DE29904356U1 - Bed frame - Google Patents

Description

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franko furniture fittings Franke GmbH & Co. KG, 05 March 1999

72336 Balingen-Weilstetten S/gs

647/01
5

Bed frame

Description
10

The invention relates to a bed base with the features of the preamble of claim 1.

Such bed frames with a pivoting foot and/or head part, which is referred to below as the pivoting part, are known per se. They are designed, for example, as a slatted frame that is divided into a base part and the head and/or foot part (pivoting part), which are pivotally connected to the base part. The pivoting part can be divided into several, often two, parts that can pivot against each other. It is known to pivot the pivoting parts of the bed frames using an electric motor drive in particular. The electric motor drive of known bed frames is attached to two crossbars on the underside of the bed frame. In bed frames with two pivoting parts, the drive has two electric motors and two gears with which the two crossbars can be driven pivotably and pivot the two pivoting parts separately from each other via radially projecting levers. The drive with the crossbars is located under the bed frame. The crossbar for swiveling the foot section serves as a support for the electric motor drive when swiveling the head section and vice versa, the crossbar for swiveling the head section serves as a support for the electric motor drive when swiveling the foot section.

The known electric motor drives for bed bases have the disadvantage that they are large. They protrude far down from the bed base. As a result, the electric motor drives reduce the storage space underneath the bed base and get in the way of drawers underneath the bed base. Another disadvantage of the known electric motor drives is that they are located in the area of the swivel part and, together with the swiveling crossbar, block an area that is covered by the swivel part when the swivel part is horizontal and forms an opening when the swivel part is swiveled upwards. The electric motor drives hinder access to a bed box underneath the bed base when the swivel part is swiveled upwards. Another disadvantage is that the crossbars of the electric motor drive have to be matched to the width of the bed base, which increases manufacturing and storage costs, since an electric motor drive with crossbars of the appropriate length is required for each bed base width. The crossbars cannot simply be shortened to the appropriate length because the radially protruding levers for pivoting the pivoting part are attached to their ends.

The invention is based on the object of proposing a bed base with a drive, the drive of which can be attached to the underside of the bed base in a space-saving manner.

This object is achieved according to the invention by the features of claim 1. The bed base according to the invention has a telescopic drive which is supported, for example, on the base part or on a frame of the bed base and which engages the swivel part directly or via a lever. The swivel part is swiveled by changing the length of the telescopic drive. The bed base according to the invention has the advantage that it can be attached to the underside of the bed base or the swivel part at a short distance from the bed base or the swivel part, thus saving space. Another advantage of the invention is that the telescopic drive moves with the swivel part when the swivel part is swiveled; it is always located at a short distance from the swivel part on the underside of the swivel part, even if

this is swiveled upwards. This has the advantage that the swivel part swiveled upwards opens an opening that is not blocked by the drive and through which, for example, a bed box below the bed frame is accessible. Another advantage is that the articulation of the telescopic drive on the swivel part is simplified and a knee lever arrangement or sliding guide, as is necessary with known electric motor drives to convert the swivel movement of the cross member into a swivel movement of the swivel part of the bed frame, is no longer required. In addition, the telescopic drive is variable in length, which means that the telescopic drive can be attached easily and without modifications to different bed frames where the articulation points for the telescopic drive are at different distances from each other.

For example, a pneumatic or hydraulic piston/cylinder unit can be used as a telescopic drive. In one embodiment of the invention, a spindle drive is provided, which can be driven in particular by an electric motor and can be easily connected to a household power supply.

Preferably, a spindle of the spindle drive has a right-hand and a left-hand thread, so that two drive elements, one of which is engaged with the right-hand thread and the other with the left-hand thread, can be moved away from and closer to one another by rotating the spindle. The drive elements are, for example, nuts or pipes (cylinders) with an internal thread that are hinged to the bed base or the swivel part and whose linear movement is converted into a swivel movement of the swivel part. The spindle with right-hand and left-hand threads has the advantage that the drive speed is doubled. Another advantage is that the drive elements are short, subject to pressure and are at low risk of buckling due to their short length. This embodiment of the invention has the advantage that buckling stress on the moving parts of the spindle drive is small.

Preferably, two telescopic drives are used for the swivel part of the bed frame, which are arranged parallel to each other in the area of the long sides of the bed frame. This prevents any load on the individual telescopic drive.

halved and the two telescopic drives exert a force on both sides to swivel the swivel part, so that twisting of the swivel part is avoided.

