A glass tube is manufactured by a method in which a smaller tube is within a larger tube. A space which is formed between the smaller and larger tube is filled with colored, patterned, or clear glass rods or bars to form an assembly. On one end of the assembly, the inner tube is sealed to the outer tube, on an opposite end of the assembly, the inner tube being closed. The assembly is attached to a linear slide mechanism. The linear slide mechanism is used to pass the assembly through a high-temperature furnace having a temperature above the glass transition temperature of the glasses used to build the assembly. A vacuum is applied to the assembly, causing the glasses to collapse towards each other once they reach a plastic state, and causing the outer tube and inner tube to seal against the colored, patterned, or clear glass rods or bars that were held captive.

A perforated quartz glass tube includes a jacket tube containing a quartz glass material, a plurality of cylindrical glass tubes which are inserted into a pore region of the jacket tube along an axial direction of the jacket tube, and contain a quartz glass material having a softening point higher than a softening point of the jacket tube, and a gap member which is inserted into a gap between the cylindrical glass tubes and a gap between the jacket tube and the cylindrical glass tube, and contains a quartz glass material having a softening point lower than a softening point of the cylindrical glass tube.

A perforated quartz glass tube includes a jacket tube containing a quartz glass material, a plurality of cylindrical glass tubes which are inserted into a pore region of the jacket tube along an axial direction of the jacket tube, and contain a quartz glass material having a softening point higher than a softening point of the jacket tube, and a gap member which is inserted into a gap between the cylindrical glass tubes and a gap between the jacket tube and the cylindrical glass tube, and contains a quartz glass material having a softening point lower than a softening point of the cylindrical glass tube.

The present disclosure discloses a glass assembly, for forming an electrochemical sensor, comprising a glass immersion tube, a glass membrane connected to a distal end of the immersion tube, wherein the glass which forms the immersion tube contains no lead, no lead compound, no lithium, and no lithium compound.

The present disclosure discloses a glass assembly, for forming an electrochemical sensor, comprising a glass immersion tube, a glass membrane connected to a distal end of the immersion tube, wherein the glass which forms the immersion tube contains no lead, no lead compound, no lithium, and no lithium compound.

A light device comprising a light emitting diode (LED) enclosed in a glass tube is described. The first closed end of the glass tube has a tapered cross section with a conical shape and a ball at the tip. The second closed end of the glass tube has a melted region encasing a pair of lead wires that pass into the lumen of the glass tube and connect to the LED.

A lead insertion system adapted to insert a lead into a glass tube includes a first robot on which a first gripper is mounted and a second robot on which a second gripper is mounted. The first gripper grips the glass tube and the second gripper grips the lead. The lead insertion system includes a flame heater heating the glass tube gripped by the first robot and the lead gripped by the second robot with a flame. The second robot inserts the lead into the glass tube held by the first robot with the lead heated by the flame and the glass tube heated and softened by the flame.

A lead insertion system adapted to insert a lead into a glass tube includes a first robot on which a first gripper is mounted and a second robot on which a second gripper is mounted. The first gripper grips the glass tube and the second gripper grips the lead. The lead insertion system includes a flame heater heating the glass tube gripped by the first robot and the lead gripped by the second robot with a flame. The second robot inserts the lead into the glass tube held by the first robot with the lead heated by the flame and the glass tube heated and softened by the flame.

A half-cell for measuring a pH value of a measuring medium is disclosed including a tube-shaped carrier element and a pH-sensitive glass membrane connected to an end section of the carrier element. At least the end section of the carrier element includes a zirconia-containing and/or alumina-containing ceramic. A method for manufacturing a half-cell for pH value measurement and a potentiometric sensor are further disclosed.

A container and a method of manufacturing a container having a base portion and a sidewall which together form a partially enclosed space for holding a fluid; and a cooling element fixedly connected to the base portion, the cooling element comprising a cavity and a cooling material sealed within the cavity.