EP3525630A1

EP3525630A1 - Pocket-spring core and method for producing the pocket-spring core

Info

Publication number: EP3525630A1
Application number: EP17780760.9A
Authority: EP
Inventors: Sabine Grothaus
Original assignee: Agro Holding GmbH
Current assignee: Agro Holding GmbH
Priority date: 2016-10-17
Filing date: 2017-10-09
Publication date: 2019-08-21
Anticipated expiration: 2037-10-09
Also published as: PL3525630T3; DE102016119742A1; EP3525630B1; WO2018073035A1; US11633048B2; ES2834885T3; US20190274444A1

Abstract

A pocket-spring core (1, 1a) having at least one first zone (2) and at least one second zone (3), wherein the first zone (2) has at least two rows of a first spring portion (4, 4a) and at least one of the second zones (3) has at least one row or line of a second spring portion (9, 9a), wherein the second spring portion (9) has at least two layers which are located vertically one above the other and comprise in each case a plurality of helically wound first compression springs (11), in a first, upper layer, and second compression springs (12), in a second, lower layer, and at least one row of a third spring portion (10, 10a), is distinguished in that at least one of the second zones (3) of the pocket-spring core (1, 1a) has at least one channel-like depression (17).

Description

Pocket spring core and method for producing the pocket spring core

The present invention relates to a pocket spring core according to the preamble of claim 1, a mattress or a cushion with such a pocket spring core according to claim 12 and a method for producing such a pocket spring core according to claim 1 6. It is known to carry pocket spring cores with sections of zones of different stiffness. As a result, the zones of the pocket spring core for individual body parts of a sleeper, e.g. the shoulder, feet or buttocks are performed with reduced or increased rigidity compared to other parts of the body.

From EP 1 603 434 B1, a method is known in which juxtaposed, different in height spring strands are made of eingetaschten springs together. This results in partial gaps in the surface of the pocket spring core, which are filled by filler. This filler material may consist of spring strands of pocketed springs joined together to form a partial spring core, the springs of which are dimensioned in height such that the gap is filled and results in a substantially flat lying surface.

For this purpose, the individual partial pocket spring cores, that is to say the springs of different height and those which fill a gap, are each made separately, with previously formed similar spring strands of inserted springs being connected to one another by gluing, for example.

The partial spring core which in each case fills a gap is placed in the gap formed, and the pocket spring core completed in this respect is subsequently provided with one or more cushioning layers and / or covered with a fabric, so that a pocket spring mattress or a cushion with zones of differing stiffness is produced. A disadvantage of the technical teaching of EP 1 603 434 B1 is the separate production of the respective spring strands from eingetaschten springs, which must then be assembled or assembled manually first to a part spring core and then to the total spring core. This results in particular by the production-logistical effort and usually manually to be done handling effort a complex production with correspondingly high costs.

The technical teaching of DE 10 2013 107 255 A1 has automated the assembly of separately manufactured pocket spring strands with respectively different, in particular different, high-height springs for the production of a zoned pocket feeder core by a device. As a result, the costs for producing a zoned pocket spring core have already been significantly reduced in comparison with EP 1 603 434 B1.

A disadvantage of the solution of DE 10 2013 107 255 A1 is the still required, separate production of the required pocket spring strands, each with different, in particular different levels of springs for producing a zoned pocket spring core.

In WO 03/096847 A1, a zoned pocket spring core is disclosed, in which two different springs, in particular springs of different heights, are inserted in each pocket, wherein the respective pockets of the different springs are arranged vertically one above the other, so that a pocket spring core with pocket spring strand sections arises and each pocket spring strand section has at least two layers eingetaschter springs, wherein the pockets of each spring are each closed by welds.

The technical teaching of WO 03/096847 A1 makes it possible to produce a complete pocket spring strand section or a complete spring strand with two or more layers of different springs, in particular springs of different heights, in one operation. WO 03/096847 A1 thus overcomes the disadvantage of each separate production of pocket spring strands, each with different springs. The invention has the object to provide a zoned pocket spring core, which is simpler and thus cheaper to produce compared to the prior art.