In a preferred embodiment of the invention, the two telescopic drives have a common energy source, i.e. a common pressure medium source in the case of pneumatic or hydraulic drives, and in particular a common electric motor in the case of spindle drives. The use of a common energy source for both telescopic drives has the advantage of being inexpensive to manufacture and of simplifying the control of the two telescopic drives. The two telescopic drives are preferably synchronized with one another, for example mechanically, to ensure that the drive movement of the telescopic drives on both sides of the bed base and thus the swivel movement on both sides of the swivel part takes place at the same speed.

In one embodiment of the invention, it is provided that the drive only works in one direction and has a freewheel in the opposite direction. This means that the drive exerts a driving force, for example as a pressure force, in one direction only and must be reset in the opposite direction by an external force. The drive therefore does not exert a pulling force, for example. In this embodiment of the invention, the swivel part is only raised by the drive, and the lowering is done by gravity. The purpose of this is to avoid the risk of being trapped when the swivel part is lowered. If someone or something, for example an arm or a hand, is under the raised swivel part, the swivel part only presses on the person, arm or hand under the swivel part when it is lowered with its own weight and the weight of a mattress lying on top of it, for example. The risk of crushing or injury is thus significantly reduced, and damage to the bed base or an object under the swivel part of the bed base caused by the swivel part being lowered onto the object is avoided.

In one embodiment of the invention, the freewheel is achieved by a windable traction device such as a belt, a rope or a chain, with which the spindle of the spindle drive can be driven in rotation. The traction device exerts a torque on the spindle in only one direction. The spindle drive is designed to be non-self-locking, so that when the traction device is released, it automatically resets under the effect of gravity.

In one embodiment, a further spindle drive is provided to drive the traction mechanism. This spindle drive has in particular a spindle with a right-hand and a left-hand thread, so that a tensile force can be exerted on two traction mechanisms that run along the two long sides of the bed frame. The two traction mechanisms can be used to drive two spindle drives arranged on the long sides of the bed frame. The traction mechanisms allow the drive to be easily adapted to bed frames of different widths. A further advantage of this embodiment of the invention is the synchronous drive of the two spindle drives that pivot the pivoting part and the freewheeling effected by the traction mechanisms. Furthermore, this embodiment of the invention is suitable for the joint drive of the two spindle drives that pivot the pivoting part with an electric motor.

The invention is explained in more detail below using an embodiment shown in the drawing. They show:

Figure 1 shows a bed base according to the invention in perspective view;
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Figures 2 and 3 show an electromechanical drive of the bed base from Figure 1 according to the invention; and

Figures 4 to 7 show the bed base from Figure 1 in side view in different positions.

The bed base according to the invention shown in Figure 1 and designated as a whole by 10 has a rectangular frame 12. The bed base 10 is a

Slatted frame, whereby the slats are not shown in the drawing for the sake of clarity. The bed frame 10 has a middle or base part 14, which is firmly screwed to the frame 12. On one side of the middle part 14, a first pivoting part 18 is pivotably attached with a pivot joint 16. The pivoting part 18 is in two parts, it comprises a back part 20, which is pivotably connected to the frame 12 via the pivot joint 16, and a head part 22, which is pivotably connected to the back part 20 with a pivot fitting 24.

On the other side of the middle part 14, a second pivot part 28 is pivotally connected to the frame 12 via a pivot joint 26. The second pivot part 28 is also in two parts, it comprises a thigh part 30, which is pivotally connected to the frame 12 via the pivot joint 26, and a lower leg and foot part (short: foot part) 32, which is pivotally connected to the thigh part 30 via a pivot joint 34. Pivoting axes of the pivot joints 16, 26, 34 and the pivot fitting 24 run parallel to one another and transversely to the frame 12 of the bed base 10. The pivot parts 18, 28 can also be designed as one piece (not shown). In this case, the back and head sections 22 would be rigid (one piece) with each other and likewise the thigh section 30 and the foot section 32 would be rigid (one piece) with each other, the swivel fitting 24 and the swivel joint 34 would be omitted.

The pivot fitting 24, which pivotally connects the head part 22 to the back part 20, is a triangular sheet metal part in side view, which is located on an underside of the head and back parts 22, 20 and which forms a lever arm for an electromechanical drive 36, which is shown enlarged in Figures 2 and 3 and which is described below.

The electromechanical drive 36 has a housing 38, the upper part of which is removed in Figure 2. An electric motor 40 with a worm 42, which is fixedly secured to a motor shaft, is mounted in the housing 38. The worm 42 is in engagement with a worm wheel 44, which is fixedly secured to a

Spindle 46 has a right-hand thread 48 on one side of the worm wheel 44 and a left-hand thread 50 on the other side of the worm wheel 44 . The worm 42 and the worm wheel 44 form a worm gear 42, 44, via which the spindle 46 can be driven in rotation by the electric motor 40.

