connection

620

cutout

630

support surface

7

suspension and adjusting device

7

a

lower chamber

71

hexagonal bolt

74

yoke

75

base plate

8

post/transom construction

81

transom

81

b, c

reinforcement section

82

suspended post

83

roof of storey

84

post

86

boundary post

Claims

1. An assembly comprising:a running mechanism disposed in a running mechanism housing and operable to carry a sliding door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and the door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to a support frame transom and the door wing when in an in use operating position mounted on a support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending in use along an upper edge of the door wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of a support frame transom when in an in use operating position mounted on a support frame, and wherein said parallelepiped shaped body has a vertical height of between 60 mm and 70 mm.
2. An assembly according to claim 1, wherein said drive motor assembly includes an electric drive motor which drives a circulating drive belt guided over deflection rollers.
3. An assembly according to claim 2, wherein the drive motor has a transmission with a drive pulley for the circulating drive belt at the output drive side.
4. An assembly according to claim 1, wherein the drive motor assembly includes a drive belt driven by a drive motor and guided in a horizontal plane via deflection rollers, with a vertical axis of rotation.
5. An assembly according to claim 4, wherein a driver which in use connects the door wing to the drive belt extends in a horizontal plane from an upper edge of the door wing to the drive belt, with provision being made for the top edge of the door wing to lie at least approximately in the same horizontal plane as the drive belt.
6. An assembly according to claim 1, wherein the drive motor assembly includes a drive belt driven by a drive motor and arranged in a plane beneath other drive units of the drive motor assembly including a motor, a control, an accumulator pack, and a transformer.
7. An assembly according to claim 6, wherein a driver which in use connects the door wing to the drive belt extends in a horizontal plane from an upper edge of the door wing to the drive belt, with provision being made for the top edge of the door wing to lie at least approximately in the same horizontal plane as the drive belt.
8. An assembly according to claim 1, wherein the running mechanism housing is formed as a sectional housing, which has two parallel vertical limbs, of which the first limb is arranged in use adjoining the transom, or on a separate carrier and the second limb is arranged adjoining the drive motor assembly housing.
9. An assembly according to claim 8, wherein the second vertical limb is made substantially shorter than the first vertical limb.
10. An assembly according to claim 9, wherein the drive motor assembly includes a first running roller with a horizontal axis of rotation and a second running roller with a vertical axis of rotation.
11. An assembly according to claim 10, wherein the first running roller is guided in the region of the first vertical limb and the second running roller is guided in the region of the second vertical limb.
12. An assembly according to claim 11, wherein the second running roller is formed as a support roller, which is supported on the first or second vertical limb.
13. An assembly according to claim 10, wherein the second running roller is formed as a support roller, which is supported on the first or second vertical limb.
14. An assembly according to claim 10, with at least one roller carriage guided in the running mechanism housing and with a suspension device for the sliding door wing connected to the roller carriage, wherein the suspension device is formed as a suspension and adjusting device, andwherein the first running roller and the second running roller are mounted on one roller carriage body, which has a vertical limb and a horizontal limb.
15. An assembly according to claim 14, wherein the suspension and adjusting device is connected to the vertical limb of the roller carriage body, or with the horizontal limb of the roller carriage body.
16. An assembly according to claim 1, wherein the running mechanism is supported on a fixed field door wing when in an in use operating position.
17. An assembly comprising:a running mechanism disposed in a running mechanism housing and operable to carry a sliding door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and the door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to a support frame transom and the door wing when in an in use operating position mounted on a support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending in use along an upper edge of the door wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of the support frame transom when in an in use operating position mounted on the support frame, and wherein a display and communications module housing is connected to said drive motor assembly housing at a side facing away from the support frame transom when in an in use operating position mounted on the support frame.
18. An assembly comprising:a running mechanism disposed in a running mechanism housing and operable to carry a sliding door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and the door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to a support frame transom and the door wing when in an in use operating position mounted on a support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending in use along an upper edge of the door wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of a support frame transom when in an in use operating position mounted on a support frame, wherein the running mechanism housing is formed with a substantially square cross-section, and wherein the drive motor assembly housing includes a receiving space for the drive and control devices and has substantially the same sized cross-section as the running mechanism housing.
19. An assembly according to claim 18, wherein the receiving space is surrounded by a cover hood, the lower edge of which cover hood is parallel with an upper edge of the running mechanism housing and lies in use beneath an upper edge of the door wing.
20. A sliding door system including:a support frame including vertical posts and a horizontal transom, a sliding door wing, and an assembly for supporting the sliding door wing at the support frame, said assembly comprising: a running mechanism disposed in a running mechanism housing and operable to carry the door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and the door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to the transom and the door wing when in an in use operating position mounted on the support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending along an upper edge of the door wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of a support frame transom when in an in use operating position mounted on a support frame, and wherein the running mechanism housing and the receiving space have the same axial length and extend over an entire door width.
21. A sliding door system including:a support frame including vertical posts and a horizontal transom, a sliding door wing, and an assembly for supporting the sliding door wing at the support frame, said assembly comprising: a running mechanism disposed in a running mechanism housing and operable to carry the door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and the door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to the transom and the door wing when in an in use operating position mounted on the support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending along an upper edge of the wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of the transom, and wherein the running mechanism housing is connectable in use to said transom by way of a separate carrier housing, said carrier housing having a horizontal limb and a vertical limb, with the horizontal limb lying in use on the transom and the lower edge of the vertical limb terminating with the lower edge of the transom.
22. A sliding door system including:a support frame including vertical posts and a horizontal transom, a sliding door wing, and an assembly for supporting the sliding door wing at the support frame, said assembly comprising: a running mechanism disposed in a running mechanism housing and operable to carry the door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and the door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to the transom and the door wing when in an in use operating position mounted on the support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending along an upper edge of the wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of the transom, wherein the running mechanism housing is connectable to said transom by way of a separate carrier housing, and wherein the carrier housing is formed in use as a part of the transom.
23. A sliding door system including:a support frame including vertical posts and a horizontal transom, a sliding door wing, and an assembly for supporting the sliding door wing at the support frame, said assembly comprising: a running mechanism disposed in a running mechanism housing and operable to carry the door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and the door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to the transom and the door wing when in an in use operating position mounted on the support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending along an upper edge of the wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of the transom, and wherein the running mechanism housing has a mounting means for the mounting of modules arranged lying behind one another when seen from the front side of the sliding door wing.
24. A sliding door system according to claim 23, wherein the mounting means has a hook-in device and a clamping device and wherein the hook-in device is arranged at an upper horizontal edge of the running mechanism housing, and the clamping device is arranged at a lower horizontal edge or vice versa.
