WO2018146224A1 - Method and extrusion installation for producing a blank from a ceramic mass and blank - Google Patents

Abstract

A method and an extrusion installation (2) are provided, for producing a blank (10) from a ceramic mass with a prescribed first diameter (D1). The extrusion installation (2) has at the end a mouthpiece (8) with an outlet diameter (D2), which is smaller than the first diameter (D1). The ceramic mass is pressed against a movable blank table (14), wherein a counterpressure is produced by means of the blank table (14) on the ceramic mass leaving the mouthpiece (8) in such a way that it is widened to the first diameter (D1) to form the blank (10).

Description

 description

 Process and extrusion plant for producing a Hubeis from a ceramic mass and Hube!

The invention relates to a method and an extrusion system for producing a Hubeis of a ceramic mass with the features of the preambles 1 and 13. The invention further relates to a Hubel.

The insulation of high-voltage power lines and systems is an essential part of high-voltage technology. High demands are also placed on the isolators in substations and substations. As insulators often ceramic insulators are used.

For the production of such insulators a ceramic mass is used, which is formed by an extrusion process into a so-called Hubel. This Hubel, also called blank, is then brought by means of cutting processes in a desired geometry for the respective application requirements. After drying, a glaze is usually applied, for example, in an immersion bath. Subsequently, the processed blank is fired and the insulator is obtained. The material density of such Hubel plays an important role in the quality of the later insulators. In order to produce a high density of material, in particular so-called vacuum extrusion systems are used, which are often oriented vertically.

High-voltage and extra-high voltage systems use large-diameter insulators with a diameter in the range of 200mm to 500mm or up to 600mm and a length in the meter range. DE 00 0001 258 775 B discloses such a vertical vacuum extrusion system. This system has a main press cylinder, a compression head and a cylindrical mouthpiece. The procedure and the main function of cylindrical mouthpieces can be found in "Technology of Ceramics", Volume 2, VEB Verlag, p 1 65-1 66. Here, a ceramic mass is fed to a vertically arranged extruder and evacuated The aid of a press screw and a press head compacts and leaves the extruder through the mouthpiece adjoining the press head To prevent the ceramic mass leaving the mouthpiece being torn off, there is a so-called lifting table below the mouthpiece, which receives the ceramic mass to form the hoof ice and moves in synchronism with the exit velocity of the Hubeis in a vertical direction away from the mouthpiece.

With conventional methods, a production of special large-caliber Hubein with high material compaction is limited.

Based on this, the present invention seeks to provide a method for producing a particular large-caliber Hubeis and an extrusion plant, with the aid of a large-caliber Hubel can be produced with a high density. Furthermore, the invention has the object to provide a Hubel with high density.

The object is achieved by a method for producing a particular large-caliber Hubeis with the features of claim 1. The Hubel is made of a ceramic mass and has a first diameter. The first diameter describes a maximum outer diameter of the Hubeis and thereby defines a Hubeldurchmesser.

In the method, a ceramic mass is forced through a mouthpiece and received by a Hubeltisch which exerts a counter pressure on the mouthpiece leaving mass. Of particular importance is that the mouthpiece extends in a vertical direction from a smallest interior diameter in particular conically expanded to an outlet diameter, wherein the inner diameter is smaller than the diameter of the hub. By the back pressure of the Hubeltisches is thereby ensured that the mouthpiece is filled at the end in the region of the extended outlet diameter homogeneously with the mass.

Investigations have shown that in a surprising way a particularly good compaction is achieved. The compaction is decisively determined by the smallest inner diameter of the mouthpiece, since here the mass undergoes a highest compression. This compression is subsequently maintained despite the extension of the mouthpiece. The plastic mass therefore has a kind of memory with respect to the compaction. A recovery or relaxation by the conical expansion is not or only to a small extent. This is also evident in a significantly reduced shrinkage during drying compared to conventionally manufactured Hubein. With conventionally manufactured Hubein shrinkage during drying is about 3% (by volume). In a manufactured with the new method described here Hubel this shrinkage is reduced to about 1% during drying. Due to the counterpressure, the desired diameter of the bowl, which is larger than the inner diameter, is achieved at the same time.

