DE7329565U - - Google Patents

Description

The invention relates to a plastic spring for armchairs or Sofas.

It is common practice to use wire coil springs in the construction of many armchairs and sofas. The use of such Coil springs and their connection with an armchair or The sofa frame is very expensive.

The aim of the invention is to create a more elaborate Spring device.

Advantageously, according to the invention, instead of a Helical spring made from Dr «.ht a specially designed plastic

BERLIN: TELEPHONE (O31t) 76 1007

CABLE: PROPINDUS ■ TELEX O1 Θ4007

MUNICH: TELEFON IOB11) 23 ^Γ · ΜΙ5 KABE I .: PROPIN D U H ■ TL LL: X Du 'JI V 4 -I

spring used.

A corrugated plastic spring according to the invention advantageously has a non-linear spring constant or spring characteristic.

In an advantageous embodiment, the shape has a corrugated Plastic spring a short compressed height to «

The invention is exemplified below with reference to the drawings described. It shows

Fig. 1 is a sectional view of a corrugated plastic spring;

FIG. 2 is a sectional view of the corrugated shown in FIG Synthetic spring in fully compressed State;

3 is a partial sectional view of a modification of FIG in Fig. 1 spring shown;

Fig. 4 is a partially sectional view of another modification the spring shown in Figure 1;

Fig. 5 is a partially sectional view of another modification the spring shown in Figure 1;

Fig. 6 is a partially sectional view of another modification the spring shown in Figure 1;

Fig. 7 is a partially sectional view of another modification the spring shown in Figure 1; and

FIG. 8 is a partial sectional view of a modification of the spring shown in FIG.

According to FIG. 1, a spring 10 is between a force transmission element 11 and a? Support member 13 supported. The spring can either rest loosely on the support member 13 or be fixedly connected thereto by an adhesive or other known device and the force transmitting member 11 can either rest loosely on the spring or be connected thereto by an adhesive or other known device. The force-transmitting element can represent a sofa bed and the support element 13 can represent a sofa frame. According to the drawing, the spring comprises a tubular, corrugated, thin-walled plastic member which has a plurality of peaks or elevations and valleys which are arranged around the longitudinal axis AA of the spring at varying distances therefrom. Each elevation 12 und.1 ^ and each valley 16, 18 includes a rohrformige Vand, which in cross section is flat and generally parallel to the axis AA. The side walls 20 and 22 of one valley and 2k and 26 of an adjacent valley are generally frustoconical in shape and form an angle ds the tilt of the axis of the spring which can vary between 85 ° and 60 °. The larger diameter edges 30 of the side walls are provided integrally with an edge of an associated elevation wall and the smaller diameter edges 32 of the side walls are provided integrally with an edge of an associated one of the bottom walls of an associated valley. According to FIG. 1, all bottoms 16 of the valleys have the smooth circumscribing radius RL around the longitudinal axis AA and all bottoms have the same circumscribing radius r. around the longitudinal axis,

where the radius r ^ is smaller than the radius R ^. All elevations \ k have the same circumscribing radius R around the longitudinal axis AA and all elevations 12 have the same circumscribing radius r around the longitudinal axis, the

Radius r smaller than the radius R is " P P

The oblique width "V ^M of the wall 26 is the large-te width followed by the slanting width of the walls 2k _t 22 and 20 in size episode" The Umsohreibungsradien of the walls can be varied depending on the desired characteristic, wherein the inclined width ^W W ^W of the walls 22 and 2k equal or the inclined width of the wall 22 can be greater or smaller than the inclined width of the wall 2k ,

If the spring is under a load ^H F ^M , which has been applied to the force-transmitting member 11, the side walls are stressed or placed under tension or deformed, as shown in FIG the frustoconical side walls are released and these return to their original unloaded position, expanding the spring back into its unloaded position. «Air passages (not shown) can be provided in the spring so that the spring can be compressed and expanded»

