DE102018128345A1 - Electrode pin - Google Patents

Abstract

The invention relates to an electrode pin (1) for anodically contacting a component (10) during electropolishing of the component (10), the component (10) having a support structure (100) which extends along a longitudinal axis (x) and in a Circumferential direction (U) of the component (10) rotates so that the support structure (100) surrounds an interior (101) of the component (10), the support structure (100) having an interior (100a) facing the interior (101), and the electrode pin (1) further comprising: an anode (3) and a cathode (4). According to the invention, the electrode pin (1) is designed to be inserted into the interior (101) of the component (10), so that the anode (3) and the cathode (4) in the interior (101) of the component ( 10) are arranged, the anode (3) being configured to contact the inside (100a) of the component (10).

Description

The invention relates to an electrode pin for electropolishing a tubular component, in particular in the form of a support structure, for. B. in the form of a stent.

When electropolishing tubular components, in particular tubular lattice structures, there is the challenge of contacting the component in order to carry out the electropolishing, especially when the component has small diameters.

For tubular components in the form of balloon-expandable stents, the current polishing frames consist of a fixed counter bearing and one or two pre-stressed Nitinol wires. The stent is located between these two elements during polishing and is contacted from the outside. The stent is contacted several times during the polishing process. The cathode plate is located horizontally below the stent.

With regard to the aforementioned methodology, which is used in balloon-expandable stents, it may prove disadvantageous that there are a maximum of two contact points with the stent, the displacement of the contact points being possible only in one direction in a limited number. Surface defects can also occur due to contact points on the outside of the stent. Furthermore, there is no contact over the entire stent scope, so that the contact may be insufficient due to the lattice structure of the stent. Furthermore, a large area of the counter bearing of the external contact can make it difficult to supply the electrolyte in this area.

The electropolishing of self-expandable stents described above proves to be problematic in that the inner anode increases the risk of scratching the inside of the stent during manual displacement and there is also a spatial separation of the anode and cathode.

The US 20147/0360887 describes an anode used as a mandrel to hold the stent in the electrolytic bath.

Furthermore, the US 7,776,189 a system for electropolishing stents, which are rotated in the electrolyte by means of a drive.

Proceeding from this, the object of the present invention is to provide an electrode pin which enables good contacting of the tubular component for electropolishing and at the same time reduces the risk of scratching the inside of the component and in particular permits a uniform flow of electrolyte in all areas of the component.

This object is achieved by an electrode pin with the features of claim 1. Advantageous configurations of the electrode pin are specified in the corresponding subclaims and are described below. Further inventive ideas relate to an arrangement and a method for electropolishing using the electrode pin.

According to claim 1, an electrode pin for anodic contacting of a component during electropolishing of the component is disclosed, the component having a support structure which extends along a longitudinal axis and rotates in a circumferential direction of the component, so that the support structure surrounds an interior of the component, wherein the support structure has an inner side facing the interior, and the electrode pin has at least one anode and one cathode.

According to the invention, it is now provided that the electrode pin is designed to be inserted into the interior of the component in the direction of the longitudinal axis, so that the anode and the cathode are arranged in the interior of the component, the anode being configured to close the inside of the component to contact. The interior is in particular an elongated cylindrical interior or a cylindrical volume.

The present invention allows anodic and cathodic contacting in the interior of the component. This is particularly advantageous if the component is an intraluminal endoprosthesis and / or a stent-based heart valve prosthesis. It has been shown that the simultaneous arrangement of the anode and cathode in the interior of the component results in a significantly improved rounding of the struts of the support structure of the prosthesis.

It is preferably provided that the cathode lies opposite the inner side and is spaced apart from it when the electrode pin is arranged as intended in the interior of the component, the electrode preferably being at least 50%, in particular at least 70%, in particular at least 80%, in particular extends over at least 90% of the length of the component along the longitudinal axis.

