A sensor arrangement for capacitive detection of an object, including: an electrode arrangement having a heating element as an electrode; a detection device providing a detection signal to a sensor electrode and capacitively detecting the presence of an object near the sensor electrode; a high-side switch connected between a heating power source having a first potential and the heating element; a low-side switch connected between the heating element and a second potential; and a gate controller closing the high-side switch and low-side switch in a heating mode and opening the high-side switch and low-side switch in a detection mode. A decoupling MOSFET is connected between the high-side switch and heating element. The gate controller closes the MOSFET in the heating mode and opens the MOSFET in the detection mode. During the detection mode, the decoupling circuit provides a third potential at a first node between the high-side switch and MOSFET.

A sensor arrangement for capacitive detection of an object, including: an electrode arrangement having a heating element as an electrode; a detection device providing a detection signal to a sensor electrode and capacitively detecting the presence of an object near the sensor electrode; a high-side switch connected between a heating power source having a first potential and the heating element; a low-side switch connected between the heating element and a second potential; and a gate controller closing the high-side switch and low-side switch in a heating mode and opening the high-side switch and low-side switch in a detection mode. A decoupling MOSFET is connected between the high-side switch and heating element. The gate controller closes the MOSFET in the heating mode and opens the MOSFET in the detection mode. During the detection mode, the decoupling circuit provides a third potential at a first node between the high-side switch and MOSFET.

A resistive heating element for use in or manufacturing of a component of an aircraft or spacecraft. The resistive heating element includes a sheet made from carbon nanotubes (CNTs) having a length of at least about 5 μ.Math.η, and formed as a nonwoven or composite polymer sheet, having good uniformity. The sheet is made with a basis weight between 1 and 50 grams per square meter (gsm), to provide a resistance value, inversely related to the basis weight, of at least about 0.01 ohms per square (Ω/□), and up to about 100 Ω/□. The CNTs can have an aspect ratio of at least about 1000:1, and at least about 10,000:1 or 100,000:1. The resistance value of the sheet can be controlled by the basis weight of CNTs, the diameter of the CNTs, and the length of CNTs, as well as chemical and mechanical treatments.

A resistive heating element for use in or manufacturing of a component of an aircraft or spacecraft. The resistive heating element includes a sheet made from carbon nanotubes (CNTs) having a length of at least about 5 μ.Math.η, and formed as a nonwoven or composite polymer sheet, having good uniformity. The sheet is made with a basis weight between 1 and 50 grams per square meter (gsm), to provide a resistance value, inversely related to the basis weight, of at least about 0.01 ohms per square (Ω/□), and up to about 100 Ω/□. The CNTs can have an aspect ratio of at least about 1000:1, and at least about 10,000:1 or 100,000:1. The resistance value of the sheet can be controlled by the basis weight of CNTs, the diameter of the CNTs, and the length of CNTs, as well as chemical and mechanical treatments.

The present disclosure relates to an aerosol delivery device that includes a reservoir housing that defines a mouthpiece channel. The aerosol delivery device includes a sealing member configured to be received within the reservoir housing to define a reservoir chamber configured to retain an aerosol precursor composition therein. The aerosol delivery device also includes a substrate member that is configured to be received within the reservoir housing and to be directly engaged with a vaporizing assembly for forming an aerosol. The reservoir housing, sealing member, substrate member, and/or vaporizing assembly can be used for forming aerosols with precise and reproducible compositions.

A heating furnace includes a bolt inserted through an insertion hole in a part of a heater and further inserted into a hole on a tip surface of an electrode rod. A first washer is between a bearing surface of the bolt and one face of the heater. A second washer is between another face of the heater and the tip surface. The relation of: |L.sub.0.Math.α.sub.0−(T.sub.H.Math.α.sub.H+T.sub.B.Math.α.sub.B+T.sub.E.Math.α.sub.E)|.Math.ΔT≦0.15(T.sub.B+T.sub.E) is satisfied, where L.sub.0 is an interval between the bearing surface and the tip surface, α.sub.0 is a linear expansion coefficient (LEC) of the bolt, T.sub.H, T.sub.B and T.sub.E are thicknesses of the part, first and second washers and α.sub.H, α.sub.B and α.sub.E are their LECs, respectively, and ΔT is a temperature increment quantity of a part where the heater and the electrode rod are fastened by the bolt.

A heating furnace includes a bolt inserted through an insertion hole in a part of a heater and further inserted into a hole on a tip surface of an electrode rod. A first washer is between a bearing surface of the bolt and one face of the heater. A second washer is between another face of the heater and the tip surface. The relation of: |L.sub.0.Math.α.sub.0−(T.sub.H.Math.α.sub.H+T.sub.B.Math.α.sub.B+T.sub.E.Math.α.sub.E)|.Math.ΔT≦0.15(T.sub.B+T.sub.E) is satisfied, where L.sub.0 is an interval between the bearing surface and the tip surface, α.sub.0 is a linear expansion coefficient (LEC) of the bolt, T.sub.H, T.sub.B and T.sub.E are thicknesses of the part, first and second washers and α.sub.H, α.sub.B and α.sub.E are their LECs, respectively, and ΔT is a temperature increment quantity of a part where the heater and the electrode rod are fastened by the bolt.

A heater 1a includes: a substrate 10 made of a resin; a conductive film 20 being a heating element; and a power supply electrode 30. The power supply electrode 30 is electrically connected to the conductive film 20 and is arranged along a surface of the conductive film 20. The power supply electrode 30 includes a conductive filler 30p and a binder 30m. The binder 30m binds the conductive filler 30p. The power supply electrode 30 has a specific resistance of 100 .Math.Ω•cm or less. The heater 1a satisfies a relation |Rd ― Ri|/Ri ≤ 0.2. Rd is an electrical resistance [Ω] of the heater 1a, the electrical resistance being obtained after an environment of the heater 1a is maintained at a temperature of 85° C. and a relative humidity of 85% for 1000 hours. Ri is an initial electrical resistance Ri of the heater 1a.

A heater 1a includes: a substrate 10 made of a resin; a conductive film 20 being a heating element; and a power supply electrode 30. The power supply electrode 30 is electrically connected to the conductive film 20 and is arranged along a surface of the conductive film 20. The power supply electrode 30 includes a conductive filler 30p and a binder 30m. The binder 30m binds the conductive filler 30p. The power supply electrode 30 has a specific resistance of 100 .Math.Ω•cm or less. The heater 1a satisfies a relation |Rd ― Ri|/Ri ≤ 0.2. Rd is an electrical resistance [Ω] of the heater 1a, the electrical resistance being obtained after an environment of the heater 1a is maintained at a temperature of 85° C. and a relative humidity of 85% for 1000 hours. Ri is an initial electrical resistance Ri of the heater 1a.

The method includes first defining at least one channel within a first housing of a heater assembly, the at least one channel extending from a first end to a second end of the first housing, second defining a cavity in the first end of the first housing, third defining a first reservoir in the second end of the first housing, the at least one channel being in fluid communication with the first reservoir, and fourth defining an opening within a first wall within the first housing, the opening causing the first reservoir and the cavity to be in communication with each other.