The spring is produced by extruding a tubular measuring shape or an egg-shaped, tubular blank and placing it in a mold and then blowing it into shape in order to expand the blank into the contour of the shape. The blank has the same length as the shape. With a special spring design, the outer diameter of the blank is around 38 ° h of the largest elevation

Aussendurchmeseere, about 40 fo the smallest bump outer Messere, about 52 ft of the smallest valley-outer Messere and about 50% of the valley-gröseten outside diameter. The thickness of the blank is about 7 1/2 times the mean thickness of the spring after it is formed. Since the spring is corrugated, the longitudinal surface area is 180 $ of the original length of the blank. Thus, the spring comprises a polymer that is biaxially stretched or stretched or stretched. Due to the biaxial stretching, the wall thickness of the spring decreases as the diameter of the spring increases. For example, with the particular spring design, the blank was approximately 4.67 mm (184 mils) thick and the thickness of the valley floor wall 18 was approximately 1.1 mm (43 mils), the thickness of the valley floor wall 16 was approximately 1.02 mm (40 mils), the thickness of the land wall 12 is about 0.51 mm (20 mils) and the thickness of the land wall 14 is about 0.23 mm (9 mils). This biaxial stretching creates a firmer spring and increases its fatigue life

The spring 10 has two spring constants, the walls 20 and 24 having a larger spring constant than that Walls 22 and 26 have. This characteristic plus the fact that the spring is blow molded leads to a non-linear force-displacement curve generally similar to that of a conical coil spring Wire.

The primary purpose of alternating the radii of the valley floors 16 and 18 and d <* r elevations 12 and 14 consists of a Provide a short height for the fully compressed spring, since the valley floors and elevations telescope into one another are displaceable, as shown in FIG.

When all valley floors and elevations have the same radius would, the amount would be fully compressed

much
Bigger spring, because the valley floors would lie against each other. A short, fully compressed spring is an advantage for the furniture and hence this design is very advantageous.

The difference in the radii of the bottom walls 16 and 18 should be at least equal to the thickness of the bottom wall and the difference in the radii of the elevations 12 and 14 at least equal be the thickness of the elevation wall. The ratio of the two different radii of the valley floors should be 1-1 / 211 and that Do not exceed the ratio of the two different radii of the elevations 1-1 / 2: 1. The maximum elevation radius should not be more than three times the minimum valley floor radius be. The wall thickness of the valley floor should not be more than 18 times the thickness of the wall thickness at the Elevation amount.

The wall thickness of the spring can range from about 0.12 mm to 2.3 mm (5 mils to 90 rails). If the If the wall thickness is less than 0.12 mm (5 mils), the spring rate is too low for an effective spring for the most use cases and buckling of the spring walls can occur. If the wall thickness is over 2.3 now (90 mils) the spring constant is too high for an effective spring for most applications »

The preferred plastic is polypropylene due to its crystal structure, high modulus, low cost, Processability and excellent flex life characteristics · Other plastic materials can also be used can be used, but they are not considered to be as beneficial as polypropylene.

In certain designs, the combined axial lengths of the wall / Talböderi 16 and 18 can be greater than those
combined axial lengths of the walls of the bumps 12
and Ik be such that when the radii of the bumps
equal and the radii of the valley are equal, the valley floor walls touch each other while a gap
between some of the surveys or all of the surveys
In this case, only the radii of the valley floors need to be varied, as illustrated in Pig. 3 _; to allow a telescopic movement of the valley floors and thereby shorten the length of the compressed faders. In other designs, the combined axial lengths of the walls of the elevations 12 and Ik can be greater than the combined axial lengths of the walls of the valley floors i6 and 18, so that when the radii of the elevations are the same and the radii of the valley floors are the same, the elevation walls are against one another concern while
Space between some or all of the valley floors
remains. In this case, according to the invention, only need
the radii of the elevation walls to be varied, as illustrated in Fig. k , to allow a telekop-like movement of the elevation walls and thereby shorten the length of the compressed spring a ⁿ a ⁿ and ^w b ^w in Fig. 3 and « k respectively.

