WO2020109558A1 - Method for producing a spring assembly, spring assembly and spring of a spring assembly - Google Patents

Abstract

The invention relates to a method for producing a spring assembly (30), comprising a spring (10) and at least one attachment part (40). The method comprises the following steps: a) providing a spring (10), in particular a coil spring or a torsion bar spring, at least sections of which is formed from a fibre composite material with a matrix and fibres, wherein, in the region of the fibre composite material, the spring (10) has at least one connection section (20) for attaching an attachment part (40); b) introducing through-openings (50) and/or depressions (60) into the connection section (20) at least in sections; and c) attaching the attachment part (40) at the connection section (20) by means of a shaping method.

Description

Method of making a spring assembly, spring assembly and

Spring of a spring assembly

description

The invention relates to a method for producing a spring assembly, comprising a spring and at least one attachment, according to the preamble of claim 1. Furthermore, the invention relates to a spring assembly and a spring, which at least in sections consists of a fiber composite material with a matrix and fibers is formed.

It is known to produce springs, in particular helical springs or torsion bar springs, from fiber composite materials. The connection of such springs made of fiber composite materials with attachments such. B. with spring washers or

Spring pads, however, are problematic. Such attachments are often made of plastic, fiber composite materials or elastomers.

Previously known connection methods, such as. B. the gluing of the components, do not offer a permanent positive connection between the spring and the associated attachments. After the corresponding connection has become tired, there are often relative movements between the components, which can lead to damage to the contact surfaces. It is also known that

Dirt particles and / or liquids can penetrate into the gap between a spring and an associated attachment. This leads to an abrasive or corrosive removal of the components. Abrasive or corrosive phenomena, in particular in the case of components which are formed from fiber composite plastics or plastics, can lead to early failures of the components.

From the above, it is the object of the present invention to provide a method for producing a spring assembly, in particular a method for connecting a spring assembly, which results in a permanent positive connection between a spring and at least one

Attachment leads. Due to the spring assembly produced according to the invention, relative movements between the components are to be prevented.

Furthermore, on the basis of the method according to the invention for producing a spring assembly, such a connection is to be made available which prevents the penetration of dirt particles and / or liquids into the

Prevents connection area between the spring and an attachment. Furthermore, the task is to specify a further developed spring assembly and a further developed spring.

According to the invention, this object is achieved with regard to the method for

Manufacture of a spring assembly by the subject matter of claim 1, with respect to the spring assembly by the subject matter of claim 6 and in terms of the spring by the subject matter of claim 7 solved.

Advantageous and expedient embodiments of the invention

Methods for producing a spring assembly and the spring according to the invention are specified in the subclaims.

The invention is based on the idea of specifying a method for producing a spring assembly which comprises a spring and at least one add-on part, the method comprising the following method steps: a) providing a spring, in particular a helical spring or a torsion bar spring, at least in sections from a

Fiber composite material is formed with a matrix and fibers, the spring in the region of the fiber composite material at least one

Has connecting portion for attaching an attachment; b) at least sections of openings and / or

Depressions in the connecting section; c) attaching the attachment to the connecting section by means of a

Archetype process.

In step a), the method according to the invention is initially based on provided springs which are formed from a fiber composite material.

The springs are selected from a group of helical springs, in particular helical compression springs, tension coil springs, conical springs, spring springs,

Bending springs, particularly preferably spiral springs, twisted torsion springs, or torsion bar springs, in particular stabilizers and combinations thereof. The fiber composite material can in particular be

act carbon fiber reinforced plastic (CFRP). Furthermore, the fiber composite material can be glass fiber reinforced plastic (GRP).

In general, the fiber composite material can be formed from mineral or organic fibers and a resinous base material. Furthermore, it is possible that the fiber composite material is based on a mixed material with glass and carbon fiber layers.

It is possible that the fiber composite material has several fiber layers.

