Abstract: A sealable container (210) for flowable material formed with top (212) and flexible and stiffened bottom (214) walls joined by front (216), rear (218), and opposite side walls (220, 222). The top wall including an openable lid (D) formed with an improved scoop holder (30) and a collar (300) received about a finish (282) of the front, rear, and side walls. The flexible and stiffened bottom wall (214) includes at least one sagittal stiffening channel (500) and an optional transverse stiffening channel (530). The openable lid includes a sealing wall (340) that cooperates with other improved container components to prevent spillage of the flowable material after the seal is peeled and removed.

Abstract: A fitting for a tube or pipe capable of functioning a high pressures having a first fitting component adapted to receive the conduit end; a conduit gripping device such as a ferrule or ferrules and a second fitting component that can be joined to the first fitting component to cause the conduit gripping device to grip the conduit and seal when assembled. In one aspect of the invention, the first fitting component is constructed from a material that is softer than the material used to construct the second fitting component. An additional aspect of the invention include a retaining portion on the second fitting component that constrains the tube gripping device against pressure. The retaining portion can also be configured to retain the tube gripping device to the second fitting component prior to installation and in a finger-tight condition.

Abstract: Mechanically attached connections for conduits may include a conduit gripping member and first and second connection members. The first and second connection members may be, for example, a nut member and a body member where the connection members cause axial movement of the conduit gripping member to grip and seal the conduit when the assembly is pulled-up. The mechanically attached connection may include a sensing function for detecting or sensing a condition or characteristic of at least one of the following: the mechanically attached connection, one or more of the connection members, the fluid contained by the mechanically attached connection, or a combination thereof. The sensing function may be, for example, a sensor that is integrated with at least one of the nut member and the body member.

Abstract: A syringe containing a high water content product and for use in a drug infusion system is provided. The syringe includes a plunger carrying front and rear o-rings made of a diene rubber compound such as chlorobutyl rubber or bromobutyl rubber to impart very low gas permeability characteristics to the o-rings. The plunger may be molded as a single part or in two parts. If molded as one part with radially-engaging mold portions, the seal glands in the plunger may include parting lines from the mold. If molded as two parts with axially-engaging mold portions, the front seal gland may include a sealing surface and under cut that has no parting line. The o-rings may be surface treated with a lubricant to improve sealing where the molding process gives rise to parting lines in the seal glands.

Abstract: A fitting is provided that may optionally be pulled up to its final assembled condition by torque rather than by turns. At least one fitting component includes a structure that facilitates pull up by torque. In one embodiment, a ring is provided that may be disposed on one of the fitting components and includes an engagement surface that engages a surface on the other of the fitting components at a first axial position that corresponds to a complete pull up. The engaging surfaces increase the torque required to continue pulling up the fitting past the first axial position.

Abstract: A vehicle, air brake system is presented with an improved service work brake arrangement. The arrangement may provide a service work brake function or both a service work brake function and a parking brake function for the vehicle. The arrangement may provide an improved service work brake arrangement disposed within a housing for reducing the number of components and plumbing required to achieve this functionality versus prior known systems. The arrangement may utilizes a pneumatic latching valve to deliver pressurized air for applying a vehicle's service brakes. The pneumatic latching valve opens upon receiving a pneumatic control signal from an electronically controlled valve and closes upon receiving a pneumatic control signal from another source. In addition, a controller and control logic may be provided for controlling the arrangement.

Abstract: Electronic elements having an active device region and integrated passive device (IPD) region on a common substrate preferably include a composite dielectric region in the IPD region underlying the IPD to reduce electro-magnetic (E-M) coupling to the substrate. Mechanical stress created by plain dielectric regions and its deleterious affect on performance, manufacturing yield and occupied area may be avoided by providing electrically isolated inclusions in the composite dielectric region of a material having a thermal expansion coefficient (TEC) less than that of the dielectric material in the composite dielectric region. For silicon substrates, non-single crystal silicon is suitable for the inclusions and silicon oxide for the dielectric material. The inclusions preferably have a blade-like shape separated by and enclosed within the dielectric material.