The spring according to any of the embodiments described above can be further modified by converting either the valley floor wall or the ridge wall or both into a curved or generally U-shaped "
Wall can be modified without affecting the functional

stocks of the Fed-SR will be adversely affected. The open ends of the curved elevation or the curved valley floor merge into an associated side wall of the valley. These modifications e: .ND in don Figures 5 »6 and 7 illustrated in which like elements as in Figure 1 with the same Bezugszeiohen the addition of a ^w c" for the embodiment shown in Fig modification of a ^w d ^M for the in.. 6 and an "e" for the modification shown in Fig. 7. The curved valley floor walls are denoted by the reference numerals 200 and 202 in Fig., The curved elevations are denoted by the numerals 300 and 302 in Fig. 6, the curved peaks are denoted by reference numerals 3 ^ and 306, and the curved valleys are denoted by reference numerals J08 and 310 in FIG.

While sidewalls 20, 22, 2k and 26 have been described as generally planar in cross-section, they may be sloped or curved or concave-co-uvex, as shown in Figure 8, in which the same Elements as in Fig. 1 are denoted by the same reference numerals with the addition of an * f ⁿ «Each pair of side walls 402 and kOk and 406 and 408, which are connected to a common elevation, have their concave surfaces facing one another. The walls are bevelled in such a way that a profile chord or chord line "c", which connects the edge with the larger diameter of each wall with its associated inner edge with the smaller diameter, forms an angle fy with the axis of the spring that is between 85 ° and 6o ° can vary.

Springs made of plastic or with areas at different distances from the longitudinal axis of the spring are from the U.S. Patents 3,118,659 and 3,305,227 are known.

Claims (15)

