WO2008062007A1 - Feeder insert and feeder element - Google Patents

Abstract

The invention relates to a feeder element (10) for the use during the casting of metals in casting molds, comprising a first end (14) for placing on a mold model (12) and a second end (16) opposite thereof for connecting to or for carrying an upper feeder part (18). The feeder element (10) comprises a passage (20) for liquid metal, extending from the first to the second end (14, 16), wherein the feeder element (10) is designed as two or multiple parts and comprises or is made of: (i) a tube-like element (22) forming the first end (14) of the feeder element (10), having a maximum wall thickness of 1.5 mm, (ii) an adapter element (24) with an opening into which the tube-like element (22) is inserted such that it is frictionally connected with the adapter element. The adapter element (24) comprises one or more displacement limiters (26) for delimiting the insertion path for the tube-like element (22). Said displacement limiters are designed such that the outer surface (46) of the edge region of the tube-like element (22) opposite of the first end (14) at the maximum width of the insertion within the adapter element (24) is present free on the entire circumference or in sections of the circumference.

Description

 Feeder insert and feeder element

The present invention relates to a feeder element for use in casting metals in molds having a first end for placement on a mold model and an opposed second end for connection to or for supporting an upper riser, the feeder element extending from the first to the second end Passage for liquid metal possesses. The invention also relates to a feeder insert for use in casting metals in molds, having a cavity for receiving liquid metal, comprising or consisting of a feeder element according to the invention and an upper feeder part. Further aspects of the invention relate to kits for producing a feeder element according to the invention or a feeder insert according to the invention and to methods for arranging a feeder insert in a casting mold. Further aspects of the invention will become apparent from the following description and the appended claims.

Feeder elements of the type mentioned are known from the prior art. In this connection, reference should be made in particular to document EP 1184104 B1, which describes a feeder insert with a first formula element. ment, which is a feeder element of the type mentioned above. Reference is also made to the document DE 10142357 A1, which discloses a feeder system with a feeder or feeder head and a tube-like body.

Further documents which define the technological background of the present invention are: DE 10200508324 A1, EP 1567294 B1, DE 20118763 U1, DE 19642838 A1; DE 201 12425 U1; WO 2005/095020 A3; DE 202004009367 U1; DE 202006011980 U1 and DE 202004021109 U1.

The object of the present invention is to develop a feeder element according to EP 1 184104 B1. The feeder elements (first mold elements) disclosed therein, which are provided for supporting an upper feeder part (second mold element), have a first end for placement on mold models, the attachment surface of which in practice is felt to be too large in some cases. On the part of the foundry industry, ever smaller surface areas (and shelves) are desired, as in the recent past the surfaces of castings have become increasingly filigree. It should be noted, however, that the passage opening (passage opening) for liquid metal must not be arbitrarily small, otherwise an acceptable feeding behavior can not be achieved. In addition, it should be noted that a cooling of the feeder neck, as it may occur in thin-walled design of a feeder element on its side facing the mold model, may not make disturbing.

From the prior art, in particular from the already mentioned DE 10142357 A1, attempts are already known to specify feeders with only a small top surface, which function satisfactorily in foundry operation. However, it has been shown in investigations that embodiments in which a thin-walled tube-like element is free at its end facing the casting, while its end facing the feeder cavity is surrounded on all sides by Speiser molding material, often the desired formation of a breaking edge on the first (lower End). According to the present invention, in order to achieve the above object, there is provided a feeder element for use in casting metals in molds having a first end for placement on a mold model and an opposed second end for connection to or for supporting an upper riser, wherein the feeder element has a liquid metal passage extending from the first end to the second end, the feed element being two or more parts and comprising or consisting of: (i) a tubular element forming the first end of the feeder element having a wall thickness of at most 1, 5 mm,

(ii) an adapter element having an opening into which the tubular element is inserted so as to be frictionally connected to the adapter element, the adapter element comprising one or more travel limiters for limiting the insertion path for the tubular element, which are arranged such that the outer surface of the first end opposite the edge region of the tubular element is freely available at maximum wide insertion within the adapter element with its entire circumference or in portions of the circumference.