The advantage of this embodiment is to be seen in the simple production of großkalibriger Hubel with high material density. This results in the finished insulators after firing to a higher mechanical (bending) strength. Investigations have shown that the strength - compared to conventionally manufactured Hubein / insulators - could be increased by about 20% to 25%. This in turn allows for the design of insulators with the increased strength and to use smaller or thinner insulators with less material at the same strength values. This results in significant material savings. Overall, the quality of the Hubel and the later insulators are improved by the new process. In addition, this also reduces the reject rate in the production of the Hubel. In addition, this also allows the production of Hubein very large diameter, their production (with sufficient strength) was previously not possible with conventional methods.

In the method, a plurality of mouthpiece variants with different (minimum) inner diameter and outlet diameter are expediently used. In this case, the minimum inner diameter in all variants preferably has values in the range from 350 mm to 500 mm, in particular values in the range between 430 mm and 460 mm. The advantage of this embodiment is a uniform and simple installation of the mouthpiece variants.

Preferably, the mouthpiece extends in a vertical direction under a

Cone angle from inside diameter to outlet diameter. The cone angle of the mouthpiece is preferably in the range between 2 ° and 5 ° and in particular in the range of 3 ° to 4 °. A cone angle in this angular range has proven to be particularly suitable for the production in particular großkalibriger Hubel with a diameter of more than 450mm, which have a high strength.

In an expedient embodiment, the mouthpiece has a conical indentation at an upper end. As a result, the mouthpiece has at its upper end a larger diameter compared to the minimum inner diameter. This is used, in particular for small inner diameters, to widen the mouthpiece on a flange side to the pressing head to a defined size in order to ensure a uniform flange for fastening for different mouthpieces. Due to the conical indentation, the ceramic mass additionally experiences compaction in the catchment area.

Alternatively, no feeder is provided and the mouthpiece widens continuously conically from its upper end to its lower end. The mouthpiece therefore already has the inner diameter at its upper end. For the production of large-bore Hubein the first diameter (Hubeldurchmesser) preferably has values in the range of 400mm to 650mm and in particular in the range of 430mm and 620mm.

The extension of the mouthpiece is used in particular to set a desired diameter of the Hubeis. The exit diameter preferably has values in the range between 270 mm and 600 mm, in particular in the range from 400 mm to 570 mm.

In a preferred embodiment, the ceramic mass leaving the mouthpiece is expanded by the back pressure to the desired first diameter of the Hubeis. The outlet diameter of the mouthpiece is therefore less than the (maximum) outer diameter of the Hubeis. The Hubel is therefore even conical and tapers from its first diameter (maximum diameter of the hub) up to the outlet diameter.

In a preferred embodiment, the first diameter is greater than the exit diameter by 5% to 15% and more preferably by 7% to 12%. the outer diameter of the Hubeis is greater than the exit diameter of the mouthpiece.

The hubs typically have a length in the range of 2m to 3.5m. Typically, the length correlates with the diameter of the bowl, preferably at least approximately proportionally. Short Hubel (eg 2m) therefore have a small Hubeldurchmesser of z. B. 400mm - 450mm and long Hubel (eg 3.5m) has a large diameter of z. B. 580mm to 630mm.

The Hubel thereby widening preferably conically at an angle, which is preferably in the range of 4 ° to 7 ° and in particular in the range of 5 ° to 6 °.

The area ratio of a first cross-sectional area, which is determined by the (maximum) outer diameter of the Hubeis, and a second cross-sectional area defines a compression. The second cross-sectional area is an exit-side cross-sectional area of an extruder in which a compression screw is arranged, which typically ends at the end of the extruder. Following the extruder, the mouthpiece is arranged, wherein usually between the mouthpiece and the extruder, a pressing head is arranged. The compression is preferably in the range between 3 and 5. It is for example "adjusted" by a suitable choice of the mouthpiece with a defined internal diameter and / or by the setting of a suitable backpressure With increasing first diameter (diameter of the neck), the compression usually decreases.

In order to achieve a high material strength in the formation of Hubein with a first diameter in the range between 400mm and 500mm, the compression is preferably set to a value of 3.5 to 5.