A fiber layer can comprise several fibers woven together. Furthermore, it is possible for a fiber layer to comprise unidirectional fiber bundles or to consist of unidirectional fiber bundles. A fiber layer can

for example a mat or a fabric or a scrim or a mesh or a random fiber mat or a non-woven or a 3D fabric or a 2D fabric or a knitted fabric.

The matrix of the fiber composite material of the spring can be formed from thermoplastic and / or elastomer and / or duroplastic. In a particularly preferred embodiment of the invention, the matrix consists of epoxy resin.

The fibers of the fiber composite material from which the spring at least

mineral or organic fibers are preferably formed in sections. The fibers are particularly preferably carbon fibers and / or glass fibers.

The fibers can be short fibers and / or long fibers and / or continuous fibers.

The at least one add-on part of the spring assembly can be, for example, a spring plate or a spring pad or a bearing element.

The at least one add-on part is preferably formed from plastic and / or from a fiber composite and / or from metal.

In a particularly preferred embodiment of the invention, the add-on part is formed from plastic, in particular from a thermoplastic and / or an elastomer and / or a thermoset. In step b), openings and / or depressions are introduced at least in sections in the connecting section.

The connecting section is the section of the spring to which the at least one attachment part is attached. In other words, a connection between the spring and the attachment is made in the connecting section of the spring.

It is possible for the spring to have several connecting sections. Several attachments can be connected to the spring.

The at least one connecting section is preferably designed as a delimited contact surface, an attachment part to be connected being brought into contact or being in contact with this contact surface.

Breakthroughs are to be understood as sections of the connecting section which represent a complete removal of material. At a

Depression is such a section of a

Connection section, which represents a partial material removal.

Both the fibers and the matrix of the fiber composite material have been removed in the openings and in the free spaces forming the depressions.

The shape of the openings can be variable. The openings can have, for example, a circular shape, an elliptical shape, an elongated hole shape, a rectangular shape, a square shape or a polygonal shape. Furthermore, it is possible for the openings to have different shapes or structures. Furthermore, it is possible that the

Breakthroughs are designed as slots. The individual openings can be arranged at the same or different distances from one another.

In particular, it is possible that the breakthroughs on common

Circumferential lines of a spring provided are formed. Both

Breakthroughs can be holes, for example.

The depressions can be blind holes, for example.

Furthermore, it is possible for the depressions to be designed as grooves. It is possible for the depressions to be formed on common circumferential lines of the spring section. The depressions can have different cross-sectional shapes. In particular, it is possible that the

Wells have a triangular cross-section. Also a

rectangular or square cross-section is possible.

When the openings and / or depressions are introduced, the

Fiber composite material in this area removed completely or in sections. The fibers of the fiber composite material are destroyed or severed at least in sections.

Furthermore, it is possible for the edge regions of the openings and / or depressions to have sections which comprise exposed fibers. In this area only the matrix is removed, whereas the fibers are exposed. The exposed fibers are particularly preferably residual pieces of separated fibers to form the openings and / or depressions.

In step c), the add-on part is attached to this connecting section, which comprises openings and / or depressions after step b)

Original molding process attached.

In other words, the invention is based on the fact that openings and / or depressions are formed on a spring made of composite material in the sections provided for the connection to the add-on part. At least one add-on part can be attached to these openings and / or depressions by primary shaping from the liquid phase, so that the still liquid material of the add-on part flows into the openings and / or depressions.

The material of the attachment then hardens, so that a

positive connection between the spring and the attachment.

The temperature of the liquid phase of the material of the attachment is

preferably lower than the glass transition temperature Tg of the matrix. The temperature of the liquid phase of the material of the attachment can be chosen such that the temperature of the matrix in the area of contact with the liquid phase does not rise above the glass transition temperature Tg of the matrix. The

The temperature of the liquid phase of the material of the add-on part should preferably be selected such that the matrix material is not burned. The connection between a spring and at least one add-on part that can be produced or produced on the basis of the method according to the invention is designed to be permanently form-fitting in such a way that relative movements between the

Components can be prevented. In addition, no dirt particles and / or liquids can get between the components, i.e. between the spring and the attachment in the connecting section.

