1010results about How to "Reduce material usage" patented technology

An interference display unit with a first electrode, a second electrode and posts located between the two electrodes is provided. The characteristic of the interference display unit is that the second electrode's stress is released through a thermal process. The position of the second electrode is shifted and the distance between the first electrode and the second electrode is therefore defined. A method for fabricating the structure described as follow. A first electrode and a sacrificial layer are sequentially formed on a substrate and at least two openings are formed in the first electrode and the sacrificial layer. A supporter is formed in the opening and the supporter may have at least one arm on the top portion of the supporter. A second electrode is formed on the sacrificial layer and the supporter and a thermal process is performed. Finally, The sacrificial layer is removed.

Refractive projection objective with a numerical aperture greater than 0.7, consisting of a first convexity, a second convexity, and a waist arranged between the two convexities. The first convexity has a maximum diameter denoted by D1, and the second convexity has a maximum diameter denoted by D2, and 0.8<D1 / D2<1.1.

A transfer method comprising a step of forming a plurality of transferred bodies on a transfer origin substrate, and a step of applying energy to partial regions corresponding to the transferred bodies to be transferred, and transferring these transferred bodies corresponding to the partial regions onto a transfer destination substrate. A plurality of transferred bodies such as devices or circuits that are to be disposed on a transfer destination substrate with spaces therebetween can be manufactured integrated together on a transfer origin substrate, and hence compared with the case that the transferred bodies are formed on the transfer destination substrate directly, the amount of materials used in the manufacture of the transferred bodies can be reduced, the area efficiency can be greatly improved, and a transfer destination substrate on which a large number of devices or circuits are disposed in scattered locations can be manufactured efficiently and cheaply.

A system suitable for collecting a body fluid, in particular blood from a body region of a person to be examined which comprises a lancing device which is suitable for holding a lancet, a lancet magazine for storing two or several lancets which has a transport device for the lancets and has an opening into which the lancing device can be inserted to remove a lancet from the lancet magazine, and two or several lancets, and which comprises a method for removing a lancet from a lancet magazine in which a lancet located in the lancet magazine is manually or automatically transported into a removal position in the interior of the lancet magazine, a lancing device is partially inserted into the opening provided in the lancet magazine in the process of which the lancing device automatically grips the lancet located in the removal position when it is partially inserted and the lancing device with the gripped lancet is removed from the lancet magazine.

A strong, easy to use tab and slot fastening device suitable for use with disposable absorbent articles. The fastening device preferably includes a tab member and a slot member. The slot member has an inboard portion, an outboard portion and a slot. The inboard portion located laterally inboard of the outboard portion and the slot located between the inboard portion and the outboard portion. The tab member has a length, a proximal edge, a distal edge and a lip portion. The tab portion is passed through the slot of the slot member to engage the fastening device. Once passed through the slot, at least the lip portion of the tab member pivots such that it overlaps the outboard portion of the slot member to prevent the tab member from disengaging from the slot member.

A transfer method comprising a step of forming a plurality of transferred bodies on a transfer origin substrate, and a step of applying energy to partial regions corresponding to the transferred bodies to be transferred, and transferring these transferred bodies corresponding to the partial regions onto a transfer destination substrate. A plurality of transferred bodies such as devices or circuits that are to be disposed on a transfer destination substrate with spaces therebetween can be manufactured integrated together on a transfer origin substrate, and hence compared with the case that the transferred bodies are formed on the transfer destination substrate directly, the amount of materials used in the manufacture of the transferred bodies can be reduced, the area efficiency can be greatly improved, and a transfer destination substrate on which a large number of devices or circuits are disposed in scattered locations can be manufactured efficiently and cheaply.