The compaction for jackets having a first diameter in the range of 500 mm to 650 mm advantageously has a value in the range of 3 to 4. The advantage of the chosen compaction values is a reduced failure rate of the hubs over conventional hubs, which are manufactured with a cylindrical mouthpiece and have lower compaction. The failure rate has been reduced by one third to one quarter over such conventional stroke.

Advantageously, the back pressure of the lifting table has a value of more than 0.5 N / mm ² and in particular more than 1 N / mm ² . Advantageously, the value is at most 3.5N / mm ² or at most 2.5N / mm ² . In particular, the back pressure is in the range between 1, 5N / mm ² and 2.5 N / mm ² .

As a result, on the one hand, a deformation of the mass in the conical mouthpiece and on the other a subordinate compression of sectional textures in the Hubel achieved. The cut textures are created by the press screw working in the extruder. This creates helical cutting planes that correspond to the screw pitch. This creates nested strands with a strongly smoothed surface. These are in the press head and in the mouthpiece so squeezing that they make an intimate connection The result is a compact Hubel. The more intense this is, the higher the compression. Therefore, the ratio of the diameter of the press screw (which is the second

Cross-sectional area defined) to the minimum inner diameter of the mouthpiece of particular importance.

With the method preferably large-caliber Vollkernhubel be prepared, which are usually made of solid core insulators. These

Insulator type offers improved dielectric strength in the range of high and high voltage compared to hollow insulators. In principle, the method described here can also be used for the production of hollow insulators.

The object underlying the invention is further achieved by an extrusion system for producing a Hubeis with the features of claim 13. The Hubel is formed from a ceramic mass having a predetermined first diameter. The extrusion plant has an extruder, and at the end a mouthpiece. Usually, between the extruder and the mouthpiece still a pressing head, often a stepped pressing head arranged. The mouthpiece extends in a vertical direction and has an outlet diameter on the end. Furthermore, the extrusion plant has a movable in and against the vertical direction Hubeltisch and a control device. Preferably, the extruder is vertically aligned and formed as a vacuum extruder. In this case evacuation chambers are usually arranged inside the extruder in order to vent the ceramic mass and thus to produce a complete material throughput and to eliminate quality-reducing inclusions within the ceramic mass.

The vertical construction offers an advantage in that the ceramic mass moves in addition to the force generated by the screw and the friction occurring due to their own mass in the direction of the mouthpiece and thus takes place a mechanical relief of the screw press. Based on this, this design offers advantages in terms of maintenance and longevity of the extruder. The pressing head is for example designed such that it is realized as a stepped pressing head. During the manufacturing process, the ceramic mass undergoes compression in the pressing head to the hub before it exits via the end piece attached to the pressing head.

Of particular importance is that the mouthpiece widens conically from a (minimum) inner diameter to the exit diameter. The inner diameter and preferably also the exit diameter is smaller than the first diameter (maximum diameter of the hub).

The object is further achieved by a Hubel, which is in particular made by means of the method described above. The Hubel tapers conically at an angle from an upper end to a lower end. This conical geometry is created by the back pressure of the Hubeltisches on the mouthpiece leaving ceramic mass in the formation of the Hubeis.

The angle is advantageously in the range between 4 ° and 7 °, in particular in the range of 5 ° to 6 °.

The advantages and preferred embodiments listed with regard to the method are to be transferred analogously to the extrusion plant and / or to the Hubel and vice versa.

Embodiments of the invention will be explained in more detail with reference to FIGS. These show partly in highly simplified representations:

1 shows a basic structure of an extrusion system with movable

 Hubeltisch and control device for production of a Hubeis,

2A-B is a longitudinal sectional view of two embodiments of a variant

Mouthpiece 3 is a fragmentary longitudinal sectional view of a

Vacuum extrusion plant, as well

 A longitudinal sectional view of a Hubeis.

In the figures, like-acting parts are represented by the same reference numerals.

