Slatted base having a frame and a measuring device

Abstract

A slatted base having a frame and a measuring device for detecting the deformation of a lying surface under the load of a person lying thereon, wherein the deformation is carried out by detecting the vertical deflection of slats, which are held on both sides in a slatted base with their free ends in a mounting body, on which the displaceable end of a vertically oriented lifting drive engages, which is supported with respect to a bottom-side base frame, wherein the mutual horizontal distances between the slats is adjustable and fixable.

Claims

1. A slatted base comprising: a bottom-side base frame; slats held on two longitudinal sides of the slatted base, the slats being separated from one another in mutual horizontal adjustable and fixable distances; a measuring device for detecting deformation of a lying surface under a load of a person lying thereon, wherein the measuring device detects vertical deflection of the slats; a mounting body holding free ends of the slats; a vertically oriented lifting drive having lifting spindle and a displaceable end that is engaged on the mounting body the vertically oriented lifting drive being supported with respect to the bottom-side base frame; a longitudinal guide arranged in a directionally horizontal orientation on the mounting body; and a guide pin engaging in the longitudinal guide, which is connected with a free, vertically displaceable end of the lifting spindle of the lifting drive.

2. The slatted base according to claim 1, wherein the free ends of the slats, which are provided in pairs, are respectively accommodated in an insertion pocket of a bearing element, and the bearing element is connected with the interposition of a spring body with the mounting body.

3. The slatted base according to claim 1, further comprising at least one pin arranged in a directionally horizontal orientation on the mounting body, the at least one pin displaceably engaging in the horizontal direction in a longitudinal guide of a guide block, which is connected with a free, vertically displaceable end of a lifting spindle of the lifting drive.

4. The slatted base according to claim 1, wherein the vertically displaceable guide between the lift-adjustable mounting body and the bottom-side base frame comprises a height-adjustable longitudinal guide comprising a grid plate fixed on the mounting body, and a clipping plate which is configured to be fixed on a frame side.

5. The slatted base according to claim 4, wherein the frame-side clipping plate is held displaceably and fixably in a guide groove on the inner longitudinal beam of the bottom-side base frame.

6. The slatted base according to claim 5, wherein the clipping plate is connected with a clipping element which engages in a guide groove, the clipping element being arranged on the hand-actuated locking hooks, which engage form-lockingly in the locked position in a toothing of a locking rail arranged in the guide groove.

7. The slatted base according to claim 1, further comprising a locking part fixed on the clipping plate, wherein the locking part supports a scale on a front side of the locking part which is associated with a displaceable position indicator on a frame side of the locking part.

8. The slatted base according to claim 7, wherein the position indicator has an indicator line oriented against the scale and is displaceably and fixably accommodated in a longitudinal groove on the outer longitudinal beam with a slot nut and a knurled screw interacting therewith.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention is hereinafter described in greater detail with reference to drawings showing only one possible embodiment. From the drawings and their description follow further features and advantages essential to the invention.

(2) FIG. 1: shows a perspective top view of a measurement bed according to the invention.

(3) FIG. 2: shows an enlarged cross-section through the left side of the measurement bed of FIG. 1.

(4) FIG. 3: shows a cross-section through the measurement bed of FIG. 1 over the entire width.

(5) FIG. 4: shows an exploded view of the individual elements of the measurement bed on the left side.

(6) FIG. 5: shows a view rotated by an angular degree with respect to FIG. 4.

(7) FIG. 6: shows the top view of the measurement bed with the position indicator system.

(8) FIG. 7: shows a schematic representation of the mounting body without the stop.

DETAILED DESCRIPTION

(9) In the FIGS. 1 to 3 is generally shown a measurement bed 1, which substantially comprises a bottom-side base frame 2 having longitudinal beams 52 which are arranged at a mutually parallel distance, which are respectively braced in the transverse direction thereto by means of transverse braces 28, and on the longitudinal beams 52, vertically aligned struts 53 are respectively arranged at a mutual distance, which as a whole carry the measurement frame.

(10) The measurement frame comprises outer longitudinal beams 3, which are respectively supported on their end faces by means of transverse beams 5, 6, wherein the outer longitudinal beams 3 are associated with inner longitudinal beams 13.

(11) A respective servomotor 7see FIG. 6is positioned on each transverse brace 28, which in each case executes the lifting drive of the bearing elements 15 of the slats 12.

(12) A servomotor 7 is thus provided for each pair of slats 12, which is respectively arranged on the side of the longitudinal beam 52 in the region of a transverse brace 28.