The present invention solves this problem by the subject matter of claim 1. It also provides the subject matter of claim 12 and the method of claim 1 6. According to the characterizing part of claim 1, it is provided that at least one of the second (s) zone (s) of the pocket spring core has at least one groove-like depression.

The invention is therefore based on the idea, in at least one zone or in several zones of the pocket spring core, which have a lower rigidity than other zones or another zone of the pocket spring core, the lower rigidity of this zone (s) by defined omission of springs at least partially to create. This advantageously results in a cost-optimized zoned pocket spring core.

In a preferred embodiment of the invention, the groove-like depressions extend through the entire width of the pocket spring core. This results in an advantageously simple, uncomplicated production and thus a cost-optimized zonierten pocket spring core.

In a further preferred embodiment of the invention, the second spring strand section has three vertically superimposed layers of a plurality of helically wound first compression spring in a first, upper layer, respectively second compression springs in a second, middle layer and respective first compression springs in a third, lower layer on. As a result, advantageously a part of a zone with comparatively low rigidity can be manufactured automatically. Advantageously, the height of the second spring strand section corresponds to the height of the first spring strand section. This results in an optimized support through the zoned pocket spring core. In a further preferred embodiment variant of the invention, the height of the third spring strand section is less than the height of the first spring strand section and less than the height of the second spring strand section.

It is advantageous that the textile material from which the pockets in which the pressure springs of the spring strand sections are dipped is a fleece. This results in a favorable cost manufacturability of the zonated pocket spring core.

In a further preferred embodiment of the invention, the pocket is closed by horizontal welds and vertical welds. The welds advantageous automated production of spring strands is achieved with short cycle times.

It is advantageous that the welds are made by an ultrasonic welding process. As a result, the manufacture of the zoned pocket spring core is advantageously simplified and thus made cost-effective.

In a further preferred embodiment variant of the invention, the second spring strand section and the third spring strand section of the second zone are arranged in a pattern. Advantageously, the second zone has a pattern of a single or a plurality of successive second spring strand section (s) on which a single or several successive third spring strand section (s) follows / follow.

By arranging the spring strands in a defined pattern, the cost-effective zoning of the pocket spring core can be automated and thus realized simply.

Further advantageous embodiments of the invention can be found in the dependent claims. Embodiments of the subject invention are illustrated in the drawings and will be described in more detail below. FIG. 1 shows a front view of a zoned pocket spring core according to the invention; a front view of a variant of the zoned pocket spring core of FIG. 1; a front view in section of a mattress or a cushion with a zonierten pocket spring core of Fig. 1; a front view in section of a mattress or a cushion with a zonierten pocket spring core of Fig. 2nd

In Fig. 1 is a front view of a zonierten pocket spring core 1 is shown. The pocket spring core 1 accordingly has at least one first zone 2 and at least one second zone 3. The first zone 2 differs from the second zone 3 in terms of its rigidity, the term "stiffness" meaning resistance to (elastic) deformation.

The first zone 2 has at least two rows or rows of a first spring strand section 4. The first spring strand section 4 has a plurality of similar, helically wound compression springs 5 which are each inserted individually in a pocket 6 enclosing the individual compression spring 5.

The term "row" or "row" refers to a direction transverse or perpendicular to the largest longitudinal extent of the finished zoned pocket spring core 1.

The pocket 6 is in each case made of a sheet-like, textile material, such as a fleece, the pocket 6 -related to the drawing plane of FIG. 1 - being closed by horizontal weld seams 7 and vertical weld seams 8, respectively. The weld seams 7, 8 are produced here by an ultrasonic welding process. posed. Alternatively, other welding methods for producing the welds 7, 8 are possible.

A spring strand of each individually eingetaschten compression springs 5 is usually produced as a quasi-endless strand in an automated process by a machine.

The at least two rows of the first spring strand section 4, which form the first zone 2 of the pocket spring core 1, are each formed by cutting the endless strand into the first spring strand section 4 in each case. The cutting is in each case in the region of the vertical weld 8 between two pockets 6, so that the respective pockets 6 is not damaged. The at least two rows or lines of the first spring strand section 4, which form the first zone of the pocket spring core 1, are formed by aligning, juxtaposing and gluing the contact points of the row-aligned and stranded spring strand sections 4.