In this way, it is surprisingly ensured that when cleaning the feeder breaks off safely in the immediate vicinity of the casting; In contrast, in an embodiment in which the tubular element does not have a free end within the adapter element, there is often an undesirable breakage of the feeder at the edge opposite the first end of the corresponding tubular element.

A corresponding feeder insert according to the invention for use in casting metals in molds, having a cavity for receiving liquid metal, comprises or consists of: a feeder element according to the invention (as just defined) and an upper feeder part. - A -

The feeder element according to the invention can advantageously be used as described in EP 1184104 B1 for the local "first molded element." The upper feeder part of a feeder insert according to the invention corresponds to the "second molded element" according to EP 1 184104 B1. Food inserts, as described in EP 1184104 B1, are commercially available under the name "Telespeiser" from CHEMEX GmbH, Germany.

In the delivery state of a feeder element according to the invention, the tubular element can be inserted into the adapter element to different extents. In some cases, it is advantageous if the tube-like element is not pushed far into the adapter element so that it continues to be inserted into the molding machine at a later time, for example after arranging a corresponding feeder insert in a molding machine and compacting mold material filled into the molding machine Adapter element can be inserted until it is prevented by the Wegbegrenzern or at another slot. Such an arrangement is advantageous to prevent breakage of a feeder element according to the invention or a corresponding feeder insert according to the invention, as would otherwise be possible in the molding material compaction due to the then acting compression forces. In particular, in combination with an upper feeder part, which is arranged displaceably relative to the feeder element according to the invention, a destruction of a feeder according to the invention is reliably prevented.

Alternatively, however, the tube-like element can also be inserted as far as possible into the adapter element as soon as it is delivered, so that it is prevented from being pushed back by the path limiter or limiters.

In any case, however, applies that in a feeder element according to the invention, the outer surface of the first end opposite edge region of the tubular element at maximum wide insertion within the adapter element with its entire circumference or in portions of the circumference freely and thus in the casting operation, the access of liquid metal the outside surface allows. Preferably, the adapter element forms the second end of the feeder element, that is, the end of the feeder element, which is intended for connection to or for supporting an upper feeder part. Alternatively, however, one or more intermediate elements can also be provided between the adapter element and the upper feeder part.

The tubular element of a feeder element according to the invention is preferably cylindrical, but other configurations may be provided, for example rectangular tube cross-sections or tubular elements having a conical shape.

Preferably, the tubular member has a length in the range of 10 to 30 mm, especially if it is cylindrical.

If the tube-like element has a length in the range of 10 to 30 mm and is not inserted as far as possible in the delivery condition in the adapter element, it allows a further insertion of at least 4 mm in the state before the compression of the molding material. It has been found that in such an arrangement, the compression forces occurring during compression of the molding material can be effectively counteracted.

Preferably, the tubular member has a substantially uniform cross section over the entire length. The ratio of wall thickness to the total diameter of the tubular element is preferably over its entire length between about 1: 5 and 1: 120, more preferably in the range of 1:10 to 1: 100. The thickness of the tubular member is chosen by the skilled person to have sufficient stability and to withstand the crushing forces encountered in the molding material compaction.

Preferably, the tubular element is made of a material which is selected from the group consisting of: metallic, ceramic or plastic materials and composite materials based on metal, ceramic and / or plastic. Here, the tubular element is preferably made of iron, an iron alloy such as steel, aluminum, an aluminum alloy, a brass alloy or ceramic.

The adapter element, however, is preferably made of an exothermic or insulating molding compound. The same applies in a feeder insert according to the invention for the upper feeder part.

It will be understood that the adapter element of a feeder element according to the invention usually has a wall or a wall section whose thickness is greater in sections or everywhere than the thickness of the tube-like element at the first end of the feeder element. In particular, when producing the adapter element from an exothermic or insulating molding material is a wall thickness of less than 1, 5 mm can not be produced with the required process reliability in the context of mass production.

It has already been mentioned that a feeder insert according to the invention advantageously resembles in its construction the feeder inserts as described in EP 1 184104 B1, wherein the components described there as "first form element" are replaced by a two- or multi-part feeder element according to the invention The content of EP 1 184104 B1 is incorporated by reference into the present text.