The support structure of the component to be machined can have a large number of through openings and accordingly does not have to form a continuously closed outside or surface of the component in the manner of a jacket. The support structure can therefore in particular by a lattice structure be formed, the z. B. has a plurality of interconnected struts that can form cells of the support or lattice structure.

The component can in particular be a stent, which is provided in particular for implantation in the body of a patient. The stent can be a vascular support (e.g. for use in angioplasty) or a heart valve carrier of an implantable heart valve prosthesis. The stent can also be designed to be self-expandable. Alternatively, the stent can be designed to be expanded by means of a balloon.

With the present invention it is advantageously possible to anodically contact all stents from the inside. It is also possible to integrate the necessary counter electrode (cathode) in the same component. This ensures a clean and even polish on the outer surface without any imperfections at the contact points. An inner cathode along the entire length of the stent or component is particularly advantageous for longer stents or components.

With the internal contact according to the invention, it is also possible to shift the stent or the component as often as desired in both directions along the longitudinal axis of the component and to vary the contact point.

The integrated inner cathode ensures a uniform distance between the stent and cathode along the longitudinal axis of the component. This makes it possible, for example, to increase the edge rounding on the inside of the stent facing the balloon. Balloon damage from sharp edges can be avoided.

The internal contacts can also be distributed in any number over the entire stent or component length. This makes it possible to use the invention for different stent or component sizes (length, diameter).

According to one embodiment of the electrode pin, it is provided that the anode for contacting the inside of the component has at least one first contact surface, the at least one first contact surface for contacting the inside of the component being movable from a first position into an extended second position when the electrode pin is arranged in the interior of the component so that the at least one first contact surface of the anode contacts the inside of the component in the second position. It is preferably provided that the at least one first contact surface in the second position protrudes further in a radial direction of the electrode pin beyond an outside of the cathode than in the first position. In the case of a first contact surface arranged in the first position, the outer diameter of the electrode pin is correspondingly smaller than in the case of a first contact surface arranged in the second position, so that the electrode pin can be positioned in the interior of the component without contact with the component if the at least one first contact surface is in the first Position is arranged (this also applies in the case of several first and / or second contact surfaces, see below).

The electrode pin is preferably elongated and extends in an axial direction or along a longitudinal axis, the radial direction being perpendicular to the axial direction or to the longitudinal axis of the electrode pin and pointing outwards or away from the longitudinal axis.

Furthermore, according to one embodiment of the electrode pin, it is provided that the electrode pin has an elongated carrier which extends along the longitudinal axis of the electrode pin, the anode and the cathode being arranged on the carrier, so that the carrier with respect to the anode and the cathode along the Longitudinal axis is displaceable.

Furthermore, according to one embodiment of the electrode pin, it is provided that the carrier has at least one spreading element, the at least one spreading element being configured to press against the anode when the carrier is displaced with respect to the anode along the longitudinal axis of the carrier / electrode pin such that the at least one a first contact surface of the anode is moved from the first position into the second position or is pushed outward in the radial direction.

Furthermore, according to one embodiment of the electrode pin, it is provided that the at least one expansion element is designed as an expansion cone or has a cone-shaped section which, when pressed against the anode, urges the at least one first contact surface (or the plurality of first contact surfaces, see below) outwards ( towards the inside of the component), so that the at least one first contact surface contacts the inside of the component when the electrode pin is arranged in the interior of the component.

Furthermore, according to one embodiment of the electrode pin, it is provided that the cathode encloses the carrier and the anode at least in sections.

Furthermore, according to one embodiment of the electrode pin, it is provided that electrical insulation is arranged between the cathode and the anode. This insulation is preferred tubular and can be designed in particular in the form of a shrink tube.

Furthermore, according to one embodiment of the electrode pin, it is provided that the at least one expansion element is formed on a first end of the carrier. The at least one expansion element can, for. B. be formed by a circumferential projection at the end of the carrier.