The cutting of the strands into the respective spring strand sections 4 as well as the alignment, lining up and bonding of the spring strand sections 4 also take place in an automated process by a machine.

At least one of the second zone (s) 3 of the zoned spring core 1 has at least one row of a second spring strand section 9 and at least one row of a third spring strand section 10.

The second spring strand section 9 and the third spring strand section 10 are arranged in a pattern. As a pattern, a simply alternating pattern is selected as an example in FIG. It follows so after a single second spring strand section 9, a single third spring strand section 10, again followed by a single second spring strand section 9, etc.

Alternatively, other patterns in the arrangement of the second spring strand section 9 and the third spring strand section 10 in the second zone 3 of the zoned pocket spring core 1 are possible. For example, it is also possible that the second zone FIG. 3 shows a pattern of one or more consecutive second spring strand sections 9 on which a single or a plurality of successive third spring strand sections 10 follow. The second spring strand section 9 has at least two layers of a plurality of helically wound first compression springs 11 in a first, upper layer and second compression springs 12 in a second, lower layer which are vertically superimposed with respect to the plane of the drawing in FIG individually in a each individual first compression spring 1 1 enclosing pocket 13 and the respective individual second compression spring 12 enclosing pocket 14 are used.

The pockets 13, 14 are made of a sheet-like textile material, such as e.g. a fabric produced, wherein the pockets 13, 14-related to the plane of the drawing of Fig. 1 - are closed by horizontal welds 15 and vertical welds 1 6, respectively. The welds 15, 16 are here produced by an ultrasonic welding process. Alternatively, other welding methods for producing the welds 15, 1 6 are possible.

The height of the second spring strand section 9 - thus its dimension in the vertical direction with respect to the plane of the drawing of FIG. 1 - corresponds to the height of the first spring strand section 4.

A spring strand of two layers of individually eingetaschter compression springs 1 1, 12 is usually produced as a quasi-endless strand in an automated process by a machine.

The compression springs 1 1, 12 differ here by their height -also their dimension in the vertical direction with respect to the plane of the drawing of Fig. 1 - and in the winding pitch. The second compression spring 12 has a higher rigidity than the first compression spring 1 1.

The first compression spring 1 1 and the second compression spring 1 2 of the second spring strand section 9 are arranged vertically one above the other. Both compression springs 1 1, 12 act at a load in the direction of the arrow "F" in Fig. 1 so as a series circuit of compression springs. As a result, an overall stiffness of a mental equivalent spring of this series circuit sets, which is less than the stiffness of the first compression spring 1 1 with the lowest single stiffness of the series circuit of the compression springs 1 1, 12. The series connection of the compression springs 1 1, 12 thus results - at least approximately - a progressive spring constant of the mental spare spring.

The third spring strand section 10 is constructed here analogously to the first spring strand section 4. Therefore, to avoid repetition, only deviations and additions to the first spring strand section 4 will be described here. The third spring strand section 10 has a plurality of similar, helically wound second compression springs 12, which are here each individually inserted in a single second compression spring 12 enclosing pocket 14. The second compression spring 12 of the third spring strand section 10 has in comparison to the compression spring 5 of the first spring strand section 4 a lower turn pitch and a lower height.

Alternatively, the third spring strand section 10 may also comprise a plurality of layers of compression springs, which are arranged vertically one above the other. Each layer has in each case a plurality of similar, helically wound compression springs, which are each individually inserted in a pocket enclosing the individual compression spring.

It is essential that the height of the third spring strand section 10 is less than the height of the first spring strand section 4 and less than the height of the second spring strand section 9.