Preferably, the feeder element and the upper feeder part of a feeder insert according to the invention are arranged to be slidable into one another. In particular, in such an arrangement of feeder elements in the upper feeder element in the feeder element according to the invention, the tubular element is preferably not pushed far into the adapter element, so that it can be further inserted into the adapter element until it is prevented by the Wegbegrenzern or at a further insertion , The compression forces occurring during the compression of the molding material is then countered by two separate relative movements, namely the relative movement of the upper feeder part relative to the feeder element (the feeder element is inserted into the upper feeder element) and the relative movement of the tubular element. element relative to the adapter element (the tube-like element is pushed further into the adapter element until it bears against the travel limiters).

The feeder element and the upper feeder part of a preferred feeder insert according to the invention together form a cavity for receiving liquid metal.

In summary, therefore, a feeder insert is preferred which comprises or consists of:

(a) a two or more sectional feeder element having a first end for placement on a mold model and an opposite second end, the feeder element having a liquid metal passageway extending from the first to the second end and comprising or consisting of:

(a) (i) a tubular element forming the first end of the feeder element having a maximum wall thickness of 1.5 mm at the first end; (a) (ii) an adapter element having a wall whose thickness is greater than that of the tubular one Element at the first end of the feeder element, and an opening, in which the tubular member is inserted so that it is frictionally connected to the adapter element, and

(b) an upper riser portion, the riser member being connected and / or supported by the second riser to the upper riser portion, wherein the riser element and the upper riser portion are slidable into each other and form or enclose a cavity, in some instances although not preferred , by forming a double wall.

The present invention also relates to a kit for producing a feeder element according to the invention, comprising a tube-like element and an adapter element. With regard to the configuration of the tubular element and the associated adapter element, the above applies accordingly. The invention also relates to a kit for producing a feeder insert according to the invention, comprising a tube-like element and an adapter element for producing a feeder element according to the invention and - an upper feeder part.

Also in this respect, the above statements apply to the design of the tubular element, the adapter element and the upper riser part accordingly.

The present invention also relates to a method for arranging a feeder insert in a casting mold, comprising the following steps:

Providing a feeder element according to the invention in one of its embodiments described above, wherein the tubular element in the adapter element

(a) is not pushed in at most, so that it can be further inserted into the adapter element until it is prevented by the Wegbegrenzern or at another slot or

(b) is pushed in so far that it is prevented by the path limiter (s) at another slot,

Providing an upper feeder part, which is preferably designed as stated in EP 1184104 B1,

Placing the upper feeder part on the feeder element, so that a feeder insert according to the invention is formed,

Arranging the feeder insert in a molding machine (the space above a model plate, which is usually surrounded by an attached molding box), Filling of molding material into the molding machine (the molding box placed on the pattern plate), so that the outer walls of the feeder insert are contacted with the molding material,

Compacting the molding material, wherein in the case (a) the tubular element is pushed further into the adapter element until it is prevented by the path limiter (s) at a further insertion.

In a method according to the invention, the upper feeder part and the feeder element are preferably chosen so that when placing the upper feeder part on the feeder element, a feeder insert is formed, wherein the feeder element and the upper feeder part are slidable into each other, wherein the upper feeder part and the Feeder element are moved into each other (optionally after separation or deformation of holding elements).

Preferably, in a method according to the invention, the molding machine comprises a pattern plate (that is, a molding machine model, usually consisting of a flat plate with cast-in or mechanically-fastened models) and the feeder element is inserted into the molding machine so that it can with its first end is in direct contact with the model plate (the model surface).

The statements from EP 1184104 B1 apply correspondingly with regard to the method according to the invention.

The invention will now be explained in more detail below with reference to the attached exemplary figures, in which: FIG.

Fig. 1 longitudinal section through a feeder insert according to the invention with a feeder element in an arrangement in which the tubular element is not inserted maximally far into the adapter element and the feeder insert is fixed by means of a centering mandrel on a mold model. Fig. 2 longitudinal section through the feeder insert according to the invention and the

Feeder element of FIG. 1 in an arrangement in which the tubular ele- ment is inserted maximally far into the adapter element and the

Feeder insert is attached by means of a centering mandrel on a mold model.