Furthermore, according to one embodiment of the electrode pin, it is provided that the at least one expansion element is designed to press against a plurality of first sections (in particular end sections) of the anode, particularly in the direction of the longitudinal axis of the anode, when the carrier is displaced with respect to the anode along the longitudinal axis of the carrier Support protrude from the cathode, wherein the at least one first contact surface is formed by one of the first sections, and wherein the further first sections of the anode form further first contact surfaces of the anode, which are each movable from a first position to a second position, the respective first contact surface is moved from its first position to its second position when the at least one expansion element of the carrier presses against the respective first section when the carrier is moved. In the second position, the first contact surfaces preferably protrude beyond the outer cathode in the radial direction of the electrode pin in order to contact the inside of the component when the electrode pin is arranged in the interior of the component.

Due to the large number of first contact surfaces, the inside of the component can be contacted along the entire circumference of the component by means of the first contact surfaces of the anode if these are arranged in the second position.

Furthermore, according to one embodiment of the electrode pin, it is provided that the first sections of the anode are formed by a tubular end section of the anode, which extends along the longitudinal axis of the electrode pin and in particular protrudes from the cathode in the direction of the longitudinal axis, the first sections being formed by slots in the tubular end portion are separated or formed from each other, the respective slot extending along the longitudinal axis of the tubular end portion of the anode or the electrode pin. Through the slots, the said first sections can be pushed apart slightly in the radial direction by the expansion element, the first contact surfaces provided on the outside of these first sections being transferred into their respective second positions and contacting the inside of the component (e.g. stent).

Furthermore, according to one embodiment of the electrode pin, it is provided that the carrier has a further spreading element which is spaced apart from the other spreading element on the carrier, the further spreading element being designed to move against the plurality of several when the carrier is displaced with respect to the anode along the longitudinal axis to press second sections of the anode, each second section forming a second contact surface of the anode for contacting the inside of the component, so that the respective second contact surface is moved from a first position to a second position when the further expansion element of the carrier is displaced of the carrier presses against the respective second section of the anode. The further expansion element can, for. B. be formed as a circumferential projection on the carrier of the carrier.

Here too, because of the large number of second contact surfaces, the inside of the component can be contacted along the entire circumference of the component by means of the second contact surfaces of the anode if these are arranged in the second position. The further expansion element can in turn be designed as an expansion cone or can have a cone-shaped section which, when pressed against the second sections of the anode, urges the second contact surfaces outward (in the direction of the inside of the component), so that the second contact surfaces cover the inside of the Contact the component if the electrode pin is located in the interior of the component.

Furthermore, according to one embodiment of the electrode pin, it is provided that the cathode has a first section and an adjacent second section, which are separated from one another on the outside of the electrode pin by a circumferential gap in the electrode pin, the second contact surfaces of the anode being configured such that that they protrude in the respective second position in a radial direction of the electrode pin from the gap over the two sections of the cathode to contact the inside of the component when the electrode pin is arranged in the interior of the component.

Furthermore, according to one embodiment of the electrode pin, it is provided that the first section of the cathode is connected in an electrically conductive manner to a core of the cathode which runs within the carrier along the longitudinal axis of the electrode pin or carrier, and in particular the second section of the electrode via a conductor is connected to the soul, the conductor running in particular outside the carrier. In the context of this application, the core of the cathode or anode means the innermost electrically conductive structure.

Furthermore, according to one embodiment of the electrode pin, it is provided that the electrode pin has a spring element which is configured to apply a force to the carrier such that the respective contact surface (ie the at least one first contact surface or the first contact surfaces and / or the second contact surfaces) is biased towards the respective second position.

The carrier can, for. B. by advancing against the spring force from the engagement with the first and / or second portions of the anode. This reduces the outside diameter of the electrode pin (the contact surfaces are in the first position) and the electrode pin can be inserted into the interior of the component. The carrier can then be displaced in the direction of action of the spring force along the longitudinal axis with respect to the anode, as a result of which the contact surfaces are transferred into their respective second positions and contact the inside of the component.