25. An assembly comprising:a running mechanism disposed in a running mechanism housing and operable to carry a sliding door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and the door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to a support frame transom and the door wing when in an in use operating position mounted on a support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending in use along an upper edge of the door wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of a support frame transom when in an in use operating position mounted on a support frame, and wherein a mounting means is formed at the running mechanism housing in such a way that drive and control devices can be fixed into it with variable placing, individually or in component groups.
26. An assembly according to claim 25, wherein the mounting means is a horizontally extending C-groove.
27. An assembly according to claim 26, wherein the groove is formed as a one-piece element of the running mechanism housing.
28. An assembly according to claim 26, wherein the groove is formed at a front side at a half height of the running mechanism housing.
29. An assembly according to claim 26, wherein the drive and control devices are secured in the groove via clamping blocks with clamping bolts.
30. An assembly comprising:a running mechanism disposed in a running mechanism housing and operable to carry a sliding door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and the door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to a support frame transom and the door wing when in an in use operating position mounted on a support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending in use along an upper edge of the door wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of a support frame transom when in an in use operating position mounted on a support frame, wherein the drive motor assembly includes a drive belt driven by a drive motor and guided in a horizontal plane via deflection rollers, with a vertical axis of rotation, wherein a driver which in use connects the door wing to the drive belt extends in a horizontal plane from an upper edge of the door wing to the drive belt, with provision being made for a top edge of the door wing to lie at least approximately in the same horizontal plane as the drive belt, and wherein the running mechanism housing includes two vertical limbs, wherein one of the two vertical limbs is of shortened design for the passage of the driver.
31. An assembly comprising:a running mechanism disposed in a running mechanism housing and operable to carry a sliding door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and the door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to a support frame transom and the door wing when in an in use operating position mounted on a support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending in use a long an upper edge of the door wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of a support frame transom when in an in use operating position mounted on a support frame, wherein at least one roller carriage is guided in the running mechanism housing and a suspension device for the sliding door wing is connected to the roller carriage, with the suspension device being designed as a suspension and adjustment device, wherein the running mechanism has a web on at least one vertical limb which divides the running mechanism housing into an upper region and a lower region, wherein the roller carriage is arranged in an upper region and a web is formed as a guide means for the roller carriage, and wherein the sliding door wing engages in use, at least in a region of its upper edge, into a lower region of the running mechanism housing.
32. An assembly according to claim 31, wherein both vertical limbs of the running mechanism housing each have a web, with both webs lying in a common horizontal plane.
33. An assembly according to claim 31, wherein the axes of rotation of the running rollers of the roller carriage are arranged horizontally, vertically or angled to the horizontal.
34. An assembly according to claim 33, wherein the axis of rotation carries at least two differently shaped running rollers.
35. An assembly according to claim 34, wherein one of the running rollers has a running surface with a convex or concave cross-section, and one of the running rollers has a planar running surface, and the running surfaces of the webs each have a shape complementary thereto.
36. An assembly according to claim 34, wherein one of the running rollers has cutout extending around it in the running surface, with a draw element in the form of one of a resilient draw member, and rubber cord being guided in the cutout.
37. An assembly comprising:a running mechanism disposed in a running mechanism housing and operable to carry at least one sliding door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and the at least one door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to a support frame transom and the at least one door wing when in an in use operating position mounted on a support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending in use along an upper edge of the at least one door wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of a support frame transom when in an in use operating position mounted on a support frame, wherein the running mechanism housing is of a design divided into two parts in its axial extent with the at least one door wing including respective first and second door wings, with the first door wing being guided in use with roller carriages in a first part of the running mechanism housing and the second door wing being guided in use with roller carriages in a second part of the running mechanism housing, and wherein provision is made for a cutout to remain between the first part and the second part for the insertion of the roller carriages.
38. A sliding door system including:a support frame including vertical posts and a horizontal transom, a sliding door wing, and an assembly for supporting the sliding door wing at the support frame, said assembly comprising: a running mechanism disposed in a running mechanism housing and operable to carry the door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to the transom and door wing when in an in use operating position mounted on the support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending along an upper edge of the wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of the transom, and wherein said parallelepiped shaped body has a vertical height of between 60 mm and 70 mm.
39. A sliding door system including:a support frame including vertical posts and a horizontal transom, a sliding door wing, and an assembly for supporting the sliding door wing at the support frame, said assembly comprising: a running mechanism disposed in a running mechanism housing and operable to carry the door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to the transom and door wing when in an in use operating position mounted on the support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending along an upper edge of the wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of the transom, and wherein a display and communications module housing is connected to said drive motor assembly housing at a side facing away from the transom.
40. A sliding door system including:a support frame including vertical posts and a horizontal transom, a sliding door wing, and an assembly for supporting the sliding door wing at the support frame, said assembly comprising: a running mechanism disposed in a running mechanism housing and operable to carry the door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to the transom and door wing when in an in use operating position mounted on the support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending along an upper edge of the wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of the transom, and wherein the running mechanism housing is connectable to said transom by way of a separate carrier housing, said carrier housing having a horizontal limb and a vertical limb, with the horizontal limb lying in use on the transom and the lower edge of the vertical limb terminating with the lower edge of the transom.
41. An assembly comprising:a running mechanism disposed in a running mechanism housing and operable to carry a sliding door wing during movements thereof, and a drive motor assembly disposed in a drive motor assembly housing and operably connected to the running mechanism to drivingly move the running mechanism and door wing, wherein said running mechanism housing and said drive motor assembly housing are disposed adjacent to and behind one another in a direction transverse to a support frame transom and door wing when in an in use operating position mounted on a support frame, wherein the running mechanism housing and drive motor assembly housing form a substantially parallelepiped shaped body with a lower edge extending in use along an upper edge of a door wing, said parallelepiped shaped body having a vertical height determined by a vertical cross-section of the respective running mechanism housing and drive motor assembly housing, wherein the parallelepiped shaped body has a horizontal width which is at least twice as large as its vertical height, said vertical height corresponding approximately to a vertical height of a support frame transom when in an in use operating position mounted on a support frame, wherein at least one roller carriage is guided in the running mechanism housing and a suspension device for the sliding door wing is connected to the roller carriage, with the suspension device being designed as a suspension and adjustment device, wherein the running mechanism has a web on at least one vertical limb which divides the running mechanism housing into an upper region and a lower region, wherein the roller carriage is arranged in an upper region and a web is formed as a guide means for the roller carriage, and wherein the suspension device engages at least with its substantially vertical extent into a lower region of the running mechanism housing.

