JP2020203810A - Glass transfer device - Google Patents

Abstract

To perform suitable cooling, while using gas as a coolant.SOLUTION: A glass transfer device includes a glass transfer pipe 18 for transferring molten glass GM, and cooling passages 22a, 22b for passing a coolant comprising gas. The glass transfer pipe 18 includes a tubular body part 19, a flange part 20 and an electrode part 21. The cooling passages 22a, 22b are formed inside the flange part 20 and/or inside the electrode part 21.SELECTED DRAWING: Figure 7

Description

The present invention relates to a glass transfer device for transferring molten glass.

As is well known, flat glass is used as a glass substrate or cover glass in flat panel displays such as liquid crystal displays and organic EL displays.

For example, Patent Document 1 discloses an apparatus for manufacturing flat glass. This manufacturing device includes a melting tank (melting container) that is a supply source of molten glass, a clarification tank (clarification container) provided on the downstream side of the melting tank, and a stirring tank (mixing) provided on the downstream side of the clarification tank. A container), a pot (feeding container) provided on the downstream side of the stirring tank, a molded body (molding body) provided on the downstream side of the pot, and a connecting conduit for connecting these components to each other. Be prepared. The clarification tank, stirring tank, pot and coupling conduit are made of a noble metal such as platinum, and have a function as a glass transfer device that transfers the molten glass to the downstream side while controlling the temperature.

The glass transfer device includes a tubular main body for transferring molten glass, a flange and an electrode as a heating device for controlling the temperature of the molten glass, and a cooling conduit for cooling the flange and the electrode. And. The flange portion and the electrode portion are integrally formed with the main body portion, and the cooling conduit is arranged along the periphery (outer edge) of the flange portion and the electrode portion. The cooling conduit cools the flange portion and the electrode portion when the molten glass is transferred by circulating a refrigerant such as water. In this case, the thickness of the flange portion and the electrode portion is, for example, about 10 mm.

Special Table 2018-513092

In a conventional glass transfer device, when the flange portion and the electrode portion are water-cooled by a cooling conduit, the flange portion and the electrode portion are excessively cooled, the power consumption related to the temperature control of the molten glass increases, and the energy efficiency decreases. May lead to. It is conceivable to use gas as a refrigerant instead of liquid such as water, but since gas has a lower thermal conductivity than liquid, cooling may be insufficient and the flange portion and the like may be oxidized. Therefore, even if the refrigerant is a gas, a cooling structure capable of suitably preventing oxidation of the flange portion or the like due to heating is required.

The present invention has been made in view of the above circumstances, and it is a technical subject to perform suitable cooling while using a gas as a refrigerant.

The present invention is for solving the above-mentioned problems, and is a glass transfer device provided with a glass transfer tube for transferring molten glass and a cooling flow path for passing a refrigerant composed of gas, and the glass transfer tube is A tubular main body portion, a flange portion, and an electrode portion are provided, and the cooling flow path is formed inside the flange portion and / or inside the electrode portion.

According to such a configuration, by passing the refrigerant through the cooling flow path formed inside the flange portion and / or the inside of the electrode portion, the cooling flow path (cooling conduit) is provided around the flange portion and the electrode portion as in the conventional case. ) Can be evenly cooled as compared with the case where the flange portion and / or the electrode portion is arranged. Further, by forming the cooling flow path inside the flange portion and / or inside the electrode portion, the thickness dimension of the flange portion and / or the electrode portion can be increased. As a result, by reducing the electrical resistance of the flange portion and / or the electrode portion and increasing the rigidity, it is possible to perform energy-efficient heating while reducing heat generation and prevent deformation of the flange portion and / or the electrode portion. Therefore, even when the gas is used as the refrigerant, the flange portion and / or the electrode portion can be suitably cooled. Further, by passing the refrigerant through the cooling flow path formed inside the flange portion and / or inside the electrode portion, the transfer device can be miniaturized as a whole, and the space required for installing the transfer device can be reduced.

The cooling flow path may be formed inside the flange portion and inside the electrode portion. As a result, both the flange portion and the electrode portion can be efficiently cooled.

The cooling flow path includes a plurality of flange cooling portions for cooling the flange portion, and the plurality of flange cooling portions extend along the circumferential direction of the flange portion and are spaced apart in the radial direction of the flange portion. It may be formed. By forming the plurality of flange cooling portions inside the flange portions in this way, it is possible to uniformly cool the entire range of the flange portions.