Another aspect of the present invention relates to an arrangement with an electrode pin according to the invention and a component (in particular a stent, see above), the component having a support structure which extends along a longitudinal axis and rotates in a circumferential direction of the component, so that the support structure is one Surrounds the interior of the component, wherein the support structure has an inside facing the interior, and wherein the electrode pin is inserted into the interior of the component, so that the anode and the cathode are arranged in the interior of the component, in particular the anode making contact with the inside of the component , e.g. B. in the manner described herein.

• - Einführen des Elektrodenstiftes in den Innenraum des Bauteils, so dass die Anode und die Kathode im Innenraum des Bauteils angeordnet sind,
• - Herstellen eines Kontakts zwischen der Innenseite des Bauteils und der Anode (insbesondere durch Verschieben des Trägers bezüglich der Anode), und
• - Anordnen des Elektrodenstifts und des Bauteils in einem Bad, das einen Elektrolyten enthält, sowie Anlegen einer Spannung zwischen der Anode und der Kathode zum Elektropolieren des Bauteils.

Another aspect of the invention relates to a method for electropolishing a component using an electrode pin according to the invention, the component having a support structure which extends along a longitudinal axis and rotates in a circumferential direction of the component, so that the support structure surrounds an interior of the component, wherein the support structure has an inner side facing the interior, and the method comprises the steps:

• Inserting the electrode pin into the interior of the component so that the anode and the cathode are arranged in the interior of the component,
• - Establishing a contact between the inside of the component and the anode (in particular by moving the carrier with respect to the anode), and
• - Placing the electrode pin and the component in a bath containing an electrolyte, and applying a voltage between the anode and the cathode for electropolishing the component.

The invention advantageously allows a uniform removal on the outside of the component and on the inside of the component, whereby defects can be avoided. The invention further ensures a uniform flow of electrolyte along the entire component. Furthermore, an improved edge rounding on the inside of the component is achieved. Any number of contact points results in a better current distribution. Furthermore, there is a better field formation by the inner cathode, which favors a uniform removal. Better process control is possible due to lower contact resistances. Due to the fact that the electrode pin is easily displaceable in both directions, even removal can also be achieved. Finally, the design of the electrode pin according to the invention has considerable automation potential, so that there is less manual influence when machining the component.

• 1 eine perspektivische Ansicht eines ersten Ausführungsbeispiels eines erfindungsgemäßen Elektrodenstifts;
• 2 eine teilweise geschnittene Ansicht eines Details des in der 1 gezeigten Elektrodenstifts;
• 3 eine ausschnitthafte Explosionsansicht des in den 1 und 2 gezeigten Elektrodenstifts;
• 4 eine perspektivische Ansicht eines weiteren Ausführungsbeispiels eines erfindungsgemäßen Elektrodenstifts;
• 5 eine Schnittansicht des in der 4 gezeigten Elektrodenstifts; und
• 6 verschiedene Gestaltungsmöglichkeiten für eine Elektrode eines erfindungsgemäßen Elektrodenstifts.

Embodiments of the invention and features and advantages of the invention are described below with reference to figures. Show it:

• 1 a perspective view of a first embodiment of an electrode pin according to the invention;
• 2nd a partially sectioned view of a detail of the in the 1 shown electrode pin;
• 3rd a fragmentary exploded view of the in the 1 and 2nd shown electrode pin;
• 4th a perspective view of another embodiment of an electrode pin according to the invention;
• 5 a sectional view of the in the 4th shown electrode pin; and
• 6 Different design options for an electrode of an electrode pin according to the invention.

The present invention relates to an electrode pin 1 for anodic contacting of a component 10th when electropolishing the component 10th , the component 10th how using the 1 and 2nd seen a support structure 100 has, which extends along a longitudinal axis x and in a circumferential direction U of the component 10th rotates so that the support structure 100 an interior 101 of the component 10th defined, the support structure 100 one the interior 101 facing inside 100a having.