1 shows a basic structure of an extrusion plant 2 for producing a Hubeis 10 of a ceramic mass having a predetermined first diameter D1. The first diameter D1 defines a maximum outer diameter of the Hubeis 10, in the present case also referred to as Hubeldurchmesser. The extrusion plant 2 shown in Figure 1 is realized in a vertical construction and extends in a vertical direction 12. The extrusion plant 2 is used for the production of particular großkalibrigen Hubein 10. The vertical construction allows exploitation of the force acting on the ceramic mass gravity. Since the production direction and the direction of gravity correspond, the promotion of the ceramic mass is favored.

The extrusion plant 2 has an extruder 4, a subsequent to the extruder 4 pressing head 6 and a mouthpiece 8. The mouthpiece 8 joins seen in the vertical direction 12 to the pressing head 6 and has an outlet diameter D2 on the end. In this case, the second diameter D2 is smaller than the first diameter D1.

The extruder 4 is preferably designed as a vacuum extruder. By this configuration, a venting of the ceramic material is possible.

Preferably, the pressing head 6 is formed such that it has a plurality of pressing stages. A so-called stepped pressing head allows a high compression of the ceramic mass.

The mouthpiece 8 is preferably attached by means of a screw end to the pressing head 6 and is used in addition to the pressing head 6 for training of the Hubeis 10. By screwing a low-cost replacement of the mouthpiece 8 is guaranteed.

Furthermore, the mouthpiece 8 is conical. The mouthpiece 8 therefore has a (minimum) inner diameter D3, from which it widens conically to the outlet diameter at a cone angle α. The mouthpiece 8 typically has a length L in the vertical direction 12 which is in the range between 500 mm and 1200 mm and in particular in the range from 700 mm to 900 mm.

In the vertical direction 12 and thus seen in the production direction, a movable in and counter to the vertical direction 12 lifting table 14 is formed below the mouthpiece 8. This and the entire extrusion system 2 are controlled by a control device 1 6. The lifting table 14 is designed such that it exerts a counter-pressure on the mouthpiece 8 leaving ceramic mass during operation.

Due to the back pressure of the Hubeltisches 14 a pressure on the ceramic mass in the mouthpiece 8 is exercised, so that this reliable - despite the conical expansion - is filled. The decisive factor here is that by the smaller compared to the outlet diameter D2 inner diameter D3, the mass undergoes a high compression, which defies the subsequent expansion is maintained.

 Due to the counterpressure, furthermore, the ceramic mass leaving the mouthpiece 8 is preferably further expanded to form the hoop ice 10 to the first diameter D1. As a result, a conically widening Hubel 10 is formed.

For this purpose, the control unit 1 6 and the lifting table 14 are designed such that they adjust the counter-pressure to a value of at least 0.5N / mm ² , in particular of more than 1 N / mm ² or more than 1, 5N / mm ² during operation ,

Conveniently, the back pressure preferably has a value of 2.5 N / mm ² . In particular, it is in the range of 1, 5 N / mm ² to 2.5N / mm ^2. The Control unit is connected, for example by means of a control line to the Hubeltisch 14. Overall, the control unit 16 is designed such that it controls the entire extrusion process in the desired manner. The control variable for controlling the Hubeltisches is preferably the counterforce.

FIGS. 2A and 2B show longitudinal sections of variants of the mouthpiece 8. The mouthpieces 8 preferably have an upper end 8a, on which a flange for attachment to the pressing head 6 is formed. The mouthpiece 8 also has a lower end 8b, on which the outlet diameter D2 is defined.

The respective mouthpiece 8 each has a minimum inner diameter D3. From this, the mouthpiece widens in particular conically under a cone angle α on the outlet diameter D2 Preferably, a continuous, uniform conical enlargement is provided. In principle, however, can not be provided conical sections, z. B. at the lower end 8b, a cylindrical end portion,

Preferably, the cone angle α is in a range between 2 ° and 5 °, in particular in a range of 3 ° to 4 °. In connection with the pressing by the Hubeltisch 14 is made possible by this mouthpiece topology by a preferably 50% higher compression of the ceramic mass in the training for Hubel 10, as in the case of the prior art Hubein.