Expectations 1. Spring, especially for armchairs or sofas, characterized in that it is biaxially streokt that a hollow corrugated jacket (1O) with a plurality of annular elevations (12,1 ^ f) and annular valleys (16,18), the each of the projections (12,14) separate from the other, it is provided that a first group yon valley floors (16) 1st arranged so that these SiOH are located at a first distance from the longitudinal axis of the spring (1O), that a second group of valley floors (18) is arranged so that they are at a second distance from the longitudinal axis (AA) of the spring (10), that the groups of valley floors (16,18) are arranged so that a floor (16) a Group alternates with a floor (18) of the other group, that the first distance is greater than the second distance by at least the wall thickness of the spring ax * the Taib floors, that a plurality of side walls (20,22,24,26) for each valley it is provided that each side wall is a generally frustoconical Ge stalt, wherein the edge of a smaller diameter is integrally connected to an edge of an associated valley floor and the edge of a larger diameter is integrally connected to an edge of an associated elevation, that the side walls (20,22,2 ^, 20) are integral with a common elevation are provided and differ from one another and
yaw that the thickness of any part of the feather jacket (10) does not exceed about 2.3 mm (about 90 mils). 2. Spring according to claim 1, characterized gekeiinzeii clinet that a first group of elevations (12) at a third distance from the Längsanliae (AA) of the spring (io) is arranged that a second group of elevations ("Hf) in one fourth distance from the longitudinal axis (AA) of the spring (1O) is arranged, that the first and second group of elevations are arranged such that one elevation (12) of one group alternates with an elevation 0 * 0 of the other group, and that the third distance is larger than the fourth distance. 3. Spring according to claim 1, characterized in _t that all elevations (12 »1 Ό at the same distance from the longitudinal axis (AA) of the spring (10) are arranged. h _m spring according to claim 1, characterized in _t that the side walls (20,22,24,26) between 60 ° and 85 ° with respect to the longitudinal axis (AA) of the spring (1O) are inclined. 5. Spring according to claim k _t, characterized in that the circumferential friction radius of the elevation farthest away from the spring axis (AA) is no more than three times the circumferential friction radius of the valley floor (18) closest to the axis (AA), and that the strength of the the valley floor wall (ί8) closest to the axis (AA) is no more than 18 times the thickness of the elevation furthest away from the axis (AA) (1 * O, 6. Spring according to claim 2, characterized in that the side walls (20,22,2 ^, 26) between 60 ° and 85 ° in With respect to the longitudinal axis (A-A) of the spring (10) are inclined. 7. Spring according to claim ¹ . 6, characterized in that the original writing radius of the elevation furthest away from the spring axis (AA) 0 * 0 is not more than three times the circumferential radius of the axis . and (A-AJ nearest valley floor is that the Thickness of the valley floor wall closest to the axis (A-A) not more than 18 times the thickness of the elevation (i'l) furthest away from the axis (A-A) is " 8. Spring according to claim 7 »characterized in that the ratio of the different radii of description (R ,, r.) Of the valley floors (16,18) is not greater than 1-1 / 2s1, and that the ratio of the different Uaischreibungsradien (R _f r) of the elevations (12, 14) is not greater than 1-1 / 2: 1. 9. Spring according to one of claims 1 to 8, characterized in that that the side walls (20,22,24,2b) are generally flat in cross-section. 10. Spring according to one of claims 1 to 8, characterized in that the side walls (402, kOk, Uo6, ^ 08) are generally concavo-convex in cross-section, and that is connected to a common elevation (12.1 k) Pair of side walls with their concave surfaces facing each other, 11. Spring according to one of claims 1 to 8, characterized in that that the valley floors (16.18) and elevations (12,1U) flat in cross-section and generally parallel to the longitudinal axis of the spring (10). • · -12- 12, spring according to one of claims 1 to 8, characterized in that _t the valley floors (16 _t 18) and projections (12,14) in cross section are U-shaped and pass with their open ends in an associated one of the side walls, 13 · Spring according to one of claims 1 to 8, characterized in that that it is made of polypropylene. 14, spring, in particular for armchairs or sofas, characterized in that si λ is stretched biaxially that ^ in a hollow, corrugated jacket (1O) with a large number of annular elevations (12,14) and annular valleys (16,18), which separate each of the elevations from the other, it is provided that a first group of elevations (12) at a first distance from the longitudinal axis (AA) of the spring (1O) and a second group of elevations (ik) at a second distance from the longitudinal axis (AA) of the spring (ΐθ) is arranged, that the groups of elevations are arranged such that an elevation (12) of one group alternates with an elevation (Ik) of the other group, from the first distance by at least the wall thickness of the Spring on the bumps is greater than the second distance, that a plurality of side walls (20,22,2 ^, 26) is provided for each valley, that each side wall has a generally frustoconical shape, the edge of smaller diameter with a Ka nth of an assigned valley floor and the edge with a larger one with
Diameter of an edge of an associated elevation is integrally provided that the side walls (20,22, 2't, 26), which are provided integrally with a common elevation (12,14), diverge from one another, and that the strength of any part of the feather jacket is about 2.3 rom (about 90 rails) does not exceed, 15. Spring according to spoke i4, characterized in that the bottoms (i6 _f 18) of the valleys are arranged at the same distance from the longitudinal axis (A- »a) of the spring (1O). 16, spring according to claim 14 or 15 »characterized in that the side walls (20,22,24,26) are inclined between 60 and with respect to the longitudinal axis (AA) of the spring β 17 · Spring according to claim 16, characterized in that the Umschreibungsradius (R) of the elevation (14) furthest away from the spring axis is no longer than three times the circumscribing radius (r,) des the axis closest to the valley floor (l8.) is, and that the thickness of the valley floor wall closest to the axis is not more than 18 times the thickness of the the elevation furthest from the axis. 18, spring according to one of claims \ k to 17 », characterized in that the ring-shaped elevations (304, 306) and the ring-shaped valleys (308, 310) are U-shaped in cross-section, and that their open ends in an associated one of the side walls (20 , 22,24,26) go over.