According to the in the 1 to 3rd In the embodiment shown, the electrode pin has an anode 3rd as well as a cathode 4th on that inside the component 10th are arranged when the electrode pin, as in the 2nd is shown as intended in the interior 101 of the component 10th is introduced, which is exemplarily formed by a stent. For contacting the inside 100a of the component 10th points the anode 3rd at least a first contact area 300a on, z. B. four such first contact surfaces 300a are available. These first contact areas 300a are on four first sections 300 of a tubular end portion 30th the anode 3rd formed, the first sections 300 through a total of four slots 31 are separated from each other, extending along the longitudinal axis x ' of the electrode pin 1 extend.

The first contact areas 300a are now for contacting the inside 100a Movable from a retracted first position to a disengaged second position by the sections 300 by means of a preferably conical expansion element 20th in the radial direction R of the electrode pin 1 be pushed apart. The spreading element 20th is here at one end along the longitudinal axis x ' stretched carrier 2nd of the electrode pin 1 formed, the anode 3rd and the cathode 4th on the carrier 2nd are arranged so that the carrier 2nd regarding the anode 3rd and the cathode 4th along the longitudinal axis x ' is movable. The cathode is enclosed here 4th the anode 3rd and the carrier 2nd at least in sections (cf. 1 and 2nd ), said first sections 300 in the direction of the longitudinal axis x ' from the cathode 4th stand out. Between the anode 3rd and the cathode 4th is preferably electrical insulation 5 arranged, e.g. B. in the form of a shrink tube. The cathode 4th can be hollow cylindrical at least in sections and preferably extends essentially over the entire length of the component 10th along the longitudinal axis of the component (except for the section through the first contact surfaces 300a the anode 3rd is taken).

The carrier 2nd can now go against the anode 3rd along the longitudinal axis x ' be moved that the expansion element 20th in the in the 1 and 2nd entered direction of movement B against the first sections 300 bumps and pushes them apart in the radial direction R. Here are the first contact areas 300a outsourced to the second positions and contact the inside there 100a of the component 10th .

The 4th and 5 show a further embodiment of an electrode pin according to the invention, wherein the respective first section 300 the anode 3rd through an end section of a first electrical conductor 33 is formed, the first conductor 33 each part of the anode 3rd form and stretch along the beam 2nd extend. The first ladder 33 extend to an electrical contact 32 the anode 3rd , this contacting 32 the expansion element 20th in the direction of the longitudinal axis x ' opposite.

The said first sections 300 the anode 3rd in turn form the first contact areas 300a from that in the manner described above by the expansion element 20th at the end of the carrier 2nd can be pressed apart to be transferred to the respective second position in which the first contact surfaces 300a the inside 100a of the component 10th to contact.

In contrast to that in the 1 to 3rd shown embodiment of the electrode pin 1 it is now also provided that the electrode pin 1 according to 4th and 5 another on the carrier 2nd trained expansion element 21st has, the further expansion element 21st is designed to move the carrier 2nd regarding the anode 3rd along the longitudinal axis x ' of the electrode pin 1 against several second sections 301 the anode 3rd to press, taking every other section 301 a second contact area 301a the anode 3rd to contact the inside 100a of the component 10th forms, the respective second contact surface 301a is moved from a first position to a second position when the carrier 2nd with the further expansion element 21st against the respective second section 301 the anode 3rd presses. The second sections 301 the anode 3rd are preferably each through an end portion of a second conductor 34 formed, the second conductor 34 along the first ladder 33 or along the beam 2nd for contacting 32 over which all leaders are led 33 , 34 or contact areas 300a , 301a the anode 3rd are electrically contactable.