(13) According to FIGS. 1 to 3, each servomotor 7 rotationally drives a drive shaft 8, which extends through an angular gear 9.

(14) According to FIGS. 4 and 5, the lifting drive is formed from a lifting spindle 27, which is led parallel through two mutually longitudinally led lifting columns 49. The upper end of the lifting spindle 27 is accommodated in a guide block 23.

(15) In the central region of the transverse brace 28, a number of measurement sensors 10 are arranged which lie behind one another and which form a visual alignment, said measurement sensors contactlessly determining the vertical deflection and downward deflection of the slat pair 12 lying thereabove.

(16) Respective pairs of combined slats 12 comprise on their undersides a metallic measurement plate 14, which forms the measurement element for the measurement sensor 10 lying thereunder.

(17) The horizontal longitudinal extent of the measurement plate 14 is selected to be so large that any desired position of displacement of the respective slat 12 in the Y direction generates a reliable signal in the measurement sensor 10 lying thereunder.

(18) In this way, the deflection and downward deflection of the respective pair of slats 12 can be steplessly detected independent of the displacement position of the respective mounting body 21 which receives the slats 12.

(19) Each end of the slat 12 is received in an insertion pocket 16 according to FIG. 2, and the insertion pocket 16 is a part of the bearing element 15.

(20) The bearing element 15 thus respectively receives the free end of the slat 12, and a hardness adjustment element 17 is arranged at the inwardly oriented end of the bearing element 15, with which the slat hardness of the spring body 20 lying thereunder can be adjusted.

(21) The mounting body 21 is a plastic part having two superimposed cones 22a, 22b. The upper pin 22a engages in an associated receiving opening 18 of the mounting body 21 and thus holds the spring body 20 fixed to the mounting body 21, while the lower pin 22b horizontally displaceably engages in a longitudinal guide 36 on the guide block 23 of the lifting apparatus which is oriented in the horizontal and the longitudinal direction of the longitudinal beam.

(22) In this way, the entire mounting body 21 is displaceably supported in the guide block 23 of the lifting apparatus.

(23) To the mounting body 21 further belongs a grid plate 43 which is fixedly connected therewith, in which grid plate are provided a number of mutually parallel horizontal slots 48 which are spaced apart from one another.

(24) The grid plate 43 arranged on the mounting body 21 engages in the manner of a vertical longitudinal guide 44 in associated receiving grooves on the opposite part, which is designated as the clipping plate 29.

(25) The downward displacement of the mounting body 21 in the longitudinal guide 44 of the grid plate 43 is limited by the stop 35. The stop 35 in this case is preferably arranged on the grid plate 43.

(26) The clipping plate 29 thus forms a U-shaped vertical longitudinal guide which opens toward the back in the direction of the oppositely located grid plate 43, wherein this clipping plate in turn has a number of superimposed mutually engaging slots 42 which are spaced apart.

(27) The clipping plate 29 accordingly consists of a longitudinally aligned clipping element 40, which is respectively limited to the left and right by locking hooks 60.

(28) The locking hooks 60 are initially disengaged from the associated toothing in the region of the locking rail 47 within the guide groove 4 in the longitudinal beam 13.

(29) In order to displace the clipping plate 29 into the guide groove 4, the snap closures 46 are first actuated by hand, in order to enable a stepless displacement.

(30) After the establishment of the desired position, the snap closures 46 are released and the locking hooks 60 snap into the associated fixed position in the region of the toothing of the locking rail 47 arranged on the longitudinal beam side.

(31) In this way, the horizontal displacement position of the clipping plate 29 is fixed on the respective longitudinal beam 13.

(32) It is thus made clear that through the engagement of the pin 22b on the mounting body 21, a stepless horizontal displacement of the entire mounting body 21 occurs in the region of the guide block 23 of the lifting device.

(33) At the same time, due to the longitudinal guide 44, the entire mounting body can be displaced in height by means of the lifting apparatus with respect to the clipping plate 29 fixed on the beam side.

(34) Thus, it is possible for the first time to ensure a displacement of the mounting body 21 both in the X direction (directional arrow 50) and in the Y direction (directional arrow 51).

(35) The drive shaft 8 is rotatably supported by guide sleeves 25 respectively extending in the transverse direction, wherein in this region is respectively provided a limit switch 37 in order to limit the lifting of the lifting spindle 27. It is thus prevented that the lifting spindle 27 falls out of its displacement guide into the angle gear 9.