Priority Claims (10)

Number	Date	Country
196 07 891	Mar 1996	DE
196 28 673	Jul 1996	DE
196 28 670	Jul 1996	DE
196 50 132	Dec 1996	DE
196 50 351	Dec 1996	DE
196 54 476	Dec 1996	DE
196 54 477	Dec 1996	DE
196 54 478	Dec 1996	DE
197 00 831	Jan 1997	DE
196 28 657	Jul 1999	DE

PCT Information

Filing Document	Filing Date	Country	Kind
PCT/EP97/01014		WO	00

Publishing Document	Publishing Date	Country	Kind
WO97/32103	9/4/1997	WO	A

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Number	Name	Date	Kind
3834081	Catlett	Sep 1974	A
3872622	Berk	Mar 1975	A
4050191	Azuma	Sep 1977	A
4401033	Gerken	Aug 1983	A
4424605	Squires et al.	Jan 1984	A
4475312	Deutschle	Oct 1984	A
5634297	Ito	Jun 1997	A

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543048	Mar 1985	AU
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2336310	Feb 1975	DE
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38 23 188	Jan 1990	DE
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0 066 658	Dec 1982	EP
0 620 353	Oct 1994	EP
2 102 924	Jul 1972	FR
2 136 842	Dec 1972	FR
1104057	Feb 1968	GB
2 201 192	Aug 1988	GB

Sliding door system

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