Due to the pattern formed by the arrangement of the second spring strand section 9 and here of the third spring strand section 10, at least one of the second zone (s) 3 of the pocket spring core 1 has groove-like depressions 17. The channel-like depressions preferably extend through the entire width of the pocket spring core 1. This advantageously results in a cost-optimized zoned pocket spring core 1. By "width" is meant the dimension of the pocket spring core 1 perpendicular to the drawing plane of FIG. The second zone (s) 3 - in particular that with the groove-like depressions 17 - has a significantly lower rigidity than the first zone 2 of the spring core 1 and is therefore arranged in areas of the spring core 1 into which certain body parts (eg shoulders or buttocks) of a sleeper should dive deeper into the spring core 1 than other body parts.

As a result of the overall progressive spring rigidity of the second zone (s) 3-in particular, that with the groove-like recesses 17, the corresponding body part of the sleeper first sinks relatively deep into the second zone 3, and then essentially through the second compression springs 12 of the second spring strand 9 and the second compression springs 12 of the third spring strand 10 to be supported. As a result, the body of the sleeper during sleep is advantageously supported in all places so that the sleeper can sleep beneficial restful.

This also results in an advantageously pleasant feel for the sleeper.

Alternatively, the pocket spring core 1 can also have more than two zones 2, 3, each with different stiffness, each of these zones being constructed either on the model of the construction of the first zone 2 or on the model of the construction of one of the second zone 3. It is essential to the invention that at least one second zone 3 has groove-shaped recesses 17 with a reduced stiffness compared to the first zone 2.

2 shows a front view of a variant of the zoned pocket spring core 1 according to FIG. 1. In order to avoid repetition, therefore, only deviations, changes or additions to the embodiment of the zoned pocket spring core 1 shown in FIG. 1 and described above will be described below. The first spring strand section 4a has a plurality of similar, helically wound compression springs 18 which are each inserted individually in a pocket 22 enclosing the individual compression spring 18. The pocket 22 is each made of a sheet-like, textile material, such as a nonwoven produced, the bag 22 -related to the drawing plane of FIG. 2- in each case by horizontal welds 23 and vertical welds 24 is closed. The welds 22, 23 are made here by an ultrasonic welding process. Alternatively, other welding methods for producing the welds 22, 23 are possible.

Deviating from the second spring strand section 9 of the second zone 3 in FIG. 1, the second spring strand section 9a of the second zone 3a with the groove-like depressions 17 has three layers of a plurality of helically wound compression springs 1, which are vertically superimposed with respect to the plane of the drawing in FIG 1, 12 on.

The layer structure of the spring strand section 9a has in each case a first compression spring 1 1 in a first, upper layer, in each case a second compression springs 12 in a second, middle layer and in each case a first compression springs 1 1 in a third, lower layer, each individually in one the respective individual first compression spring 1 1 enclosing pocket 13 and the respective individual compression spring 12 enclosing pocket 14 are used.

The height of the second spring strand section 9a -also whose dimension in the vertical direction with respect to the plane of the drawing of FIG. 2- corresponds to the height of the first spring strand 4a. The third spring strand section 10a of the second zone (s) 3a with the groove-like depressions 17 is constructed here analogously to the first spring strand 4a. Accordingly, the third spring strand 10a here has a plurality of identical, helically wound second compression springs 12 which are each inserted individually in a pocket 14 enclosing the individual second compression spring 12. Accordingly, the second compression spring 12 of the third Federstrangabschnittsl Oa compared to the compression spring 18 of the first spring strand section 4a a lower Windungssteigung and a lower height. Alternatively, the third spring strand section 10a may also comprise a plurality of layers of compression springs, which are arranged vertically one above the other. Each layer has in each case a plurality of similar, helically wound compression springs, which are each individually inserted in a pocket enclosing the individual compression spring.

It is essential that the height of the third spring strand section 10a is less than the height of the first spring strand section 4a and less than the height of the second spring strand section 9a.

The second spring strand section 9a and the third spring strand section 10a are arranged here in a pattern. As a pattern, a simply alternating pattern is chosen as an example in FIG. Thus, after a single second spring strand section 9a, there follows a single third spring strand section 10a, followed by a single second spring strand section 9a again, etc.