A tension nut 52, 54 is engaged with the right-hand thread 48 and the left-hand thread 50 of the spindle 46, which are guided in the housing 38 in a rotationally fixed manner and can be moved in the axial direction of the spindle 46. The spindle 46 and the tension nuts 42, 54 form a spindle drive 46, 52, 54. The rotating drive of the spindle 46 moves the tension nuts 52, 54 towards or away from each other. A fabric belt 56 is attached to each tension nut 52, 54, which extends outwards as an extension of the spindle 46. The two fabric belts 56 each run in a tube 58, of which only the lower half is shown in the drawing for the sake of clarity. The tubes 58 are fixedly mounted in the housing 38, coaxial with the spindle 46; together with the housing 38, they form a cross member 38, 58 of the drive 36, which runs in the transverse direction of the bed base 10 (see Figure 1).

A telescopic drive 60 shown in Figure 3 is rigidly attached to both ends of the cross member 38, 58 comprising the housing 38 and the tubes 58. The telescopic drive 60 is arranged transversely to the cross member 38, 58, i.e. in the longitudinal direction of the bed base 10. The telescopic drive 60 has a tubular housing 62 in which two telescopic cylinders 64 are accommodated in an axially displaceable and rotationally fixed manner. The telescopic cylinders 64 have an internal thread, with one telescopic cylinder 64 having a right-hand thread and the other telescopic cylinder 64 having a left-hand thread. The telescopic cylinders 64 are in engagement with a spindle 66 which is rotatably mounted in the housing 62 of the telescopic drive 60 and which has a right-hand and a left-hand thread. In its middle between the telescopic cylinders 64, the spindle 66 has a drum 68 that is fixed to it and on which the fabric belt 56 is wound. The spindle 66 and the telescopic cylinders 64 form a spindle drive 64, 66 that is designed to be self-locking. By pulling on the fabric belt 56, which is driven by the rotating drive of the

Spindle 46 in the housing 38 can be applied via the tension nut 52, 54, the fabric belt 56 is unwound from the drum 68 of the spindle 66 of the telescopic drive 60 and the spindle 66 is driven in rotation. The rotating drive of the spindle 66 moves or pushes the telescopic cylinders 64 apart. If the fabric belt 56 is released, which is done by the opposite rotation of the spindle 46 in the housing 38, the spindle 66 of the telescopic drive 60 is set in rotation by the self-locking design of the spindle drive 64, 66 of the telescopic drive 60 when an external pressure force acts on the telescopic cylinders 64, which pushes the telescopic cylinders 64 together. The fabric belt 56 is wound onto the drum 68 of the spindle 66. The two telescopic cylinders 64 therefore do not necessarily move back, the telescopic drive 60 has a freewheel in the direction of shortening the distance between its two telescopic cylinders 64.

A drive 36, as shown in Figures 2 and 3 and explained above, is attached to an underside of the first pivoting part 18 of the bed base 10. The two telescopic drives 60 of the drive 36 are arranged in the longitudinal direction of the bed base 10 in the side area of the pivoting part 18, the cross member 38, 58 extends transversely below the first pivoting part 18. The telescopic drives 60 are supported with their one telescopic cylinder 64 on a support 70, which is fixed and protrudes downwards on the middle part 14 of the bed base 10. The other telescopic cylinder 64 engages the pivot fitting 24, which is attached to the underside of the back and head sections 22 and which forms a lever arm. As described above, the telescopic cylinders 64 of the drive 36 can be pushed apart and the first pivoting part 18 can be pivoted upwards into the position shown in Figure 1.

Various swivel positions are shown in Figures 4-7, whereby in Figures 4 - 7 a front part of the frame 12 in the direction of view is omitted to clearly show the swivel parts 18, 28. In the starting position shown in Figure 4, the back and head parts 20, 22 of the first swivel part 18 lie horizontally in the frame 12. The drive 36 is used to

Pivoting fitting 24 is pushed off the support 70 and the head part 22 is thereby initially pivoted upwards into the position shown in Figure 5, the back part 20 initially remains in its horizontal position. In the position shown in Figure 5, a pivot angle limiting pin 72 of the pivoting fitting 24 hits the back part 20 from below. The pivot angle limiting pin 72 limits the angle by which the head part 22 can be pivoted upwards relative to the back part 20. If the pivoting fitting 24 is pushed further off the support 70 with the drive 36, the back and head parts 20, 22 pivot together via the position shown in Figure 6 to the end position shown in Figures 1 and 7.