In the variant according to FIG. 2A, the mouthpiece 8 additionally has a conical indentation 18 at the upper end 8a, so that the mouthpiece initially tapers from an inlet diameter D4 to the inner diameter D3. The conical intake 18 extends only over a small portion of the length L1 of the mouthpiece 8, for example, a maximum of over 5% or at most over 10% of the length L1. As a result, a compression is achieved in the region of the feeder 18. Specifically, this indentation 18 serves to bring the upper end 8a with the flange to a defined size to a plurality of mouthpieces 8 with different inner diameter D3 and exit diameter D2 with a flange of the same To train size. As a result, different mouthpieces 8 can be connected to a same pressing head 6.

In contrast, in the embodiment of FIG. 2B, the mouthpiece 8 widens continuously from the upper end 8a to the lower end 8b. In this variant, therefore, the inner diameter D3 is set directly by the upper end 8a.

According to FIG. 3, the extruder 4 has a vertical construction known per se. The extruder 4 shown in longitudinal section has a first extruder part 22, a second extruder part 24, a press screw 20, the pressing head 6 and the mouthpiece 8.

The second extruder part 24 closes at the end viewed in the vertical direction 12 to the first extruder part 22 at. The first extruder part 22 serves to pre-compact the ceramic mass, which is further compressed by the press screw 20 in the further course. In addition, the second extruder part 24 has longitudinal strips in the interior on the circumferential side. The longitudinal strips support the promotion of the ceramic mass within the second extruder part 24.

The extruder 4 is designed overall as a vacuum extruder and has for this purpose evacuation chambers, which are not shown in Fig. 3. With the help of evacuation chambers of the ceramic mass are removed by venting any inclusions and achieved a uniform material throughput.

The promotion of the ceramic mass is realized by means of the press screw 20. In operation, it rotates and compresses the ceramic mass within the extruder 4 by rotation about an axis of rotation 21. Because of the vertical configuration of the extruder 4, the extruder screw 20 undergoes mechanical relief due to the inherent movement of the ceramic mass caused by gravity. The press screw 20 has at its end on a Endschneckenstück, which is connected to a central shaft via a toothing (Hirth toothing). The end of the second extruder 24 subsequent pressing head 6 serves to densify the ceramic mass. The surface at the end-side transition point between the second extruder part 24 and the pressing head 6 defines a second cross-sectional area F2.

The pressing head 6 shown in Fig. 3 is designed as a stepped pressing head, which also has circumferentially longitudinal strips inside.

The conical mouthpiece 8 adjoins the pressing head 6 at the end. At the lower end 8b of the mouthpiece 8 located in the vertical direction 12, this has the exit diameter D2.

In Fig. 3 the mouthpiece 8 is still a central linkage 26 is arranged, on the end a bell-shaped extension is attached. This serves to form a central cavity. The mouthpiece 8 is therefore provided for forming a Hohlhubeis.

Preferably, however, such a linkage 26 with the bell-shaped extension is dispensed with and the mouthpiece 8 is designed to form a full-core lever 10, which therefore has no hollow space.

The Hubel 10 shown in Figure 4 is designed as großkalibriger Vollhubel. Full-stroke or Fullkernhubel this geometry are preferably used in high-voltage and ultra-high voltage technology, since they are made so-called full core support insulators. This type of insulator offers advantages in the area of dielectric strength compared to hollow insulators and is therefore preferred for use in the high and very high voltage range.

The Hubel 10 preferably has a β at an angle from an upper end to a lower end conical course. The angle is

expediently in the range between 4 ° and 7 °. The Hubel 10 preferably has at a lower end the first diameter D1 through which a first cross-sectional area F1 is defined. The first diameter D1 corresponds to the maximum outer diameter of the Hubeis.

At an upper end of the Hubel 10 has a diameter corresponding to the outlet diameter D2. The Hubel 10 has in the vertical direction 12 from an upper end to a lower end a length L2. This is typically in the range of 2m to 3.5m.

In addition to the second cross-sectional area F2 provided by the extruder 4, the area ratio between the first cross-sectional area F1 and the second cross-sectional area F2 defines a compression, which is preferably set to a value between 3 and 5.