As from the 4th it can also be seen that the cathode is preferably provided 4th a first (e.g. helical) section 40 and an adjacent second (e.g. helical) section 41 has in the direction of the longitudinal axis x ' through a gap 8th are separated from one another, the second contact surfaces 301a the anode 3rd in the respective second position in a radial direction R of the electrode pin 1 out of the gap 8th stand out while doing so over the two sections 40 , 41 the cathode 4th protrude in the radial direction R to the inside 100a of the component 10th to contact when the electrode pin 1 in the interior 101 of the component 10th is arranged.

To form the said gap 8th it is provided that the first section 40 the cathode 4th electrically conductive with a soul 42 the cathode 4th connected within the carrier 2nd along the longitudinal axis x ' of the electrode pin 1 at the gap 8th passes by. The second section 41 the electrode 4th is especially about an electrical conductor 43 with an end section of the soul 42 connected so that contacting 44 for the cathode 4th is formed, the head 43 especially outside of the wearer 2nd runs.

Furthermore, according to 4th be provided that the electrode pin 1 a spring element 6 configured to support the carrier 2nd to apply such a force that the respective contact surface 300a , 301a is biased towards the respective second position. The spring element 6 can be at an abutment 7 of the carrier 2nd support that also as a handle for moving the carrier 2nd opposite the anode 3rd is usable.

The first and / or second contact surfaces 300a , 301a the anode 3rd of the above-described embodiments of the electrode pin 1 can be gold-plated or can be formed or have a noble metal. As a result, the lowest possible contact resistance can be achieved.

The cathode 4th of the electrode pins described above 1 or their sections 40 and 41 can continue z. B. by the type of 6 be trained. So z. B. the cathode 4th (see also 4th ) have an at least sectionally arranged helical electrical conductor, the z. B. as a round wire (cf. 6 (A) ) or as flat wire (cf. 6 (C) ) can be formed. So z. B. according 4th provided that the two sections 40 and 41 the cathode 4th are at least partially helical.

The cathode 4th can furthermore also have an electrical conductor which is at least partially hollow-cylindrical (cf. 1 to 3rd ), as in the 6 (B) is shown. It is conceivable for the two helical cathode sections 40 , 41 the 4th to be replaced by a hollow cylindrical section.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• US 20147/0360887 [0006]
• US 7776189 [0007]

Claims (15)