Alternatively, other patterns in the arrangement of the second spring strand portion 9a and the third spring strand portion 10a in the second zone (s) 3a with the groove-like recesses 17 are possible. So it is e.g. It is also possible for the second zone (s) 3a with the groove-like recesses 17 to have a pattern of in each case one or more consecutive second spring strand sections 9a on which a single or several successive third spring strand sections 10a follow. Due to the pattern formed by the arrangement of the second spring strand section 9a and the third spring strand section 10a, at least one of the second zone (s) 3a of the pocket spring core 1a has groove-like depressions 17. Deviating from the zonated pocket spring core 1 according to FIG. 1, the channel-shaped recesses 17 are located in the vertical direction above and below the second, middle compression spring 12 of the second spring strand section 9a. This advantageously results in a cost-optimized zoned pocket spring core 1 a.

In a further alternative design of the zoned pocket spring core 1a according to FIG. 2, it is also possible for the second zone (s) 3a to be provided with the groove-like depression. 17 is constructed from a pattern of mutually arranged second spring strands 9 of FIG. 1. In this case, the pattern can also each have a single or a plurality of successive second (n) spring strand section (s) 9, in which the recess 17 respectively results above the second compression springs 12 and subsequently a single or several consecutive (n) second (n) spring strand section (s) 9, in which the recess 17 results in each case below the second compression springs 12. This results in an advantageous cost-optimized zonierter pocket spring core 1 a. The zonierte pocket spring core 1 a has a symmetrical structure with respect to its front view shown in Fig. 2.

In Fig. 3 is a front view in section of a mattress 19 or a cushion with the zonierten pocket spring core 1 of FIG. 1 is shown. In order to avoid repetition, therefore, only supplements relating to the mattress 19 will be described below for the embodiment of the zoned pocket spring core 1 shown in FIG. 1 and described above. In the context of the present invention, the term "mattress" used below also applies synonymously to a cushion, for example for a sitting or lying furniture.

The mattress 19 has, in addition to the zoned spring core 1, a first cushion layer 20a and a second cushion layer 20b. The cushion layers 20a, 20b are made of an elastic material, such as e.g. a foamed plastic produced and arranged with respect to the plane of the drawing of FIG. 3 each vertically above and below the zoni- ed pocket spring core 1 over its entire extent.

The arrangement of the first cushion layer 20a, the groove-like recesses 17, which forms the zoned pocket spring core 1, covered, so that the mattress 19 channel-like hollow chambers 21 is formed. The channel-like hollow chambers 19 preferably pass through the mattress 19 over the entire width of the mattress 19. "Width" refers to the smaller extent of the lying surface of the mattress 19. The channel-like hollow chambers 21 receive aqueous secretions of the sleeper formed by transpiration during sleep that these secretions are not in the obe- ren cushioning 20a remain and thus can evaporate faster. This results in a mattress 19 with advantageously improved hygienic properties.

The mattress 19 is further completely enveloped by a textile covering material (not shown here).

In Figure 4 is a front view in section of a variant of the mattress 19 or a cushion of FIG. 3 with the zonierten pocket spring core 1 a of Fig. 2 is shown. In order to avoid repetition, therefore, only supplements which relate to the mattress 19 a according to FIG. 4 will be described below for the embodiment of the zoned pocket spring core 1 a shown in FIG. 2 and described above. In the context of the present invention, the term "mattress" used below is also synonymous with a cushion for, for example, a sitting or lying furniture 20a, 20b are made of an elastic material, such as a foamed plastic, and arranged vertically above and below the zoned pocket spring core 1a over its entire extent with respect to the plane of the drawing of Fig. 4. The mattress 19a shown in Fig. 4 becomes also referred to in the jargon as a so-called reversing mattress, since it is constructed symmetrically with respect to the front view (see Fig. 4) Further, the mattress 19a may each have different cover fabrics their lying sides, for example, a "summer side" and a "winter side" define.

The arrangement of the first cushion layer 20a, the groove-like recesses 17 which forms the zonierte pocket spring core 1 a, covered, so that the mattress 19a channel-like hollow chambers 21 a is formed. In contrast to the mattress 19 according to FIG. 3, the mattress 19a has the channel-like hollow chambers 21 analogous to the channel-like recesses 17 of the zoned pocket spring core 1 a vertically below the first cushion layer 26a and vertically above the second cushion layer 26b. The channel-like hollow chambers 21 receive aqueous secretions of the sleeper formed by transpiration during sleep, so that these secretions do not remain in the upper cushion layer 20a and can therefore evaporate faster.