Fig. 3 shows a longitudinal section through the feeder insert according to the invention and the feeder element of Fig. 1 in a compressed arrangement, as it exists after compacting.

4 top view of the feeder element of the feeder insert according to FIG. 1.

5 enlarged view of a longitudinal section of the feeder element according to FIG. 4.

In Fig. 1, a feeder insert 8 according to the invention is shown in a possible starting arrangement (before the filling of molding material and before the compression process). The feeder insert 8 according to the invention comprises a feeder element 10 and an upper feeder part 18, which are essentially rotationally symmetrical. The axis of rotation extending in the longitudinal direction of the feeder insert 8 is indicated in FIG. 1 by a dashed line 48. The feeder element 10 comprises an adapter element 24 into which a tube-like element 22 is inserted in such a way that it is frictionally connected to the adapter element 24, but is displaceable therein using a certain amount of force. Alternatively, the feeder element 10 may consist of more than two components. The feeder element comprises a first end 14 and a second end 16, the first end 14 being formed by the tubular element 22 and the second end 16 being formed by the adapter element 24. The tubular member includes an edge region opposite the first end 14 of the feeder element. The adapter element 24 includes Wegbegrenzer 26. In the illustrated output assembly, the tubular element 22 is not inserted maximally far into the adapter element 24. Alternatively, the tubular element 22 may be inserted as far as possible into the adapter element 24, so that it rests against the Wegbegrenzern 26 with its the first end 14 opposite edge region and is prevented from further insertion (see Fig. 2). With the first end 14 of the tubular element 22, the feeder element 10 is placed on a mold model 12. The feeder element 10 forms between its first end 14 (formed by the tubular element 22) and a second end 16 (formed by the adapter element) a passage 20 for liquid metal. The tubular element 22 has a maximum wall thickness of 1, 5 mm and consists of metallic, ceramic or plastic materials and composite materials based on metal, ceramic and / or plastics. Preferably, however, the tubular member 22 is made of iron, an iron alloy such as steel, aluminum, an aluminum alloy, a brass alloy, or ceramics.

The adapter element 24 has a wall which is larger in sections or everywhere than the thickness of the tubular element at the first end 14 of the feeder element 10 and, like the upper feeder section 18, consists of an exothermic or insulating molding compound. In the adapter element 24 Wegbegrenzer 26 are integrated, which are designed in the form of ribs (see Figures 4, 5). The Wegbegrenzer consist of the same exothermic or insulating molding compound as the Adapterelelment 24 and do not form a separate component. They serve to limit the insertion path of the tubular element 22. Starting from the mold model 12, the outer wall of the adapter element 24 has a conically widening section 62, which merges into a section 42 with a constant diameter. At least one holding projection 34 is provided at this section 42. The inner wall of the adapter element 24 also consists of a flared portion and a constant diameter portion.

According to FIG. 1, the upper feeder part 18 is placed with its lower edge 38 on holding projections 34 of the adapter element 24 and fixed by means of the centering mandrel 36. The upper feeder part 18 is made quite thick-walled in relation to the tubular element 22 and to the adapter element 24. Starting from the lower edge 38, the outer wall of the upper riser 18 has a first relatively sharply flared portion 56 before the outer wall merges into a less extensive flared conical section 58. In the wall section 60, the upper feeder part 18 tapers conically upwards.

Also starting from the lower edge 38, the inner wall of the upper feeder part 18 forms a portion 40, which initially parallel to the outer wall 42 of the adapter element 24 and then merges into a conically upwardly tapering wall portion 50, along which the tip of a centering mandrel during positioning of Feeder insert 8 can be performed. The conical wall section 50 finally opens into a centering bore 52 located in the axis of rotation 48 of the feeder insert 8 for receiving the tip of the centering mandrel 36.

The upper riser 18 and the adapter 24 form a cavity of interconnected part cavities 30 and 44 for receiving liquid material.

