The present disclosure provides a nanowire bundle including a plurality of cores including metal and arranged in a predetermined shape at regular intervals; a first glass portion including glass and covering the plurality of cores; and a second glass portion including glass and covering the first glass portion, and a method for manufacturing the nanowire bundle.

The present disclosure is a conductive paste for a solar cell electrode comprising a metal powder, a glass frit, and an organic vehicle, wherein the discharge amount factor A of the bus-bar electrode can be calculated by Equation 1 below, and the discharge amount factor B of the finger electrode can be calculated by the following Equation 2, and |AB| relates to a conductive paste for a solar cell electrode, characterized in that it is 0.100 or less.

[00001]$\text{A}\text{=}\left(\text{Slip velocity}\times \text{10}\right)/\left(\text{G ′}\times 0.01\right)$

[00002]$\text{B = 1/}\left(\text{G″}\times \text{0}\text{.01}\right)$

The present disclosure is a conductive paste for a solar cell electrode comprising a metal powder, a glass frit, and an organic vehicle, wherein the discharge amount factor A of the bus-bar electrode can be calculated by Equation 1 below, and the discharge amount factor B of the finger electrode can be calculated by the following Equation 2, and |AB| relates to a conductive paste for a solar cell electrode, characterized in that it is 0.100 or less.

[00001]$\text{A}\text{=}\left(\text{Slip velocity}\times \text{10}\right)/\left(\text{G ′}\times 0.01\right)$

[00002]$\text{B = 1/}\left(\text{G″}\times \text{0}\text{.01}\right)$

A coaxial cable comprises inner and outer conductors disposed along an elongate axis, a dielectric insulating material disposed between the inner and outer conductors, a compliant outer jacket disposed over the inner and outer conductors, and a reinforcing outer jacket disposed over the compliant inner jacket, the outer jacket being physically separate from the inner jacket and comprising on-axis and off-axis fibers disposed in a binding matrix, the outer jacket comprising more on-axis than off-axis fibers.

A lead-through or connecting element is provided that includes an assembly having a carrier body of a high-temperature alloy, a functional element, and an at least partially crystallized glass. The crystallized glass is between a portion of the functional element and a portion of the carrier body. The carrier body subjects the crystallized glass to a compressive stress of greater than or equal to zero, at a temperature from at least 20° C. to more than 450° C. Also provided are a method for producing a lead-through or connecting element, the use of such a lead-through or connecting element, and to a measuring device including such a lead-through or connecting element.

High thermal conductivity dielectric materials systems or pastes are useful on aluminum alloy substrates for LED and high power circuitry applications.

A conductive device includes a housing, a glass insulator, and a conductor. The housing comprises an opening. The glass insulator is located within the opening, wherein a seal is formed between the housing and the glass insulator. The conductor is located at least partially within the glass insulator and comprises at least one of conductive ceramic, cemented carbide, and cermet. A seal is formed between the glass insulator and the conductor.

A conductive device includes a housing, a glass insulator, and a conductor. The housing comprises an opening. The glass insulator is located within the opening, wherein a seal is formed between the housing and the glass insulator. The conductor is located at least partially within the glass insulator and comprises at least one of conductive ceramic, cemented carbide, and cermet. A seal is formed between the glass insulator and the conductor.

A cable assembly for a flame sensor apparatus includes an inner conductor electrically connected to a photodiode that generates a current. The inner conductor transmits the current from the photodiode. A first insulating layer circumferentially surrounds the inner conductor. The first insulating layer includes a mineral insulation material. An inner sheath circumferentially surrounds the first insulating layer. The inner sheath includes an electrically conductive material. A second insulating layer circumferentially surrounds the inner sheath. The second insulating layer includes a mineral insulation material. An outer sheath circumferentially surrounds the second insulating layer. The outer sheath includes an electrically conductive material. The cable assembly is for use in temperatures up to about 300 degrees Celsius or greater. A method of attaching a cable assembly for a flame sensor apparatus.

A cable assembly for a flame sensor apparatus includes an inner conductor electrically connected to a photodiode that generates a current. The inner conductor transmits the current from the photodiode. A first insulating layer circumferentially surrounds the inner conductor. The first insulating layer includes a mineral insulation material. An inner sheath circumferentially surrounds the first insulating layer. The inner sheath includes an electrically conductive material. A second insulating layer circumferentially surrounds the inner sheath. The second insulating layer includes a mineral insulation material. An outer sheath circumferentially surrounds the second insulating layer. The outer sheath includes an electrically conductive material. The cable assembly is for use in temperatures up to about 300 degrees Celsius or greater. A method of attaching a cable assembly for a flame sensor apparatus.