The electrode portion has a predetermined width, the cooling flow path includes a plurality of electrode cooling portions for cooling the electrode portion, and the plurality of electrode cooling portions are spaced apart in the width direction of the electrode portion. It may be formed after. By forming the plurality of electrode cooling portions inside the electrode portions in this way, it is possible to uniformly cool the electrode portions over the entire range.

The glass transfer tube may be a stirring tank for stirring the molten glass. It is difficult to secure the space required for installation of the glass transfer pipe of the stirring tank extending in the vertical direction in the lower flange portion and the electrode portion. Therefore, when applied to the glass transfer pipe of the stirring tank, the effect of reducing the space required for installing the above-mentioned transfer device becomes remarkable.

The flange portion and the electrode portion may be made of nickel or a nickel alloy having excellent heat resistance. Since nickel or nickel alloy is easily oxidized, the effect of suitably cooling the flange portion and / or the electrode portion described above becomes remarkable.

According to the present invention, suitable cooling can be performed while using a gas as a refrigerant.

It is a side view which shows the whole structure of a glass manufacturing apparatus. It is a perspective view of a stirring tank. It is sectional drawing which shows the main part of a stirring tank. It is sectional drawing which shows the method of manufacturing the flange part of a stirring tank. It is sectional drawing which shows the method of manufacturing the flange part of a stirring tank. It is a perspective view which shows the end part of the glass transfer tube which concerns on a glass supply path. It is sectional drawing which shows the main part of the glass transfer tube. It is sectional drawing which shows the method of manufacturing the flange part of a glass transfer tube. It is sectional drawing which shows the method of manufacturing the flange part of a glass transfer tube.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

FIG. 1 shows a glass article manufacturing apparatus. In this manufacturing apparatus, in order from the upstream side, the melting tank 1, the clarification tank 2, the stirring tank (stirring pot) 3, the pot 4, the molded body 5, and the glass connecting each of these components 1 to 5 are connected. It is provided with supply paths 6a to 6d. In addition, the manufacturing apparatus includes a slow cooling furnace (not shown) for slowly cooling the plate glass GR (glass article) formed by the molded body 5 and a cutting device (not shown) for cutting the plate glass GR after slow cooling.

The melting tank 1 is a container for performing a melting step of melting the charged glass raw material to obtain molten glass GM. The melting tank 1 is connected to the clarification tank 2 by a glass supply path 6a.

The clarification tank 2 is a container for performing a clarification step of defoaming by the action of a clarifying agent or the like while transferring the molten glass GM. The clarification tank 2 is connected to the stirring tank 3 by a glass supply path 6b.

The stirring tank 3 is a tubular container with a bottom for performing a step of stirring and homogenizing the clarified molten glass GM (homogenization step). The stirring tank 3 includes a starla 3a having stirring blades. The stirring tank 3 is connected to the pot 4 by a glass supply path 6c. The stirring tank 3 functions as a glass transfer device (glass transfer tube) that transfers the molten glass GM while stirring.

As shown in FIGS. 2 and 3, the stirring tank 3 includes a main body portion 7, a flange portion 8 provided on the outer peripheral portion (outer peripheral surface) of the main body portion 7, and an electrode portion that functions as a heating device together with the flange portion 8. 9. And cooling flow paths 10a and 10b for cooling the flange portion 8 and the electrode portion 9 are provided.

The main body 7 is formed of platinum or a platinum alloy into a tubular shape (for example, a circular tubular shape). The main body 7 is arranged along the vertical direction, and glass supply paths 6b and 6c are connected to the middle portion thereof. The glass supply path 6b that connects the clarification tank 2 and the main body 7 is located above the glass supply path 6c that connects the pot 4 and the main body 7. With this structure, the main body 7 transfers the molten glass GM supplied from the glass supply path 6b on the upstream side downward and supplies it to the glass supply path 6c on the downstream side.

The flange portion 8 is formed in a disk shape and is formed so as to surround the entire circumference of the main body portion 7. The flange portion 8 is integrally configured (welded) with the main body portion 7 so as to be concentric with the main body portion 7. In the present embodiment, the flange portion 8 is provided at the end portion in the longitudinal direction of the main body portion 7, but may be provided in the middle portion of the main body portion 7.