According to FIG. 2, the tubular element 22 of the feeder insert 8 according to the invention is inserted maximally far into the adapter element 24. The illustration includes two cutting planes through the adapter element 24: on the left side of the axis of rotation 48 in FIG. 2, the cutting plane is selected such that the travel limiter 26 is not cut (section A), on the right side of the rotation axis 48 in FIG the cutting plane passes through the Wegbegrenzer 26 (section B, to select the cutting planes see also Fig. 4).

In Fig. 3, the feeder insert 8 (according to Figures 1 and 2) is shown in a compressed arrangement. The connecting surfaces between the holding projections 34 and the adapter element 24 are each quite small, so that the holding projections 34 can be separated from the adapter element 24 with little effort. Due to the force resulting from the compression, the upper feeder part 18 is displaced in the direction of the mold model 12. In this case, the force need only be sufficiently large to hold the retaining projections 34 from the adapter element 24 to separate. The displacement path of the upper feeder part 18 in the direction of the mold model 12 is predetermined and limited by the degree of compression molding.

When moving the upper feeder part 18 in the direction of the mold model 12, the tip of the centering mandrel 36 as shown in FIG. 3 breaks through the between the upper end of the center hole 52 and a wall section 54 located in a Wandungsabschluss. This wall portion is dimensioned so that the displacement between the upper feeder part 18 and the adapter element 24 is not hindered.

In the event that the tube-like element 22, as shown in FIG. 1, is not inserted maximally far into the adapter element 24 prior to compression, there is a separate displacement in addition to the displacement between the adapter element 24 and the upper feeder part 18 The dimension of the displacement is also predetermined here by the compression of the mold, but is at most the distance between the first end 14 opposite edge region 46 of the tubular element and the Wegbegrenzern or 26 before compression limited. Such a separate displacement between the tube-like element 22 and the adapter element 24 does not occur during compaction, if the configuration according to FIG. 2 is assumed.

The lower edge 36 of the upper feeder part 18 acts as a stamp surface on the material to be compacted between the lower edge 36 and the mold model 12 during the compression process.

4 is a plan view of the feeder element 10. In the illustrated embodiment, four path limiters 26 are provided, distributed uniformly over the circumference of the adapter element 24, which are an integral part of the adapter elements. Against this Wegbegrenzer 26, the tubular element 22 is located at a maximum insertion in sections of its circumference. The Wegbegrenzer 26 are disposed within the adapter member 24 that the outer surface 46th of the first end 14 opposite edge region of the tubular member 22 is freely present in sections of the circumference. Alternatively, the path limiter (s) 26 may be arranged in the adapter element 24 in such a way that the outer surface 46 of the edge region of the tubular element 22 opposite the first end 14 is freely present with its entire circumference. From Fig. 4, the sectional planes A and B can be seen, which are used in Figures 2 and 5.

5 shows an enlarged longitudinal section through the feeder element 10, consisting of the adapter part 24 and the tubular element 22. The illustration includes two cutting planes through the adapter element 24: on the left in FIG. 5, the axis of rotation 48, the cutting plane is selected that the Wegbegrenzer 26 is not cut (section A), on the right side of the axis of rotation 48 in FIG. 5, the cutting plane through the Wegbegrenzer 26 (section B, to select the cutting planes see also Fig. 4). It can again be seen that the outer surface 46 of the edge region 46 of the tubular element 22 opposite the first end 14 is free in sections of the circumference. The cavity 44 of the adapter member 24 includes the free portions of the outer surface 46 of the first end 14 opposite edge region of the tubular member 22 at maximum insertion, so that liquid metal during the casting process with the outer surface 46 of the tube-like element 22 contact and contact there can remain. After solidification of the metal is achieved so that the feeder insert 8 breaks off during cleaning in the immediate vicinity of the casting and not in the upper region of the outer surface 46 of the tubular member 22.

Depending on the field of application, the tube-like element 22 can already be completely inserted into the adapter element 24 prior to compaction (compare FIG. 2). In this case, the compression forces, which act on the feeder insert 8 during the compression process, are absorbed only by the relative movement between the upper feeder part 18 and the adapter element 24. In the alternative case, in which the tube-like element 22 has a length between 10 and 30 mm and not as far as possible in the state of delivery before compression the adapter element 24 is inserted, a slot of at least 4 mm is ensured, see. Fig. 1.