A laser is preferably used in step b). The introduction of

Breakthroughs and / or depressions are thus preferably carried out by means of a laser, in particular by means of an ultra-short pulse laser.

Laser pulses with a duration of <20 ps are preferred

(Picoseconds), in particular <10 ps, on the fiber composite material

upset. Lasers with a wavelength of up to 1,064 nm (nanometers) are preferably used.

Furthermore, the use of a laser is based on using such a laser with an average power of up to 400 W (watts), in particular up to 100 W, particularly preferably with a power of 30-80 W.

The repetition rate of the laser beams to be applied to the

Fiber composite material can be up to 1 MHz (megahertz). The preferred use of a laser, in particular an ultrashort pulse laser, has the

Advantage that the fiber composite material can be processed and / or removed in a location and depth selective manner.

The master molding process mentioned in step c) can in particular be an injection molding process or a casting process or an injection molding process. These primary shaping processes have the advantage that a liquid material is initially present, which can be applied in the region of the connecting section, so that the openings and / or depressions with the liquid

Material can be filled and / or enclosed and then cured.

Furthermore, it is possible that in step c) a connecting element is produced by means of the master molding process, which connects the add-on part to the spring. In this exemplary embodiment, therefore, it is not the add-on part itself that is produced in a primary molding process, but a connecting element. Also one of those attached connecting element has the advantage that a permanent positive connection between the spring and the connecting element is produced.

In particular, it is possible that a spring provided and machined according to step b) and a provided add-on part are connected to one another in step c) by forming a connecting element. Accordingly, in this context it is not the add-on part that is produced using the primary molding process, but the connection between the spring and the add-on part.

In this case, the connection takes place on the basis of an injection molding process and / or casting process and / or injection molding process.

In particular, it is possible for the add-on part to be produced in step c) by means of the master molding process and simultaneously connected to the spring.

Another aspect of the invention relates to a spring assembly comprising a spring, in particular a helical spring or a torsion bar spring, and at least one add-on part, in particular a spring plate or a

Spring pad or a bearing element, the spring assembly being produced by means of a method according to the invention. The above applies to the materials from which the spring and / or the attachment are formed.

With the aid of the spring assembly according to the invention, the same advantages or similar advantages as those already mentioned in connection with the method according to the invention go hand in hand.

Another, in particular secondary, aspect of the invention relates to a spring, in particular a helical spring or torsion bar spring, for producing a spring assembly, the spring being formed at least in sections from a fiber composite material with a matrix and fibers.

The spring according to the invention is in particular designed such that it can be used in the method according to the invention for producing a spring assembly.

The spring has at least one connecting section for attaching an attachment, the connecting section having openings and / or

Has depressions. Such a section is in particular a breakthrough to understand a wall of the spring, which has a complete material removal or material removal.

A depression is such a section of a wall of the spring which has a partial material removal or a partial material removal. The above applies to the shape of the openings and / or depressions.

The fibers of the fiber composite material can be formed from mineral or organic material. In particular, the fibers are made of carbon and / or glass.

The matrix is formed in particular from a plastic material. In a particularly preferred embodiment of the invention, it is a thermoplastic and / or thermoset and / or elastomer. A particularly preferred material for forming the matrix is epoxy resin.

The fiber composite material of the spring can therefore be

act glass fiber reinforced plastic (GRP) and / or carbon fiber reinforced plastic (CFRP).

Furthermore, it is possible for the openings and / or depressions to have edge regions at least in sections, which comprise exposed fibers. In other words, only the matrix is removed in the edge regions, so that the fibers are exposed at least in sections.

The matrix in the connecting section is removed in such a way that fibers of the

Connection section are exposed. In particular, the fibers are exposed in such a way that they are not destroyed. In other words, the fibers are exposed in step b) without destruction. In other words, only the matrix material of the fiber composite material is removed, so that the fibers are neither cut through nor damaged in any other way.

