Abstract: A conduit coupling system, sealing device, bell, and method of use are disclosed herein. The system comprises at least two piping components, and a sealing device. A first component has a bell and a second component has a spigot, the spigot is adapted to mate with the bell. The bell comprises a first end and a second end, the first end coupled to the first component. The bell has a concave annular inner surface and a diameter of the annular inner surface adjacent to the first end of the bell is greater than a diameter of the annular inner surface adjacent to the second end of the bell. The sealing device comprises a locking segment comprising a convex outer surface and a K-type gasket coupled to a locking segment or a non-restraining anti-extrusion segment. The sealing device is adapted to fit between the bell and the spigot.

Abstract: A conduit coupling system, sealing device, bell and method of use are disclosed herein. The system comprises at least two piping components, and a sealing device. A first component has a bell and a second component has a spigot, the spigot is adapted to mate with the bell. The bell comprises a first end and a second end, the first end coupled to the first component. The bell has a concave annular inner surface and a diameter of the annular inner surface adjacent to the first end of the bell is greater than a diameter of the annular inner surface adjacent to the second end of the bell. The sealing device comprises a locking segment comprising a convex outer surface and a K-type gasket coupled to a locking segment or a non-restraining anti-extrusion segment. The sealing device is adapted to fit between the bell and the spigot.

Abstract: A method of use of a conduit coupling system, sealing device, and bell are disclosed herein. The method comprises positioning a sealing device inside a bell coupled to one end of a first conduit, inserting a spigot of a second conduit through the sealing device inside the bell, wherein the sealing device is adapted to move axially within the bell in the direction of the insertion of the spigot and in a radial direction from a centerline of the conduit, and partially removing the spigot from the bell, wherein a segment of the sealing device engages the outer surface of the spigot end as the spigot end is partially removed from the bell. The bell comprises a first end and a second end, the first end coupled to the first conduit. The bell has a concave annular inner surface and a diameter of the annular inner surface adjacent to the first end of the bell is greater than a diameter of the annular inner surface adjacent to the second end of the bell.

Abstract: A coating for a metal surface that provides excellent resistance to both electrochemical corrosion and mechanical insult is provided. The coating involves at least an inner coating that is a sacrificial anodic layer and an outer coating that is a protective dielectric material made of inorganic metal oxide. Some versions of the coating include an intermediate layer as well that serves to improve adhesion between the coatings and may provide additional galvanic protection. Although the coating can be made by a variety of methods, advanced methods of spray application are provided for making high-quality lightweight versions the coating.

Abstract: A conduit coupling system, sealing device, bell and method of use are disclosed herein. The system comprises at least two piping components, and a sealing device. A first component has a bell and a second component has a spigot, the spigot is adapted to mate with the bell. The bell comprises a first end and a second end, the first end coupled to the first component. The bell has a concave annular inner surface and a diameter of the annular inner surface adjacent to the first end of the bell is greater than a diameter of the annular inner surface adjacent to the second end of the bell. The sealing device comprises a locking segment comprising a convex outer surface and a K-type gasket coupled to a locking segment or a non-restraining anti-extrusion segment. The sealing device is adapted to fit between the bell and the spigot.

Abstract: A gasket and a piping system using the gasket are disclosed. The gasket has an o-shaped body including an inner diameter and an outer diameter. The gasket further may include at least one gasket retaining bar attached to the body that bar prevents the gasket from being displaced while the spigot is being inserted into the gasket. The gasket may also include at least one restraining device attached to the body. The restraining device has at least one edge that extends beyond the inner diameter of the body of the gasket to engage the spigot.

Abstract: A protective coating for a metal substrate is provided that is light, durable, galvanically protective, and easily applied at the site of manufacture. The coating has at least two layers, one of which is a galvanizing layer and one of which is a micro-composite of a galvanic metal and a non-conducting material, such as polymer. Such coatings are useful for example to protect pipes or other metal surfaces in corrosive environments. Methods of producing the coating are provided, including methods that use advanced spraying techniques to provide very thin but consistent layers. Using the advanced spraying methods the composite layer can be created by co-spraying the galvanic metal and the nonconductive material onto the surface of the galvanic coating. Optionally, an outer coat of insulating material can be applied to provide further protection to the surface.

Abstract: In an exemplary embodiment, a temperature sensor and a 4-20 mA transmitter on a single flexible circuit subassembly with a separate housing suitable for use in industrial control or HVAC applications. In a preferred embodiment, a narrow flex circuit substrate includes a silicon diode-based surface-mount sensor at a sensor end, a surface-mount programmable transmitter IC on a flex circuit substrate in the transmitter section, conductive traces connecting the sensor to the transmitter IC, and two conductive pads at an output end for connecting the 4-20 mA output to a pair of external wires. Additional traces on the flex subassembly are provided for testing and programming the transmitter IC and sensor. The sensor end of the flex subassembly is mounted in a metal sensor tube, filled and sealed in the same manner as RTD or thermistor sensors with leads are currently assembled for use in industrial control or HVAC applications.