Electrode pin (1) for electropolishing a component (10), the component (10) having a support structure (100) which extends along a longitudinal axis (x) and runs in a circumferential direction (U) of the component (10), so that the support structure (100) surrounds an interior (101) of the component (10), the support structure (100) having an inside (100a) facing the interior (101), and the electrode pin (1) further comprising: an anode (3), and - a cathode (4), characterized in that the electrode pin (1) is designed to be inserted into the interior (101) of the component (10), so that the anode (3) and the cathode (4) are arranged in the interior (101) of the component (10), the anode (3) being configured to contact the inside (100a) of the component (10). Electrode pin after Claim 1 , characterized in that the anode (3) for contacting the inside (100a) of the component (10) has at least one first contact surface (300a), the at least one first contact surface (300a) for contacting the inside (100a) of the component ( 10) can be moved from a first position into a second position with respect to the cathode (4). Electrode pin after Claim 2 , characterized in that the at least one contact surface (300a) in the second position in a radial direction (R) of the electrode pin (1) projects further beyond an outside (4a) of the cathode (4) than in the first position. Electrode pin according to one of the Claims 1 to 3rd characterized in that the electrode pin (1) has an elongate support (2) which extends along a longitudinal axis (x ') of the electrode pin (1), the anode (3) and the cathode (4) on the support ( 2) are arranged so that the carrier (2) can be displaced with respect to the anode (3) and the cathode (4) along the longitudinal axis (x '). Electrode pin after Claim 4 , characterized in that the carrier (2) has at least one expansion element (20), the at least one expansion element (20) being configured to move the carrier (2) with respect to the anode (3) along the longitudinal axis (x ') of the electrode pin (1) against the anode (3) in such a way that the at least one first contact surface (300a) of the anode (3) is moved from the first position to the second position. Electrode pin according to one of the Claims 4 to 5 , characterized in that the cathode (4) surrounds the carrier (2) and the anode (3) at least in sections. Electrode pin according to one of the preceding claims, characterized in that electrical insulation (5) is arranged between the cathode (4) and the anode (3). Electrode pin according to one of the Claims 5 to 7 , characterized in that the at least one expansion element (20) is formed at a first end of the carrier (2). Electrode pin after Claim 2 and after one of the Claims 5 to 8th , characterized in that the at least one spreading element (20) is designed to move against the plurality of first sections (300) of the anode when the carrier (2) is displaced with respect to the anode (3) along the longitudinal axis (x ') of the electrode pin (1) (3) to be pressed, the at least one first contact area (300a) being formed by one of the first sections (300), the further first sections (300) forming further first contact areas (300a) of the anode (3), each of which consists of a first position can be moved into a second position, the respective first contact surface (300a) being moved from its first position into its second position when the at least one expansion element (20) of the carrier (2) against the respective first section (300) presses. Electrode pin after Claim 9 , characterized in that the first sections (300) of the anode (3) are formed by a tubular end section (30) of the anode (3) which extends along the longitudinal axis (x ') of the electrode pin (1), the first Sections (300) are separated from one another by slots (31) in the end section (30), and the respective slot (31) extends along the longitudinal axis (x ') of the tubular end section (30) of the anode (3). Electrode pin according to one of the Claims 5 to 10th , characterized in that the carrier (2) has a further expansion element (21), the further expansion element (21) being designed to move the carrier (2) with respect to the anode (3) along the longitudinal axis (x ') of the Press electrode pin (1) against a plurality of second sections (301) of the anode (3), each second section (301) forming a second contact surface (301a) of the anode (3) for contacting the inside (100a) of the component (10) , wherein the respective second contact surface (301a) is moved from a first position into a second position when the further expansion element (21) of the carrier (2) presses against the respective second section (301) of the anode (3). Electrode pin after Claim 11 , characterized in that the cathode (4) has a first Section (40) and an adjacent second section (41), which are separated from one another by a gap (8), the second contact surfaces (301a) of the anode (3) being configured such that they are in the respective second position in a radial direction (R) of the electrode pin (1) protrude from the gap (8) over the two sections (40, 41) of the cathode (4) in order to contact the inside (100a) of the component (10) when the electrode pin ( 1) is arranged in the interior (101) of the component (10). Electrode pin after Claim 12 , characterized in that the first section (40) of the cathode (4) is electrically conductively connected to a core (42) of the cathode (4) which is inside the carrier (2) along the longitudinal axis (x ') of the electrode pin (1 ), and in particular the second section (41) of the electrode (4) is connected to the core (42) via a conductor (43), the conductor (43) running in particular outside the carrier (2). Electrode pin according to one of the Claims 4 to 13 , characterized in that the electrode pin has a spring element (6) which is configured to apply a force to the carrier (2) in such a way that the respective contact surface (300a, 301a) is biased towards the respective second position. Method for electropolishing a component (10) using an electrode pin (1) according to one of the preceding claims, wherein the component (10) has a support structure (100) which extends along a longitudinal axis (x) and in a circumferential direction (U) of the component (10) rotates so that the support structure (100) surrounds an interior (101) of the component (10), the support structure (100) having an inside (100a) facing the interior (101), and wherein the method Steps: Inserting the electrode pin (1) into the interior (101) of the component (10) so that the anode (3) and the cathode (4) are arranged in the interior (101) of the component (10), Establishing a contact between the inside (100a) of the component (10) and the anode (3), - Placing the component (10) in an electrolyte and applying an electrical voltage between the anode (3) and the cathode (4) for electropolishing the component (10).

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