In step c), the add-on part is attached to this connecting section, which comprises fibers exposed after step b), by means of an original molding process. In other words, the invention is based on a spring

Composite material in the surfaces or boundary layer areas provided for the connection to the add-on part, the matrix material is removed by suitable means, so that the fibers are exposed undamaged. At least one add-on part can be formed on the fibers exposed in this way, in particular on the fiber structure exposed in this way, by primary shaping from the liquid phase

be attached so that the still liquid material of the attachment encloses the exposed fibers. Then the material of the attachment hardens, so that a positive connection between the spring and the

Add-on part is created.

The temperature of the liquid phase of the material of the attachment is

preferably lower than the glass transition temperature Tg of the matrix. The temperature of the liquid phase of the material of the attachment can be chosen such that the temperature of the matrix in the area of contact with the liquid phase does not rise above the glass transition temperature Tg of the matrix. The

The temperature of the liquid phase of the material of the add-on part should preferably be selected such that the matrix material is not burned.

The connection between a spring and at least one add-on part that can be produced on the basis of the method according to the invention is designed to be permanently form-fitting in such a way that relative movements between the components are prevented. In addition, no dirt particles and / or

Liquids between the components, i.e. between the spring and the attachment in the connecting section.

A laser is preferably used in step b). That in sections

The matrix is therefore preferably removed by means of a laser,

in particular by means of an ultrashort pulse laser.

Laser pulses with a duration of <20 ps are preferred

(Picoseconds), in particular <10 ps, applied to the matrix. Lasers with a wavelength of up to 1,064 nm (nanometers) are preferably used.

Furthermore, the use of a laser is based on using such a laser with an average power of up to 400 W (watts), in particular up to 100 W, particularly preferably with a power of 30-80 W. The repetition rate of the laser beams to be applied to the matrix can be up to 1 MHz (megahertz). The preferred use of a laser, in particular an ultrashort pulse laser, has the advantage that the matrix material can be processed and / or removed in a location- and depth-selective manner.

The master molding process mentioned in step c) can in particular be an injection molding process or a casting process or an injection molding process. These primary shaping processes have the advantage that a liquid material is initially present, which can be applied in the region of the connecting section, so that exposed fibers can be enclosed by the liquid material and then cured.

Furthermore, it is possible that in step c) a connecting element is produced by means of the master molding process, which connects the add-on part to the spring. In this exemplary embodiment, therefore, it is not the add-on part itself that is produced in a primary molding process, but a connecting element. A connecting element attached in this way also has the advantage that a permanent positive connection is established between the spring and the connecting element.

In particular, it is possible that a spring provided and machined according to step b) and a provided add-on part are connected to one another in step c) by forming a connecting element. Accordingly, the add-on part is not used in the primary molding process in this context

made, but the connection between the spring and the attachment. In this case, the connection takes place on the basis of an injection molding process and / or casting process and / or injection molding process.

In step b), the matrix is preferably removed to such a depth that at least one fiber of a near-surface fiber layer is completely exposed with respect to the fiber cross section. A near-surface fiber layer is defined below in such a way that it is the outermost fiber layer of the

Fiber composite material of the spring affects. When the matrix is removed, this fiber layer is the first exposed fiber layer.

A fiber layer can comprise several fibers woven together. Furthermore, it is possible for a fiber layer to comprise unidirectional fiber bundles or to consist of unidirectional fiber bundles. A fiber layer can for example a mat or a fabric or a scrim or a mesh or a random fiber mat or a non-woven or a 3D fabric or a 2D fabric or a knitted fabric.

The matrix is removed or removed to such a depth that at least one fiber of a near-surface fiber layer, in particular a section of a near-surface fiber layer, is completely exposed from the matrix. This means that the fiber (s) are mostly round

The fiber cross section is / are substantially completely freed from the matrix material.