The flange portion 8 includes a first flange portion 8a and a second flange portion 8b integrally fixed to the outer periphery of the first flange portion 8a.

The first flange portion 8a is made of platinum or a platinum alloy. The first flange portion 8a is integrally formed with each end portion of the main body portion 7. The second flange portion 8b is formed of nickel or a nickel alloy in an annular shape (for example, an annular shape). The second flange portion 8b is integrally formed with the first flange portion 8a by joining the inner peripheral portion thereof and the outer peripheral portion of the first flange portion 8a by welding.

The electrode portion 9 is formed of nickel or a nickel alloy in a plate shape. The electrode portion 9 has a predetermined width, and is a long portion that protrudes outward in the radial direction from the outer peripheral portion of the second flange portion 8b. A power supply (not shown) is connected to the electrode portion 9.

As shown in FIG. 3, the cooling flow paths 10a and 10b include a first cooling flow path 10a and a second cooling flow path 10b. The number of cooling flow paths 10a and 10b is not limited to this embodiment, and can be appropriately set according to the dimensions of the flange portion 8 and the electrode portion 9. Each of the cooling flow paths 10a and 10b is configured by arranging a cooling pipe 11 for transferring a refrigerant R made of a gas such as air inside the flange portion 8 and the electrode portion 9. The cooling pipe 11 is made of nickel or a nickel alloy.

Each of the cooling flow paths 10a and 10b has a flange cooling portion 12 for cooling the flange portion 8 and an electrode cooling portion 13 for cooling the electrode portion 9. The flange cooling portion 12 is formed inside the second flange portion 8b, and the electrode cooling portion 13 is formed inside the electrode portion 9. The flange cooling portion 12 is an arcuate flow path that extends along the circumferential direction of the flange portion 8 and is arranged side by side at intervals in the radial direction of the flange portion 8. The electrode cooling unit 13 is a plurality of linear flow paths along the longitudinal direction of the electrode portion 9, and is arranged at a predetermined interval in the width direction (direction orthogonal to the longitudinal direction) of the electrode portion 9.

As shown in FIGS. 4 and 5, the second flange portion 8b is formed by joining the annular and plate-shaped first constituent member 14 and the second constituent member 15 by welding. Grooves 16 and 17 having an arcuate cross-sectional view are formed on one surface of the first component 14 and one surface of the second component 15. In order to form the cooling flow paths 10a and 10b inside the second flange portion 8b, as shown in FIG. 5, for cooling between the groove portion 16 of the first constituent member 14 and the groove portion 17 of the second constituent member 15. The first constituent member 14 and the second constituent member 15 are overlapped with each other so that the pipe 11 is interposed. After that, the first constituent member 14 and the second constituent member 15 are integrated by welding the portions that come into contact with each other. As a result, the second flange portion 8b in which the cooling passages 10a and 10b formed by the cooling pipe 11 is formed is formed.

The pot 4 is a container for performing a state adjusting step of adjusting the molten glass GM to a state suitable for molding. The pot 4 is exemplified as a volume portion for adjusting the viscosity and the flow rate of the molten glass GM. The pot 4 is connected to the molded body 5 by a glass supply path 6d.

The molded body 5 molds the molten glass GM into a plate shape by the overflow down draw method. Specifically, the molded body 5 has a substantially wedge-shaped cross-sectional shape (cross-sectional shape orthogonal to the paper surface of FIG. 1), and an overflow groove (not shown) is formed on the upper portion of the molded body 5. Has been done.

The molded body 5 causes the molten glass GM to overflow from the overflow groove and flows down along the side wall surfaces (side surfaces located on the front and back sides of the paper surface) on both sides of the molded body 5. In the molded body 5, the molten glass GM that has flowed down is fused at the lower top of the side wall surface. As a result, the strip-shaped flat glass GR is formed. The strip-shaped plate glass GR is cut by a cutting device after passing through a slow cooling furnace to obtain a plate glass having a desired size.

The plate glass thus obtained has a thickness of, for example, 0.01 to 10 mm, and is used for flat panel displays such as liquid crystal displays and organic EL displays, substrates for organic EL lighting, solar cells, and protective covers. To. The molded body 5 may execute another down-draw method such as the slot down-draw method, and a molding device using the float method may be provided instead of the molded body 5. The glass article manufactured by the manufacturing apparatus is not limited to the flat glass GR, and includes a glass tube and other objects having various shapes. For example, when forming a glass tube, a molding apparatus using the Dunner method is deployed instead of the molded body 5.