This results in a mattress 19a-here a reversible mattress-with advantageously improved hygienic properties on both sides.

For producing the zoned pocket spring core 1, 1 a, the following method is given: First, wire for the compression springs 5, 1 1, 12, 18, the textile material for the pockets 6, 13, 14, 22, a machine for the automated production of endless Spring strands of eingetaschten springs, a machine for the separation of the spring strands and the alignment, juxtaposition and bonding of spring strand sections and adhesive for bonding the spring strand sections 4, 4a, 9, 9a, 10, 10a provided.

In a subsequent method step, the compression spring 5, 18 is wound by the machine for the automated production of endless spring strands of eingetaschten springs from the wire and in a at least one side opened, formed by the welds 7, 8, 23, 24 of a welding process bag 6, 22nd used from the textile material and the bag 6, 22 closed by a weld 7, 8, 23, 24 and so the first spring strand eingetaschter pressure springs 5, 18 produced. In a further method step, the first compression springs 1 1 and the second compression spring 12 are each wound through the machine and each inserted into a at least one side opened, formed by the welds 15, 1 6 a welding process pocket 13, 14 and the respective pocket 13, 14th closed by a weld 15, 1 6 and so the second spring strand eingetaschter and vertically superposed compression springs 1 1, 12 prepared. This method step preferably takes place on a second machine in parallel to the previous method step. In a subsequent method step, the second compression spring 12 is wound by the machine from the wire and inserted into a at least one side opened, formed by the welds 15, 1 6 a welding process pocket 14 of the textile material and the pocket 14 by a weld 15, 1 6 closed and so the third spring strand einetaschter compression springs 12 produced. This method step preferably takes place on a second machine in parallel to the two preceding method steps.

In a subsequent method step, the respective endless spring strand sections in the machine for the separation of the spring strands and the alignment, juxtaposition and bonding of spring strand sections 4, 4a, 9, 9a, 10, 10a are separated and the resulting spring strand sections 4, 4a, 9, 9a, 10, 10a aligned to a defined pattern and glued together so that the zonierte pocket spring core 1, 1 a is formed with at least a first zone 2 and a second zone 3, wherein at least one zone 3 of the at least two zones 2, 3 groove-like recesses 17 has.

The specified method advantageously simplifies the production of the zoned pocket spring core 1, 1a. This advantageously produces a cost-effective zoned pocket spring core 1, 1 a.

LIST OF REFERENCE NUMBERS

1, 1 a pocket spring core

2 zone

3 zone

4, 4a spring strand section

5 compression spring

6 bag

7 weld

8 weld

9, 9a spring strand section

10, 10a spring strand section

1 1 compression spring

12 compression spring

13 bag

14 bag

15 weld

16 weld

17 deepening

18 compression spring

19 mattress

20a, 20b padding position

21 hollow chamber

22 bag

23 weld

24 weld

F force

Claims

claims

Pocket spring core (1, 1 a) having at least a first zone (2) and at least a second zone (3), wherein the first zone (2) at least two rows of a first spring strand section (4, 4a) and at least one of the second zone (n ) (3) at least one row or row of a second spring strand section (9, 9a), said second spring strand section (9) at least two vertically superposed layers of a plurality of helically wound first compression springs (1 1) in a first, upper layer and second compression springs (12) in a second, lower layer and at least one row of a third spring strand section (10, 10a), characterized in that at least one of the second zone (s) (3) of the pocket spring core (1 , 1 a) has at least one groove-like depression (17).

Pocket spring core (1, 1 a) according to claim 1, characterized in that the at least one groove-like depression (17) extend through the entire width of the pocket spring core (1, 1a).