(36) The drive shaft 8 rotates, for example, in the direction of arrow 26, or in the opposite direction thereto.

(37) The respective servomotor 7 is fixed to the bearing flange 38 on the inside of the longitudinal beam 13.

(38) The clipping plate 29 is a plastic part, in the associated slots 42 of which the protruding pins 40 of the locking part 39 are releasably fixed. The locking part 39 comprises a front-side scale 41.

(39) According to FIG. 4, a number of zero positions 59 are marked on the longitudinal beam side, said zero positions being mutually parallel and arranged at an equal or unequal spacing from one another.

(40) A number of position indicators 55 are therefore displaceably arranged on the outer longitudinal beam 3 for marking the displacement position of the individual mounting body 21 in the longitudinal beam 3.

(41) Each position indicator has an inner slot nut 57, which engages in an associated longitudinal groove 54 on the outer side of the outer longitudinal beam 3.

(42) The slot nut 57 can be fixed in the longitudinal groove 54 by means of a knurled screw 56.

(43) In the zero position, the indicator line 58 indicates the zero value of the scale 41 on the locking part 39.

(44) Thus, any desired horizontal displacement position in the direction of arrows 50 of the respective mounting body 21, which accommodates the paired slats 12, can be repeatably read from the frame side.

(45) In this way, during the test setupsee the general introduction of the specificationthe mutual distances of the slat pairs can be individually adjusted to one another in the horizontal direction (direction of arrow 50), and the thus-read value is then read in comparison with the indicator line 58 at the associated scale value of the scale 41.

(46) After the displacement of the position indicator 55 with a lying surface loaded by the subject, the subject then leaves the lying surface, and with an unloaded lying surface the mounting body 21 is now displaced through the engagement of the pin 22b in the longitudinal guide 36 on the guide block 23 in the direction of arrow 50, until the indicator line of the position indicator 55 again indicates the zero position of the scale 41 on the locking part 39.

(47) Each position of the mutual spacing of the slat pairs is thus found.

(48) An individual adjustment of the slat pairs in the horizontal direction (direction of arrow 50) which is thus produced on the measurement bed is then transferred to a slatted base which is individually adjustable to the subject, wherein the scale values are transferred to the scale 41 of a lying surface associated with the subject and a slatted base associated therewith.

(49) FIG. 7 shows a further preferred embodiment, wherein the grid plate 43 does not have a stop 35.

(50) The two pins 22a and 22b form a type of downward translation in the series frame. If one places the spring element 15 on the lower bolt, one thus obtains a deeper sinking of the slat pair than if only the pin 22a were present. It is crucial here that the mounting part 21 does not dip deeper than the lower edge of the clipping plate 29. This is an important prerequisite in series frames, so that no conflict may arise during insertion of the frame into different bedsteads.

(51) This effect can be achieved in the embodiment according to the invention without a repositioning of the spring element 21, in that it is possible to sink the mounting plate 21 deeper. Here, the spring element 15 lies at position 22a.

(52) Instead of the permitted five grids which are formed by the slots 48, the measurement bed travels continuously downward at all positions during a downward sinking, which arises from the manual translation by means of pins 22a and 22b.

LEGEND OF DRAWINGS

(53) 1 Measurement bed 2 Base frame 3 Outer longitudinal beam 4 Guide groove 5 Transverse beam 6 Transverse beam 7 Servomotor 8 Drive shaft 9 Angle gear 10 Measurement sensor 11 Connecting plate 12 Slat 13 Inner longitudinal beam 14 Measurement plate 15 Bearing element 16 Insertion pocket 17 Hardness adjustment element 18 Receiving opening 19 20 Spring body 21 Mounting body 22 Pin (of 21) a top, b bottom 23 Guide block 24 25 Guide sleeve 26 Directional arrow 27 Lifting spindle 28 Transverse brace 29 Clipping plate 30 31 32 33 34 35 Stop 36 Longitudinal guide (in 23) 37 Limit switch 38 Bearing flange 39 Locking part 40 Pin 41 Scale 42 Slot 43 Grid plate 44 Longitudinal guide 45 Clipping element 46 Snap closure 47 Locking rail 48 Slots (of 43) 49 Lifting column 50 Directional arrow 51 Directional arrow 52 Longitudinal beam 53 Strut 54 Longitudinal groove 55 Position indicator 56 Knurled screw 57 Slot nut 58 Indicator line 59 Zero position 60 Locking hook