In a further embodiment of the invention, it is possible for a plurality of fiber layers arranged one above the other to be at least partially separated from the

Material of the matrix are exposed. This enables an improved

positive connection between a spring and at least one

Attachment.

Another aspect of the invention relates to a spring assembly, comprising a spring, in particular a coil spring or a torsion bar spring, and

at least one attachment, in particular a spring plate or a

Spring pad or a bearing element, the spring assembly being produced by means of a method according to the invention. The above applies to the materials from which the spring and / or the attachment are formed.

With the aid of the spring assembly according to the invention, the same advantages or similar advantages as those already mentioned in connection with the method according to the invention go hand in hand.

Another, in particular secondary, aspect of the invention relates to a spring, in particular a helical spring or torsion bar spring, for producing a spring assembly, the spring being formed at least in sections from a fiber composite material with a matrix and fibers.

The spring according to the invention is in particular designed such that it can be used in the method according to the invention for producing a spring assembly. The spring has at least one connecting section for attaching an attachment, the connecting section having fibers exposed by the matrix.

The fibers can be formed from mineral or organic material. In particular, the fibers are made of carbon and / or glass.

The matrix is formed in particular from a plastic material. In a particularly preferred embodiment of the invention, it is a thermoplastic and / or thermoset and / or elastomer. A particularly preferred material for forming the matrix is epoxy resin.

The fiber composite material of the spring can therefore be

act glass fiber reinforced plastic (GRP) and / or carbon fiber reinforced plastic (CFRP).

At least one fiber of a near-surface fiber layer is preferably completely exposed with respect to the fiber cross section. With regard to the definition of the near-surface fiber layer, reference is made to previous explanations.

In particular, it is possible for a plurality of fiber layers arranged one above the other to be completely exposed at least in sections from the matrix in the connecting section.

The invention comprises the following further embodiments:

1. A method for producing a spring assembly (30) comprising a spring (10) and at least one attachment (40),

in which

the procedural steps:

a) providing a spring (10), in particular a coil spring or a torsion bar spring, which at least in sections consists of a

Fiber composite material is formed with a matrix (22) and fibers (25), the spring (10) in the area of the fiber composite material having at least one connecting section (20) for attaching an attachment (40);

b) removal of the matrix (22) at least in sections

Connection section (20) and at least in sections, in particular the fibers (25) are not destructive, exposing fibers (25) in

Connecting section (20);

c) attaching the add-on part (40) to the connecting section (20) by means of a master molding process. Method according to embodiment 1,

in which

the matrix (22) is removed in sections by means of a laser, in particular by means of an ultrashort pulse laser. Method according to embodiment 1 or 2,

in which

the primary molding process is a spraying process or a casting process or an injection molding process. Method according to one of the preceding embodiments, w o b e i

in step c) the add-on part (40) is produced by means of the master molding process and at the same time connected to the spring (10). Method according to one of the embodiments 1 to 3,

in which

in step c) a connecting element is produced by means of the master molding process, which connects the add-on part (40) to the spring (10). Method according to one of the preceding embodiments, w o b e i

in step b) the matrix (22) is removed to such a depth that at least fibers (25) of a near-surface fiber layer (28) are completely exposed with respect to the fiber cross section. Spring assembly (30), comprising a spring (10), in particular a helical spring or a torsion bar spring, and at least one add-on part (40), in particular a spring plate or a spring base or a bearing element, the spring assembly (30) using a method is produced according to one of the embodiments 1 to 6. 8. spring (10), in particular helical spring or torsion bar spring, for producing a spring assembly (30), the spring (10) being formed at least in sections from a fiber composite material with a matrix (22) and fibers (25),

in which

a connecting section (20) for attaching an attachment (40), the connecting section (20) having fibers (25) exposed by the matrix (22).

9. spring (10) according to embodiment 8,

in which

the fibers (25) are formed from carbon and / or glass.