Abstract: A system and method is provided for improving the accuracy of the voltage reference output of a floating gate voltage reference circuit by minimizing the temperature coefficient, Tc. The system and method provides a minimized Tc on output reference voltage, for a wide variety of such output voltages. In a dual floating gate voltage reference circuit wherein a voltage reference output (Vref) is generated as a function of the difference in charge of said floating gates, a method includes causing each of the floating gates to change voltage substantially the same amount as a function of temperature such that, during a read mode of the reference circuit, the temperature coefficient, Tc, of the voltage reference output is substantially reduced. The system and method achieves very low Tc over a wide range of reference or comparator voltages using low cost analog test equipment and methods.

Abstract: A circuit for setting a reference voltage in a floating gate circuit is configured as a precise voltage comparator circuit with a built-in programmable voltage reference. Once the one or more floating gates in the floating gate circuit are set during the a SET operation, the floating gate circuit is configured during a READ mode as a comparator circuit with a built-in voltage reference.

Abstract: A system and method is provided for improving the accuracy of the voltage reference output of a floating gate voltage reference circuit by minimizing the temperature coefficient, Tc. The system and method provides a minimized Tc on output reference voltage, for a wide variety of such output voltages. In a dual floating gate voltage reference circuit wherein a voltage reference output (Vref) is generated as a function of the difference in charge of said floating gates, a method includes causing each of the floating gates to change voltage substantially the same amount as a function of temperature such that, during a read mode of the reference circuit, the temperature coefficient, Tc, of the voltage reference output is substantially reduced. The system and method achieves very low Tc over a wide range of reference or comparator voltages using low cost analog test equipment and methods.

Abstract: A method and apparatus for stabilizing the charge on a floating gate in a floating gate reference voltage generator. After an initial high voltage set mode, the method and apparatus allows for a controlled ramp down sequence to ramp down the voltages at the floating gate erase and program electrode generated by first and second bias sources coupled thereto, such that, when these bias sources are completely shut down in the generator, a more accurate voltage is set on the floating gate. The first bias source is preferably a voltage source and the second bias source is preferably a current source. The voltage at the erase electrode that is coupled to the floating gate is controlled during the ramp down sequence by shutting off the current source coupled thereto while allowing a feedback circuit in the generator to remain active.

Abstract: A floating gate circuit having a floating gate and a level shift circuit. A first tunneling device formed between a first and second tunnel electrode is included for removing electrons from the floating gate. Electrons are injected onto the floating gate without the use of a tunneling device, e.g., using avalanche injection. A first circuit is coupled to the floating gate for generating an output voltage at an output terminal. The level shift circuit has a second tunnel device coupled between the output terminal and the first tunnel electrode. The second tunnel device is for tracking changes in the characteristics of the first tunneling device connected to the floating gate. The level shift circuit level shifts the output of the floating gate circuit to a voltage that enables the tunnel device coupled to a floating gate to precisely set the floating gate to a desired voltage during a set mode.

Abstract: A mechanical pipe joint, restraining gasket, and method for restraining pipe spigots within adjacent bell sockets. The restraining gasket is composed of two axially-separate components: a sealing portion and a restraining portion made of a plurality of arcuate locking members. The restraining gasket and a gland surround an outer surface of the pipe spigot. The mechanical pipe joint is formed as the pipe spigot is inserted into the bell socket and the gland is axially attached to the bell socket so that the restraining gasket is held between: the gland, an inner surface of the bell socket, and the outer surface of the pipe spigot, so as to provide a fluid seal in the joint and urge the locking members into contact with the outer surface of the pipe spigot, axially restraining the pipe spigot within the bell socket.

Abstract: A floating gate voltage level shift circuit is disclosed for generating a voltage reference which can operate on a low supply voltage Vcc by providing a circuit that enables the floating gate to be set accurately to a positive voltage during a SET operation and subsequently shifted down to a lower voltage for a READ operation. The floating gate voltage level shift circuit comprises a differential amplifier with two floating gates, a first floating gate and a second floating gate where the second floating gate is capacitively coupled to either a READ voltage or a Vshift voltage. The floating gate voltage level shift circuit operates in two primary modes, a SET operation and a READ operation. During the SET operation, the C1p capacitor of the second floating gate is connected to a Vshift voltage, rather than ground, while accurately setting the floating gate a positive voltage.

Abstract: A floating gate circuit has a level shift circuit. The floating gate circuit includes: a floating gate; a first and second tunnel device formed respectively between a first and second tunnel electrode; a first circuit coupled to the floating gate for generating an output voltage at an output terminal; a level shift circuit having a third tunnel device coupled between the output terminal and the first tunnel electrode; and a second circuit for causing a first current to flow through the first and second tunnel devices and for causing a second current to flow through the third tunnel device. The floating gate circuit then settles to a steady state condition during the set mode such that the first and second currents are approximately equal and the floating gate voltage and the output voltage are approximately equal.

Abstract: A method and circuit for setting a reference voltage in a dual floating gate circuit is disclosed. During a set mode, a first and second floating gate are programmed to different charge levels that are a function of an input set voltage capacitively coupled to the first floating gate during the set mode. During a read mode, this difference in charge level is used by the dual floating gate circuit to generate a reference voltage that is a function of the input set voltage, and is preferably equal to the input set voltage.