Abstract: Fittings are provided for use with different types of tubing. One such fitting includes a gripping member having a sharp tube indenting edge that provides a seal between the tube gripping member and the tube. Another such fitting includes a tube gripping member having a body indenting edge that provides a seal between the tube gripping member and a fitting body.

Abstract: Electronic elements having an active device region and bonding pad (BP) region on a common substrate desirably include a dielectric region underlying the BP to reduce the parasitic impedance of the BP and its interconnection as the electronic elements are scaled to higher power and/or operating frequency. Mechanical stress created by plain (e.g., oxide only) dielectric regions can adversely affect performance, manufacturing yield, pad-to-device proximity and occupied area. This can be avoided by providing a composite dielectric region having electrically isolated inclusions of a thermal expansion coefficient (TEC) less than that of the dielectric material in which they are embedded and/or closer to the substrate TEC. For silicon substrates, poly or amorphous silicon is suitable for the inclusions and silicon oxide for the dielectric material. The inclusions preferably have a blade-like shape separated by and enclosed within the dielectric material.

Abstract: Electronic elements having an active device region and integrated passive device (IPD) region on a common substrate preferably include a composite dielectric region in the IPD region underlying the IPD to reduce electro-magnetic (E-M) coupling to the substrate. Mechanical stress created by plain dielectric regions and its deleterious affect on performance, manufacturing yield and occupied area may be avoided by providing electrically isolated inclusions in the composite dielectric region of a material having a thermal expansion coefficient (TEC) less than that of the dielectric material in the composite dielectric region. For silicon substrates, non-single crystal silicon is suitable for the inclusions and silicon oxide for the dielectric material. The inclusions preferably have a blade-like shape separated by and enclosed within the dielectric material.

Abstract: Electronic elements (44, 44?, 44?) having an active device region (46) and integrated passive device (IPD) region (60) on a common substrate (45) preferably include a composite dielectric region (62, 62?, 62?) in the IPD region underlying the IPD (35) to reduce electromagnetic (E-M) (33) coupling to the substrate (45). Mechanical stress created by plain dielectric regions (36?) and its deleterious affect on performance, manufacturing yield and occupied area may be avoided by providing electrically isolated inclusions (65, 65?, 65?) in the composite dielectric region (62, 62?, 62?) of a material having a thermal expansion coefficient (TEC) less than that of the dielectric material (78, 78?, 78?) in the composite dielectric region (62, 62?, 62?). For silicon substrates (45), non-single crystal silicon is suitable for the inclusions (65, 65?, 65?) and silicon oxide for the dielectric material (78, 78?, 78?).

Abstract: A ferrule type, flareless fitting is provided that may optionally be pulled-up to its assembled condition by torque rather than by turns. In one embodiment, at least one fitting component includes a structure that facilitates pull-up by torque and allows the fitting to be remade. The structure may take a wide variety of different forms. Examples of fitting component structures that facilitate pull-up by torque and allow the fitting to be remade include, but are not limited to, deformable or compressible devices or structures that are configured to increase the torque required to further tighten the fitting components when the fitting is properly pulled up, resiliently deformable structures that bias a tube gripping device into engagement with a conduit when the fitting is remade to an initial pull-up position, and plastically deformable retaining structures that maintain a tube gripping device in sealing en a ement with a conduit when a fittin is disassembled.

Abstract: Electronic elements having an active device region and bonding pad (BP) region on a common substrate desirably include a dielectric region underlying the BP to reduce the parasitic impedance of the BP and its interconnection as the electronic elements are scaled to higher power and/or operating frequency. Mechanical stress created by plain (e.g., oxide only) dielectric regions can adversely affect performance, manufacturing yield, pad-to-device proximity and occupied area. This can be avoided by providing a composite dielectric region having electrically isolated inclusions of a thermal expansion coefficient (TEC) less than that of the dielectric material in which they are embedded and/or closer to the substrate TEC. For silicon substrates, poly or amorphous silicon is suitable for the inclusions and silicon oxide for the dielectric material. The inclusions preferably have a blade-like shape separated by and enclosed within the dielectric material.