As can be clearly seen in Figures 4-7, the drive 36 pivots upwards with the first pivot part 18, it is always located a short distance below the first pivot part 18 and is therefore not in the way, particularly when the pivot part 18 is pivoted upwards.

To lower, the fabric belts 56 of the drive 36 are released as described in Figures 2 and 3. The swivel part 18 is lowered by gravity and in doing so presses together the telescopic cylinders 64 of the drive 36. If there is something in the lowering path of the first swivel part 18, the swivel part 18 rests with its weight on this something and does not move further downwards. Since the lowering of the swivel part 18 takes place in the freewheeling direction of the telescopic drives 60, the drive 36 does not exert any downward force on the swivel part 18 in order to avoid or at least reduce the risk of crushing, injury and damage.

The second pivoting part 28, which comprises the thigh part 30 and the foot part 32, has an identical drive 36 to the first pivoting part 18. This drive 36 is supported on a support 74, which is attached to the frame 12 in the area of a free end of the foot part 32 and protrudes downwards. The second drive 36 engages the thigh part 30 in the area of the pivot joint 34 between the thigh part 30 and the foot part 32. The second drive 36 can be used to move the second pivoting part 28 from the

Figure 7 shows the initial position, in which the thigh part 30 and the foot part 32 are horizontal, to the position shown in Figures 1, 4, 5 and 6, in which the thigh part 30 is pivoted upwards. The foot part 32 is connected in an articulated manner to the support 74 in the area of its foot end by a pair of pivot levers 76, so that the foot part 32 also rises when the thigh part 30 is raised. The rise of the foot part 32 at the free end is less than at the pivot axis 34, i.e. the foot part 32 is raised, but pivots downwards relative to the thigh part 30. The lowering of the thigh part 30 and the foot part 32 takes place as described above for the head and back parts 22, 20 in the freewheeling direction of the drive 36 by weight and not by a force of the drive 36.

As can be seen, the two pivoting parts 18, 28 can be provided independently of one another, i.e. also individually. It is also possible with the drive 36 according to the invention to pivot one-piece pivoting parts upwards, in which the head and back parts 22, 20 or the thigh and foot parts 30, 32 are rigidly connected to one another.

Claims (11)

franko Möbelbeschläge Franke GmbH & Co. KG, 05 March 1999 72336 Balingen-Weilstetten S/gs 647/01 Protection claims 1. Bed frame with a pivoting part which is attached to the bed frame so as to be pivotable about a pivot axis and with a drive for pivoting the pivoting part, characterized in that the drive (36) has a telescopic drive (60) which is supported on the bed frame (10) and engages the pivoting part (18; 28). 2. Bed base according to claim 1, characterized in that the telescopic drive (60) has a spindle drive (64, 66). 3. Bed base according to claim 2, characterized in that the spindle drive has a spindle (66) with a right-hand and a left-hand thread, with which two drive elements (64) are engaged, one of which is supported on the bed base (10) and the other of which engages the pivoting part (18; 28). 4. Bed base according to one of claims 1 to 3, characterized in that the drive (36) has two telescopic drives (60) which are arranged parallel to one another in the region of the longitudinal sides of the bed base (10). 5. Bed base according to claim 4, characterized in that the two telescopic drives (60) have a common energy source (40) for their drive. 6. Bed base according to claim 5, characterized in that the common energy source comprises an electric motor (40). 7. Bed base according to claim 4, characterized in that the two telescopic drives (60) are synchronized. 8. Bed base according to one of claims 1 to 7, characterized in that the drive (36) acts exclusively in one direction and has a freewheel in the opposite direction. 9. Bed base according to claim 8, characterized in that the drive (36) has a self-locking spindle drive (64, 66) which can be driven in rotation via a windable traction means (56). 10. Bed base according to claim 9, characterized in that the drive (36) has a spindle drive (46, 52, 54) for the traction means (56), wherein a tensile force can be exerted on the traction means (56) by means of the spindle drive (46, 52, 54). 11. Bed base according to claim 10, characterized in that the spindle drive (46, 52, 54) for the traction means (56) has a spindle (46) with a right-hand and a left-hand thread (48, 50), wherein the spindle (46) can exert a tensile force on two traction means (56), with which two spindle drives (64, 66) can be driven in rotation, which are arranged parallel to one another in the region of the long sides of the bed base (10) and with which the pivoting part (18; 28) can be pivoted.