An interference display unit with a first electrode, a second electrode and posts located between the two electrodes is provided. The characteristic of the interference display unit is that the second electrode's stress is released through a thermal process. The position of the second electrode is shifted and the distance between the first electrode and the second electrode is therefore defined. A method for fabricating the structure described as follow. A first electrode and a sacrificial layer are sequentially formed on a substrate and at least two openings are formed in the first electrode and the sacrificial layer. A supporter is formed in the opening and the supporter may have at least one arm on the top portion of the supporter. A second electrode is formed on the sacrificial layer and the supporter and a thermal process is performed. Finally, The sacrificial layer is removed.

System and methods for creating shaped, non-circular boreholes in rocks especially for use with geothermal heat pump applications and for increasing wellbore support in applications such as horizontal oil and gas drilling are described. The systems and methods when applied to geothermal heat pumps create an elliptical shaped hole that is optimized for placing heat transfer tubes with a minimum of grout used. The significantly reduced cross-sectional area of the elliptical borehole also increases the overall drilling rate in rock and especially in hard rocks. In horizontal hard-rock drilling, creation of a horizontal non-circular borehole or modification of a circular borehole to a non-circular geometry is used to stabilize the borehole prior to casing insertion, and may also allow the use of lower mud pressures improving drilling rates. The system uses a non-contacting drilling system which in one embodiment uses a supersonic flame jet drilling system with a movable nozzle that swings between pivot points. In a second embodiment the elliptical shaped hole is created by an abrasive fluid or particle bearing-fluid or air jet drill that moves between pivot points. In another embodiment a non-contacting drill can use dual parallel nutating nozzles that create a pair of overlapping circular holes. The non-circular shaped hole is created by either the high temperature flame or water-particle jet or chemically active fluid jet as it removes rock material by erosion, dissolution and or thermal spalling. Modifications of circular boreholes to a generally elliptical shape can also be done using milling or jetting techniques.

A light control device for a light source unit having a specific spatial intensity and / or spectral distribution is provided herein. The light control device is positioned on the path of the light from the light source unit and contains at least one of three light control functions, namely the diffusion, collimation, and color mixing, which has a spatial distribution of its processing power corresponding to the spatial intensity and / or spectral distribution of the incident light. The light control device could also directly or interactively combine two or more of the light control functions into a single device. At least one of the combined light control functions of the device has a spatial distribution of its processing power corresponding to the spatial intensity and / or spectral distribution of the incident light to the device.

The present invention relates generally to mill blank constructions to facilitate the manufacture of dental restorations. A given mill blank is formed in a shape (i.e. with a given geometry) that has been predetermined to reduce material waste when the mill blank is machined into the final part. A set of two or more blanks each having such characteristics comprise a smart blank “library.” In one embodiment, a smart blank library includes a sufficient number of unique blanks such that, when the geometry of the designed restoration is known, the smart blank with a highest yield can be selected for use in milling the restoration. The “yield” of a given smart blank represents the amount of material of the smart blank that is actually used in the final restoration. Automated processes for smart blank inventory management and smart blank selection are also described.

A shaver that includes a handle with an elongated handgrip portion and a mounting portion, and a shaver head attached to the mounting portion. A removable cartridge is attached to the shaver head through a rotating lock. The rotating lock is adapted to rotate about an axis parallel to the length of the blades of the cartridge, thus defining a neutral position and a rotated position. The rotating lock in the neutral position attaches the cartridge to the shaver head, and the rotating lock in the rotated position releases the cartridge from the shaver head.

A heat exchange reactor including a housing, a plurality of tubes mounted in the housing and configured to carry a first fluid, and a baffle having a plurality of holes receiving the tubes. The baffle is configured to guide a second fluid provided within the housing to flow in a direction generally perpendicular to the tubes. The reactor includes various configurations for minimizing adverse effects of thermal expansion of the baffle and the tubes. The reactor is configured to minimize mechanical interference between the baffle and the tubes in both an operational state and a non-operational state, for example, by shaping the holes in the baffle to take into account thermal expansion. The reactor also includes a thermal insulator along a length of the tubes at a large temperature gradient zone within the reactor. The reactor further includes a heat transfer fin in contact with only one of the tubes.