In this alternative case, the compression forces occurring during the compression of the molding material are counteracted by two separate relative movements: first, by the relative movement between the upper feeder part 18 relative to the adapter element 24 and, secondly, by the relative movement between the adapter element 24 and the tubular element 22.

FIGS. 1-3 also schematically illustrate a method according to the invention for arranging a feeder insert according to the invention in a casting mold.

1, a tube-like element 22, which is inserted into an adapter element 24, placed together with this on a centering mandrel 36 which is mounted on a mold model 12. The tubular element 22 is thereby brought into direct contact with the mold model 12 with a first end 14. In Fig. 1, the tubular member is only partially, i. not maximally inserted far into the adapter element 24. Alternatively, the tubular element 22 can be inserted maximally far into the adapter element 24, cf. Fig. 2.

Subsequently, an upper feeder part is placed on the adapter element 24 so that it is supported by this. For this purpose, holding projections 34 are provided, for example. There is now a composite feeder insert 8 in a possible output arrangement.

In a subsequent step illustrated only in FIG. 2, the feeder insert 8 is enveloped with molding sand 32 or another molding material (cladding indicated only in the lower region). In FIG. 2, the tube-like element 22 is inserted maximally far into the adapter element 24, so that it rests against travel limiters 26 and can no longer be pushed into the adapter element 24. Whether the tubular element 22 partially or maximally in the adapter element 24 before the Compression process is inserted depends on the particular application.

After a compression process, not shown in the figures, the arrangement according to FIG. 3 results. The holding projections 34 are broken off by the adapter element 24, the upper feeder part 18 is pushed telescopically a distance onto the adapter element 24. The displacement path of the upper feeder part 18 on the adapter element 24 is predetermined by the degree of molding material compaction. In the event that the tube-like element 22, as shown in Fig. 1, was not pushed far into the adapter element 24 prior to the compression process, it is pushed by the force acting in the compression process force as far into the adapter element 24 until it at the Wegbegrenzern 26 is applied and then prevented from further insertion. During the compression process, the spring mandrel 36 breaks through the upper wall 54 of the upper riser 18; The depth of the centering bore 52 is chosen so that the displacement between the upper feeder part and the adapter element 24 is not hindered.

Since the outer wall 38 protruding over the first adapter element 24 of the upper feeder part 18 acts like a die on the between it and the mold model 12 during the compression process, an excellent molding compound compression occurs in this area (in FIG. 3 by a comparison with FIG. 2 denser puncturing of the molding sand 32 indicated).