As the composition of the flat glass, silicate glass and silica glass are used, preferably borosilicate glass, sodalime glass, aluminosilicate glass, and chemically strengthened glass are used, and most preferably non-alkali glass is used. Here, the non-alkali glass is a glass that does not substantially contain an alkaline component (alkali metal oxide), and specifically, a glass having a weight ratio of an alkaline component of 3000 ppm or less. is there. The weight ratio of the alkaline component is preferably 1000 ppm or less, more preferably 500 ppm or less, and most preferably 300 ppm or less.

The glass supply paths 6a to 6d function as a glass transfer device for transferring the molten glass GM. The glass supply paths 6a to 6d include a glass transfer tube 18 including a heating device and a cooling device (see FIG. 6). The glass supply paths 6a to 6d are configured by one glass transfer tube 18 or by connecting a plurality of glass transfer tubes 18. The entire glass transfer pipe 18 is covered with a heat insulating material such as brick (not shown).

As shown in FIGS. 6 and 7, the glass transfer tube 18 includes a main body portion 19, a flange portion 20 provided on the outer peripheral portion (outer peripheral surface) of the main body portion 19, and an electrode that functions as a heating device together with the flange portion 20. A portion 21, and cooling flow paths 22a and 22b for cooling the flange portion 20 and the electrode portion 21 are provided.

The main body 19 is formed of platinum or a platinum alloy into a tubular shape (for example, a circular tubular shape). The main body 19 transfers the molten glass GM from one end side (upstream side) to the other end side (downstream side) by passing the molten glass GM inside.

The flange portion 20 is formed in a disk shape and is formed so as to surround the entire circumference of the main body portion 19. The flange portion 20 is integrally configured (welded) with the main body portion 19 so as to be concentric with the main body portion 19. In the present embodiment, the flange portion 20 is provided at the end portion in the longitudinal direction of the main body portion 19, but may be provided in the middle portion of the main body portion 19.

The flange portion 20 includes a first flange portion 20a and a second flange portion 20b integrally fixed to the outer periphery of the first flange portion 20a.

The first flange portion 20a is made of platinum or a platinum alloy. The first flange portion 20a is integrally formed with each end portion of the main body portion 19. The second flange portion 20b is formed of nickel or a nickel alloy in an annular shape (for example, an annular shape). The second flange portion 20b is integrally formed with the first flange portion 20a by joining the inner peripheral portion thereof and the outer peripheral portion of the first flange portion 20a by welding.

The electrode portion 21 is formed of nickel or a nickel alloy in a plate shape. The electrode portion 21 has a predetermined width, and is a long portion that protrudes outward (upward) in the radial direction from the upper portion of the flange portion 20 (second flange portion 20b). A power supply (not shown) is connected to the electrode portion 21. The electrode portion 21 may be provided at the lower portion or the side portion of the flange portion 20 (second flange portion 20b).

As shown in FIG. 7, the cooling flow paths 22a and 22b include a first cooling flow path 22a and a second cooling flow path 22b. The number of cooling flow paths 22a and 22b is not limited to this embodiment, and can be appropriately set according to the dimensions of the flange portion 20 and the electrode portion 21.

The first cooling flow path 22a and the second cooling flow path 22b have a flange cooling unit 23 for cooling the flange portion 20 and an electrode cooling portion 24 for cooling the electrode portion 21. The flange cooling portion 23 is formed inside the second flange portion 20b, and the electrode cooling portion 24 is formed inside the electrode portion 21. The flange cooling portion 23 is an arcuate flow path that extends along the circumferential direction of the flange portion 20 and is arranged side by side at intervals in the radial direction of the flange portion 20. The electrode cooling unit 13 is a plurality of linear flow paths along the longitudinal direction of the electrode portion 21, and is arranged at a predetermined interval in the width direction (direction orthogonal to the longitudinal direction) of the electrode portion 21.