LIST OF REFERENCE NUMBERS

2 extrusion line

 4 extruders

 6 pressing head

 8 mouthpiece

 8a upper end of the mouthpiece

 8b lower end of the mouthpiece

 10 hips

 12 vertical direction

 14 lifting table

 1 6 control device

 18 conical feeder

 20 press screw

 21 rotation axis

 22 first extruder part

24 second extruder part

26 linkage

α cone angle of the mouthpiece

ß Angle of the conical extension of the Hubeis

D1 first diameter

 D2 outlet diameter

 D3 inner diameter

 D4 inlet diameter

 F1 first cross-sectional area

 F2 second cross-sectional area

 L1 length of the mouthpiece

 L2 length of the Hubeis

Claims

claims

1 . Method for producing a straw (10) from a ceramic mass having a predetermined first diameter (D1) by means of a

 Extrusion plant (2), which has a mouthpiece (8) with an inner diameter (D3)

 characterized,

 in that the mouthpiece (8) expands in a vertical direction (12) from the inside diameter (D3) to an outlet diameter (D2), that the inside diameter (D3) is smaller than the first diameter (D1), and that the ceramic mass is vertical direction (12) through the mouthpiece (8) against a Hubeltisch (14) is pressed, over the Hubeltisch (14) a back pressure on the mouthpiece (8) leaving ceramic mass is generated.

2. The method according to claim 1

 characterized,

 in that the mouthpiece (8) tapers conically under a cone angle (a) which lies in the range between 2 ° and 5 °, in particular in the range between 3 ° and 4 °.

3. The method according to one of the two preceding claims

 characterized,

 the mouthpiece (8) has a conical indentation (18) at an upper end (8a).

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

 characterized,

 the outlet diameter (D2) is smaller than the first diameter (D1) such that the ceramic mass leaving the mouthpiece (8) is formed by the backpressure exerted by the lifting table (14) to form the hoist (10) to the first diameter (D1). is extended.

Method according to one of the preceding claims

 characterized,

the first diameter (D1) is preferably in the range between 300 mm and 650 mm, in particular in the range from 430 mm to 620 mm.

Method according to one of the preceding claims

 characterized,

the second diameter (D2) is preferably in the range between 270 mm and 600 mm, in particular in the range from 400 mm to 570 mm.

Method according to one of the preceding claims

 characterized,

the first diameter (D1) is 5% to 1 5% and in particular 7% to 1 2% greater than the second diameter (D2).

Method according to one of the preceding claims

 characterized,

in that a first cross-sectional area (F1) is defined by the first diameter (D1) and that the extrusion plant (2) has an extruder (4) which has a second cross-sectional area (F2) at the end and the area ratio between the first cross-sectional area (F1) and the second cross-sectional area (F2) defines a compression, wherein the compression in operation produces a value in the range of 3 to 5.

Method according to the preceding claim

 characterized,

that in operation, the compaction is generated with a value in the range of 3.5 to 5 for Hubel (1 0) with a first diameter (D1) in the range of 400mm to 500mm.

10. The method according to claim 8

 characterized,

 in operation, the compaction is generated at a value in the range of 3 to 4 for hoists (10) having a first diameter (D1) in the range of 500mm to 650mm.

1 1. Method according to one of the preceding claims

 characterized,

in that from the lifting table (14) there is a back pressure of more than 0.5 N / mm ² and at most 3.5 N / mm ² or at most 2.5 N / mm ² , in particular more than 1 N / mm ² , in particular in the range between 1, 5 N / mm ² and 2.5 N / mm ^{2 is} exercised.

12. The method according to any one of the preceding claims

 characterized,

 that the Hubel (10) is designed as Vollkernhubel.

13. Extrusion plant (2) for producing a Hubeis (10) of a ceramic mass having a predetermined first diameter (D1) having

 an extruder (4),

 a mouthpiece (8) extending in a vertical direction (12) and having an inner diameter (D3),

 a lifting table (14) movable in and against a vertical direction (12),

 a control device (1 6),

 characterized,

that extends the mouthpiece (8) in a vertical direction (12), starting from the inner diameter (D3) to an outlet diameter (D2).

14. Hubel (10), in particular produced by a method according to one of claims 1 to 12,

 characterized,

 that it widens conically at an angle (β) from an upper end to a lower end.

1 5. Hubel according to the preceding claim

 characterized,

 that the angle (β) is preferably in the range of 4 ° to 7 °, in particular between 5 ° and 6 °.