Claims

claims A feeder element (10) for use in casting metals in molds, comprising a first end (14) for seating on a mold model (12) and an opposing second end (16) for connecting to or supporting an upper riser (18). wherein the feeder element (10) has a liquid metal passage (20) extending from the first to the second end (14, 16), characterized in that the feeder element (10) is two or more parts and comprises or consists of: ( i) a tubular element (22) forming the first end (14) of the feeder element (10) and having a maximum wall thickness of 1.5 mm; (ii) an adapter element (24) having an opening into which the tubular element (22) 22) is inserted so that it is frictionally connected to the adapter element, wherein the adapter element (24) comprises one or more Wegbegrenzer (26) for limiting the insertion path for the tubular element (22), which are arranged so that the Außenfl surface (46) of the first end (14) opposite the edge region of the tubular member (22) at a maximum distance within the insertion of the adapter element (24), with its entire periphery or portions of the periphery is present free. 2. feeder element (10) according to any one of the preceding claims, wherein the tubular element (22) in the adapter element (24) (a) is not inserted maximally far, so that it can be further inserted into the adapter element (24) until it is prevented by the Wegbegrenzern or (26) at another slot or (B) is inserted a maximum so that it is prevented by the Wegbegrenzern or (26) at another slot. 3. feeder element (10) according to any one of the preceding claims, wherein the adapter element (24) forms the second end (16) of the feeder element (10). 4. Feeder element (10) according to one of the preceding claims, wherein the tubular element (22) is cylindrical and / or has a length in the range of 10 to 30 mm. 5. feeder element (10) according to one of the preceding claims, wherein the tubular element (22) is made of a material which is selected from the group consisting of: metallic, ceramic or plastic materials and composite materials based on metal, ceramic and or plastic, wherein the tubular element is preferably made of iron, an iron alloy such as steel, aluminum, an aluminum alloy, a brass alloy or ceramic. 6. Feeder element (10) according to one of the preceding claims, wherein the adapter element (24) is made of an exothermic or insulating molding compound. 7. feeder element (10) according to any one of the preceding claims, wherein the adapter element (24) has a wall or a wall portion whose thickness in sections or everywhere is greater than the thickness of the tubular element (22) at the first end (14) of the feeder element ( 10). A feeder sleeve (8) for use in casting metals in molds, having a cavity for receiving liquid metal, comprising or consisting of a feeder element (10) according to any one of the preceding claims and an upper riser (18). 9. Feeding insert (8) according to claim 8, wherein the feeder element (10) and the upper feeder part (18) are slidable into one another. 10. feeder insert (8) according to claim 8 or 9, wherein in the feeder element (10) the tubular element (22) in the adapter element (24) not a maximum of far a is pushed so that it can be further inserted into the adapter element (24) until it is prevented by the Wegbegrenzern or (26) at another slot. 1 1. Feeding insert (8) according to any one of claims 8 to 10, wherein the feeder element (10) and the upper feeder part (18) together form a cavity (30, 44) for receiving liquid metal. The feeder sleeve (8) according to any one of claims 8 to 11, comprising or consisting of: (a) a two or more parts feeder element (10) having a first end (14) for seating on a mold model (12) and an opposite second end (16), the feeder element (10) extending from the first to the second end (14). 14, 16) has liquid metal passage (20) and comprises or consists of: (a) (i) a tube-like element (22) forming the first end (14) of the feeder element (10) and having a maximum wall thickness of 1.5 mm at the first end, (a) (ii) an adapter element (24) having a wall whose thickness is greater than that of the tubular element (22) at the first end (14) of the feeder element (10), and an opening into which the tubular element (22 ) is inserted so that it is frictionally connected to the adapter element (24), and (b) an upper riser (18), the riser (10) being connected to and / or supporting the upper riser (18) via its second end (16), the riser (10) and upper riser (18 ) are displaceable into one another and form or enclose a cavity (30, 44). 13. A kit for producing a feeder element according to one of claims 1 to 7, comprising a tube-like element and an adapter element. 14. Kit for producing a feeder insert (8) according to one of claims 8 to 12, comprising a tube-like element (22) and an adapter element (24) for producing a feeder element (10) according to one of claims 1 to 7 and an upper feeder part (18). 15. Method for arranging a feeder insert (8) in a casting mold, comprising the following steps: Providing a feeder element (10) according to one of claims 1 to 7, wherein the tubular element (22) into the adapter element (24) (a) is not inserted maximally far, so that it can be further inserted into the adapter element (24) until it is prevented by the Wegbegrenzern or (26) at another slot or (b) is inserted so far that it is prevented from the one or more Wegbegrenzern (26) at another slot, Providing an upper riser part (18), placing the upper riser part (18) on the feeder element (10) so that a feeder insert (8) according to one of claims 8 to 12 is formed, arranging the feeder insert (8) in a molding machine, Filling molding material (32) into the molding machine so that the outer walls of the feeder insert (8) are in contact with the molding material (32), - compacting the molding material (31), wherein the tubular element (22) in case (a) further into the adapter element (24) is inserted until it is prevented by the Wegbegrenzern or (26) at a further slot. 16. The method of claim 15, wherein the upper feeder part (18) and the feeder element (10) are selected so that when placing the upper feeder part (18) on the feeder element (10) a feeder insert (8) is formed, in which The feeder element (10) and the upper feeder part (18) are slidable into one another, and wherein the compression of the molding material (32), the upper feeder part (18) and the feeder element (10) are moved into one another. 17. The method of claim 16, wherein the molding machine comprises a pattern plate and the feeder element is inserted into the molding machine so that it is in direct contact with the pattern plate with its first end.