Each cooling flow path 22a, 22b includes an inflow port 25 and an outflow port 26 of the refrigerant R. A cooling pipe 27 for transferring the refrigerant R is connected to the inflow port 25 and the outflow port 26. The inflow port 25 and the outflow port 26 of the cooling flow paths 22a and 22b are provided at the ends of the electrode portions 21. In the present embodiment, the cooling pipe 27 is connected to the outlet 26, but the refrigerant R may be discharged from the outlet 26 without connecting the cooling pipe 27 to the outlet 26. Further, the flange cooling portion 23 may be divided in the circumferential direction of the flange portion 20 (for example, divided into two to four), and the refrigerant R may flow through each of the divided flange cooling portions 23. In this case, the inflow port 25 and the outflow port 26 of each flange cooling portion 23 are formed on the peripheral edge portion of the flange portion 20. Further, in the present embodiment, the flow direction of the refrigerant R in the cooling flow path 22a and the flow direction of the refrigerant R in the cooling flow path 22b face each other, but the flow direction of the refrigerant R in the cooling flow path 22a and the cooling flow path The flow direction of the refrigerant R in 22b may be parallel to that of the refrigerant R. These configurations can also be applied to the flange portion 8 of the stirring tank 3 described above.

As shown in FIGS. 8 and 9, the second flange portion 20b is formed by joining the annular and plate-shaped first constituent member 28 and the second constituent member 29 by welding. Grooves 30 and 31 having a rectangular cross section forming the cooling flow paths 22a and 22b are formed on one surface of the first component 28 and one surface of the second component 29. As shown in FIG. 9, when one surface of the first constituent member 28 and the second constituent member 29 is brought into contact with each other, the groove portion 30 of the first constituent member 28 and the groove portion 31 of the second constituent member 29 coincide with each other. In this state, the first constituent member 28 and the second constituent member 29 are integrated by welding the portions that come into contact with each other. As a result, the groove 30 of the first constituent member 28 and the groove 31 of the second constituent member 29 are integrally formed to form cooling passages 22a and 22b having a square cross-sectional view (for example, a square). Not limited to this example, the cooling passages 22a and 22b are formed by interposing the cooling pipe 27 between the grooves 30 and 31 in the same manner as the cooling passages 10a and 10b of the second flange portion 8b of the stirring tank 3. It may be configured.

Hereinafter, a method of manufacturing a flat glass using the manufacturing apparatus having the above configuration will be described. In this method, the raw glass is melted in the melting tank 1 (melting step) to obtain the molten glass GM, and then the molten glass GM is sequentially subjected to a clarification step by the clarification tank 2 and a homogenization step by the stirring tank 3. And the state adjustment step by the pot 4 is carried out. After that, the molten glass GM is transferred to the molded body 5, and the flat glass GR is molded from the molten glass GM by a molding step. After that, the flat glass GR is formed into a predetermined size through a slow cooling step by a slow cooling furnace and a cutting step by a cutting device.

In the homogenization step, the stirring tank 3 rotates the starla 3a while transferring the molten glass GM by the main body 7. In this case, the stirring tank 3 applies a voltage to the electrode portion 9 to heat the main body portion 7 in order to control the temperature of the molten glass GM. At the same time, the refrigerant R is supplied to the cooling channels 10a and 10b. The refrigerant R passes through the cooling pipe 11 and cools the flange portion 8 and the electrode portion 9. In the present embodiment, the refrigerant R flows in the order of the electrode cooling unit 13 and the flange cooling unit 12 of the cooling flow paths 10a and 10b. Not limited to this, the flange cooling unit 12 and the electrode cooling unit 13 may be made independent without being connected to each other. From the viewpoint of preventing the structure from becoming complicated and accurately cooling the flange portion 8 and the electrode portion 9, the refrigerant R is the electrode cooling portion 13 and the flange cooling of the cooling flow paths 10a and 10b as in the present embodiment. It is preferable to flow in the order of the parts 12.

When the molten glass GM is transferred through the glass supply paths 6a to 6d, a voltage is applied to the electrode portion 21 to control the temperature of the molten glass GM flowing in the main body 19 of the glass transfer tube 18, and the main body 19 is transferred. Heat. In this case, the refrigerant R is supplied to the cooling channels 22a and 22b. The cooling flow paths 22a and 22b circulate the refrigerant R supplied from the cooling pipe 27 from the inflow port 25 to the outflow port 26 to cool the flange portion 20 and the electrode portion 21.