Pocket spring core (1 a) according to one of the preceding claims, characterized in that the second spring strand section (9a) three vertically superposed layers of a plurality of helically wound first compression spring (1 1) in a first, upper layer, respectively second compression springs (12) in a second, middle layer and in each case first compression springs (1 1) in a third, lower layer.

Pocket spring core (1, 1 a) according to any one of the preceding claims, characterized in that the height of the second spring strand section (9, 9a) corresponds to the height of the first spring strand section (4, 4a).

Pocket spring core (1, 1 a) according to any one of claims 1 to 4, characterized in that the third spring strand section (10, 10a) comprises a plurality of layers of compression springs which are arranged vertically one above the other. Pocket spring core (1, 1 a) according to any one of the preceding claims, characterized in that the height of the third spring strand section (10, 10a) is less than the height of the first spring strand section (4, 4a) and is less than the height of the second spring strand section ( 9, 9a).

Pocket spring core (1, 1 a) according to any one of the preceding claims, characterized in that the compression springs (5, 1 1, 12, 18) each individually in a pocket enclosing the individual compression spring (5, 1 1, 12, 18) (6 , 12, 14, 22) are used.

Pocket spring core (1, 1 a) according to claim 7, characterized in that the pocket (6, 12, 14, 22) is in each case made of a sheet-like textile material, in particular made of non-woven.

Pocket spring core (1, 1 a) according to any one of claims 7 or 8, characterized in that the pocket (6, 12, 14, 22) respectively by horizontal

Weld seams (7, 15, 23) and vertical welds (8, 1 6, 24) is closed.

Pocket spring core (1, 1 a) according to claim 9, characterized in that the welds (7, 8, 15, 1 6, 23, 24) are made by an ultrasonic welding process.

Pocket spring core (1, 1 a) according to any one of the preceding claims, characterized in that the at least one second zone (3) has a pattern of a single or several consecutive second Fe strand strandabschnitt (s) (9, 9a) on which one or more consecutive third spring strand section (s) (10, 10a) follows / follow.

Mattress or upholstery (19, 19a) with a pocket spring core (1, 1a) according to one of claims 1 to 11 or the preamble of claim 1 and a first cushion layer (20a) which is arranged vertically above the pocket spring core (1, 1a) and a second cushion layer (20b) vertically below the tab. The spring mat (1, 1 a) is arranged, characterized in that the mattress or pad (19, 19a) between the pocket spring core (1, 1 a) and the first cushion layer (20a) channel-like hollow chambers (21) is formed. 13. Mattress or upholstery (19, 19a) according to claim 12, characterized in that the mattress or upholstery (19, 19a) between the pocket spring core (1, 1a) and the first cushion layer (20a) and the second cushion layer (20b ) Channel-like hollow chambers (21) is formed. 14. mattress or upholstery (19,19a) according to any one of claims 12 or 13, characterized in that the channel-like hollow chambers (21) pass through the mattress (19, 19a) over the entire width of the mattress (19, 19a).

Mattress or upholstery (19, 19a) according to one of Claims 12 to 14, characterized in that the mattress (19, 19a) is completely enveloped by a textile covering material.

16. A method for producing a pocket spring core (1, 1 a) according to any one of claims 1 to 1 1, characterized by the following method steps:

Providing wire, and a textile material, a machine for the automated production of endless spring strands from pocketed springs, a machine for separating the spring strands and the alignment, juxtaposition and bonding of spring strand sections and adhesive. b) producing a first spring strand eingetaschter pressure springs 5, 18; c) producing a second spring strand eingetaschter and vertically stacked compression springs 1 1, 12;

Producing a third spring strand eingetaschter compression springs 12; e) separating the respective spring strand eingetaschter compression spring (5,18; 1 1, 12, 12) in the respective spring strand sections (4, 4a, 9, 9a, 10, 10a) and Ausgerichten, juxtaposing a defined pattern and bonding of the spring strand sections (4, 4a, 9, 9a, 10, 10a) to a pocket spring core (1, 1a) such that the zoned pocket spring core (1, 1a) is provided with at least one first zone (2) and one second zone (3). is formed, wherein at least one of the first zone (s) (3) of the at least two zones (2, 3) has groove-like depressions (17).