10. spring (10) according to embodiment 8 or 9,

in which

the matrix (22) is formed from a plastic material, in particular from thermoset and / or elastomer and / or thermoplastic.

The invention is explained in more detail below using an exemplary embodiment with reference to the accompanying schematic drawings. In it show:

Fig. La: a perspective view of a portion of a

spring according to the invention;

Fig. Lb: a cross section through a spring in the connecting section; and

2: a perspective view of a spring assembly;

3a: a spring according to the invention;

3b: a cross section through a spring in the connecting section.

Below are the same for the same and equivalent parts

Reference numbers used. Fig. La shows a partial perspective view of a spring 10 according to the invention. This spring 10 is, for example, a

Torsion bar spring. The spring 10 is formed from a fiber composite material.

In particular, the spring 10 is formed from carbon fiber reinforced plastic and / or glass fiber reinforced plastic.

The spring 10 has a connecting section 20. The connecting section 20 is used for later connection of an attachment to the spring 10th

It is possible for the spring 10 to have a plurality of connecting sections 20.

In the example shown, openings 50 are formed in the connecting section 20. In the present case, four openings 50 are shown. The breakthroughs are complete material removals. The openings have an elongated hole shape. The openings 50 are evenly spaced from one another. Alternatively, it is possible for multiple breakthroughs

have different shapes and / or sizes and / or distances from one another.

Furthermore, it is possible for fibers exposed from the matrix to be formed in edge regions 51 of the openings 50. This serves to produce a particularly firm connection between the spring 10 and an attachment.

In Fig. La is also shown that the openings 50 on a

common circumferential line or are formed in a common plane.

A further embodiment with respect to a spring 10 according to the invention is shown in FIG. 1b. The surface 15 of a connecting section 20 can be seen in the cross section shown. Wells 60 are made in surface 15. The depressions 60 are designed as blind holes. In the example shown, these depressions 60 are evenly spaced from one another.

Edge regions 61 can also be formed in the depressions 60, which have fiber sections freed or exposed from the matrix. In the

Wells 60 can be the plastic material of the also indicated

Add part 40 as part of the selected primary molding process. A particularly positive connection between the attachment 40 and the spring 10 can be established. An ultrashort pulse laser is used in particular to introduce the openings 50 and / or depressions 60 into the connecting section 20.

With the help of such an ultrashort pulse laser, the fiber composite material can be removed in a location- and depth-selective manner. This is particularly advantageous when the recesses 60 are formed. The in step d) in the

Connections 20 introduced and openings 50 and / or depressions 60 can be used in a further method step for connection to / the attachment. For this purpose, the liquid material of the add-on part and / or of a connecting element is inserted into the

Indentations 60 introduced or flows through the openings 50. The liquid material then hardens. Because of this, a positive connection is established.

FIG. 2 shows a spring assembly 30 according to the invention. This initially comprises a spring 10. The spring 10 is made at least in sections

Fiber composite material, in particular carbon fiber reinforced plastic and / or glass fiber reinforced plastic.

At a spring end 18, openings 50 and / or depressions 60 were first made in a connecting section 20.

The attachment 40 was attached to the connecting section 20 by means of a master molding process. The attachment 40 can be a spring plate, a spring pad or a bearing element.

3a shows a perspective view of a spring 10 according to the invention. This spring 10 is a torsion bar spring. The spring 10 is formed from a fiber composite material. In particular, the spring 10 is formed from carbon fiber reinforced plastic and / or glass fiber reinforced plastic.

The spring 10 has a connecting section 20 on the surface 15. The connecting section 20 serves for the later connection of an add-on part with the spring 10. It is possible for several on the surface 15

Connection sections 20 are formed.