Abstract: Electronic elements (44, 44?, 44?) having an active device region (46) and bonding pad (BP) region (60) on a common substrate (45) desirably include a dielectric region underlying the BP (35) to reduce the parasitic impedance of the BP (35) and its interconnection (41) as the electronic elements (44, 44?, 44?) are scaled to higher power and/or operating frequency. Mechanical stress created by plain (e.g., oxide only) dielectric regions (36?) can adversely affect performance, manufacturing yield, pad-to-device proximity and occupied area. This can be avoided by providing a composite dielectric region (62, 62?, 62?) having electrically isolated inclusions (65, 65?, 65?) of a thermal expansion coefficient (TEC) less than that of the dielectric material (78, 78?, 78?) in which they are embedded and/or closer to the substrate (45) TEC. For silicon substrates (45), poly or amorphous silicon is suitable for the inclusions (65, 65?, 65?) and silicon oxide for the dielectric material (78, 78?, 78?).

Abstract: Three elements of a fluid flow control device—switch, button, label—are designed to minimize the possibility of two labeled buttons being swapped on their switches. If the parts are assembled incorrectly or mislabeled, or if the buttons are thereafter swapped on the switches, it will be very obvious; then, if one attempts to fix such a problem, it can only be fixed by placing the buttons on the correct switches, and it can not be fixed by leaving the buttons on the wrong switches.

Abstract: A sealable container (210) for flowable material formed with top (212) and flexible and stiffened bottom (214) walls joined by front (216), rear (218), and opposite side walls (220, 222). The top wall including an openable lid (D) formed with an improved scoop holder (30) and a collar (300) received about a finish (282) of the front, rear, and side walls. The flexible and stiffened bottom wall (214) includes at least one sagittal stiffening channel (500) and an optional transverse stiffening channel (530). The openable lid includes a sealing wall (340) that cooperates with other improved container components to prevent spillage of the flowable material after the seal is peeled and removed.

Abstract: A fitting for a tube or pipe capable of functioning a high pressures having a first fitting component adapted to receive the conduit end; a conduit gripping device such as a ferrule or ferrules and a second fitting component that can be joined to the first fitting component to cause the conduit gripping device to grip the conduit and seal when assembled. In one aspect of the invention, the first fitting component is constructed from a material that is softer than the material used to construct the second fitting component. An additional aspect of the invention include a retaining portion on the second fitting component that constrains the tube gripping device against pressure. The retaining portion can also be configured to retain the tube gripping device to the second fitting component prior to installation and in a finger-tight condition.

Abstract: Apparatus and method for mechanically attached connections of conduits may include a conduit gripping member (34), a drive member (36), and a seal member (48), the drive member causing axial movement of the conduit gripping member to indent into an outer surface of the conduit when the assembly is pulled-up, the drive member causing the seal member to form a zero clearance seal at a location that is axially spaced from the conduit gripping member. The zero clearance seal may comprise a face seal arrangement including a gasket (48), and the conduit gripping member may be a ferrule, ring or other device that can grip and optionally seal against the conduit outer surface. The assembly may include a sensing function for detecting or sensing a characteristic or condition of an assembly component or the fluid or both, hi one embodiment, a body coupling member has a two piece construction of a main body and a conduit socket insert. A flared fitting embodiment is also provided.

Abstract: A tube fitting for a tube end has a female member that cooperates with a male member. A tube gripping device in the form of a gripping ring or ferrule is retained with the female member. Upon a partial pull-up, the tube gripping device separates from the female member.

Abstract: Two conduit gripping devices that are to be used together in a conduit fitting assembly are interconnected or held together as a cartridge or subassembly prior to assembly with fitting components to form a fitting assembly. In a more specific embodiment, one or both of the conduit gripping devices comprises a retaining structure by which the devices are mechanically connected together as a subassembly. For example, in one embodiment a front ferrule and a back ferrule for a tube fitting may be snapped together.