According to the glass transfer device (stirring tank 3, glass supply paths 6a to 6d) according to the present embodiment described above, the cooling flow paths 10a and 10b formed inside the flange portions 8 and 20 and the electrode portions 9 and 21. By passing the refrigerant R through the, 22a, and 22b, the flange portions 8, 20 and the electrode portions 9 are compared with the case where the cooling conduit is arranged around the flange portion and the electrode portion as in the conventional glass transfer device. , 21 can be cooled evenly from the inside. Therefore, even when a gas is used as the refrigerant R, suitable cooling can be realized without causing a decrease in energy efficiency due to excessive cooling of the flange portions 8 and 20 and the electrode portions 9 and 21.

The present invention is not limited to the configuration of the above embodiment, and is not limited to the above-mentioned action and effect. The present invention can be modified in various ways without departing from the gist of the present invention.

In the above embodiment, an example in which the present invention is applied to the stirring tank 3 and the glass transfer pipe 18 included in the glass supply passages 6a to 6d is shown, but the present invention is not limited to this configuration. The configurations of the cooling channels 10a and 10b of the stirring tank 3 of the above embodiment may be applied to the clarification tank 2, the pot 4, and the glass transfer pipes constituting the glass supply passages 6a to 6d. Further, even if the configurations of the cooling passages 22a and 22b of the glass transfer pipes 18 according to the glass supply passages 6a to 6d of the above embodiment are applied to the glass transfer pipes constituting the clarification tank 2, the stirring tank 3 and the pot 4. Good.

The glass supply paths 6a to 6d and the clarification tank 2 can be configured to have a desired length by connecting a plurality of glass transfer pipes 18. In this case, the flange portions 20 of the adjacent glass transfer tubes 18 can face each other, and the glass transfer tubes 18 can be connected with a heat insulating member or the like interposed between the flange portions 20. Since the cooling flow paths 22a and 22b are formed inside the flange portion 20, the thickness dimension thereof becomes larger than that of the conventional flange portion 20, so that the rigidity of the flange portion 20 is increased. Therefore, when connecting the plurality of glass transfer tubes 18, the connection work can be easily performed while preventing the flange portion 20 from being deformed. The thickness of the flange portion 20 is preferably, for example, 20 to 50 mm, more preferably 30 to 50 mm.

In the above embodiment, the cooling passages 10a and 10b of the stirring tank 3 and the cooling passages 22a and 22b of the glass transfer pipe 18 related to the glass supply passages 6a to 6d are the flange portions 8 and 20 and the electrode portions 9 and 21. Although it was configured to cool both, the present invention is not limited to this configuration. Each cooling flow path 10a, 10b, 22a, 22b may cool only the flange portions 8 and 20, or may cool only the electrode portions 9 and 21.

3 Stirring tank 7 Main body 8 Flange part 9 Electrode part 10a First cooling flow path 10b Second cooling flow path 18 Glass transfer pipe 19 Main body part 20 Flange part 21 Electrode part 22a First cooling flow path 22b Second cooling flow path R Refrigerant GM molten glass

Claims (6)

A glass transfer device including a glass transfer tube for transferring molten glass and a cooling flow path for passing a refrigerant composed of gas.
The glass transfer tube includes a tubular main body portion, a flange portion, and an electrode portion.
A glass transfer device characterized in that the cooling flow path is formed inside the flange portion and / or inside the electrode portion. The glass transfer device according to claim 1, wherein the cooling flow path is formed inside the flange portion and inside the electrode portion. The cooling flow path includes a plurality of flange cooling portions for cooling the flange portions.
The glass transfer device according to claim 2, wherein the plurality of flange cooling portions extend along the circumferential direction of the flange portions and are formed at intervals in the radial direction of the flange portions. The electrode portion has a predetermined width and has a predetermined width.
The cooling flow path includes a plurality of electrode cooling portions for cooling the electrode portions.
The glass transfer device according to claim 2 or 3, wherein the plurality of electrode cooling portions are formed at intervals in the width direction of the electrode portions. The glass transfer device according to any one of claims 1 to 4, wherein the glass transfer tube is a stirring tank for stirring the molten glass. The glass transfer device according to any one of claims 1 to 4, wherein the flange portion and the electrode portion are made of nickel or a nickel alloy.

Images