A possible connection section 20 is shown in more detail in FIG. 3b. In the connecting section 20, a plurality of fibers 25 are exposed from the matrix 22. in the The example shown shows four fiber layers 26 with associated fibers 25 exposed by the matrix 22. The fibers 25 are exposed non-destructively. In other words, the fiber layers 26 are intact. No fibers 25 are separated and / or perforated and / or removed in sections. In particular, the near-surface fiber layer 28 is exposed. The near-surface fiber layer 28 is the fiber layer 26 which, starting from the surface 15, forms the first fiber layer.

In the example shown in FIG. 3b, part of the fibers 25 lies at a 90 ° angle to the other part of the fibers 25. However, this is only an example. In principle, the fibers can assume any angle to one another within a fiber layer 26. It is possible that the fibers are unidirectional or multidirectional.

In the example indicated in FIG. 3a, the fibers 25 are unidirectional.

In Fig. 3b, the fiber layers 26 are formed as a fabric. However, this is only an example. In principle, a fiber layer 26 can have a one-, two- or three-dimensional architecture. A one-dimensional layer can e.g. B. from unidirectional rovings or unidirectional multifilaments or

unidirectional tissues. Examples of a two or

three-dimensional architecture include Tangled fiber mats, nonwovens, 2D fabrics, 3D fabrics, scrims, braids and knitted fabrics.

In a particularly preferred embodiment of the invention

Exposing the fibers 25 of the fiber layers 26 uses an ultrashort pulse laser. With the help of such an ultrashort pulse laser, the material of the matrix 22, in particular the plastic material, can be removed in a location- and depth-selective manner.

The exposed fiber structure of the spring 10 can in another

Process step for connection to an attachment can be used. For this purpose, the liquid material of the add-on part and / or a connecting element is applied to the exposed fibers 25 of the fiber layers 26 in a master molding process. The liquid material encloses the initially exposed fibers 25 and then hardens. Because of this, a positive connection is established. Reference symbol list

10 spring

15 surface

18 spring end

20 connecting section 22 matrix

25 fiber

26 fiber layer

28 near-surface fiber layer 30 spring assembly

40 attachment

50 breakthrough

51 edge area

60 deepening

61 edge area

Claims

Claims

1. A method for producing a spring assembly (30) comprising a spring (10) and at least one attachment (40),

marked by

the procedural steps:

a) providing a spring (10), in particular a coil spring or a torsion bar spring, which is formed at least in sections from a fiber composite material with a matrix and fibers, the spring (10) in the region of the fiber composite material having at least one connecting section (20) for attaching an attachment part (40);

b) at least section-wise introduction of openings (50)

and / or depressions (60) in the connecting section (20);

c) attaching the add-on part (40) to the connecting section (20) by means of a master molding process.

2. The method according to claim 1,

That means that

breakthroughs (50) and / or depressions (60) are introduced by means of a laser, in particular by means of an ultrashort pulse laser.

3. The method according to claim 1 or 2,

That means that

the primary molding process is a spraying process or a casting process or an injection molding process.

4. The method according to any one of the preceding claims,

That means that

in step c) the add-on part (40) is produced by means of the master molding process and at the same time connected to the spring (10).

5. The method according to any one of claims 1 to 3,

That means that

in step c) a connecting element is produced by means of the master molding process, which connects the add-on part (40) to the spring (10).

6. spring assembly (30), comprising a spring (10), in particular a helical spring or a torsion bar spring, and at least one add-on part (40), in particular a spring plate or a spring pad or a bearing element, the spring assembly (30) by means of of a method according to one of claims 1 to 5.

7. Spring (10), in particular coil spring or torsion bar spring, for

Manufacture of a spring assembly (30), the spring (10) being formed at least in sections from a fiber composite material with a matrix and fibers,

marked by

at least one connecting section (20) formed in the area of the fiber composite material for attaching an add-on part (40), the connecting section (40) having openings (50) and / or depressions (60).

8. spring (10) according to claim 7,

That means that

the fibers are made of carbon and / or glass.

9. spring (10) according to claim 7 or 8,

That means that

the matrix is formed from a plastic material, in particular from thermoset and / or elastomer and / or thermoplastic.