The present invention deals with integrating methods for manufacturing and applying a spacer frame to a glass plate, particularly in the circumstance of increased sizes thereof, of the rigid type, i.e. which profiles essentially are formed by a hollow body having cross section close to the rectangular, micro-perforated in the wall facing the chamber of the insulating glass, where at least the wall facing the outer cavity intended for the secondary sealant is made of solid metal material or with a metal liner, the remaining walls or all the walls being capable of being made of plastic or metal, e.g. aluminum or stainless steel. Certain innovative elements of the devices implementing such methods are also claimed.

A spacer frame assembly and method of manufacturing that includes a substantially linear channel comprising two lateral walls connected by a base wall, the channel having first and second ends that when assembled, includes at least three sides and corresponding corners between each of the sides; the linear channel further includes a nose portion of the first end and a receiving portion of the second end having a channel for receiving the nose portion; and the nose portion comprising a first undulation in the first end and the receiving portion comprising a second undulation in the second end. The first and second undulations nest when the ends are in an assembled position.

Method and Apparatus for fabricating a spacer frame for use in an insulating glass unit. One of a multiple number of possible spacer frame materials is chosen for the spacer frame. An elongated strip of the material is moved to a notching station where notches are formed at corner locations. The character of the notches is adjusted based on the selection of the metal strip material and more particularly to achieve bending of the material in an repeatable, straightforward manner. Downstream from the notching station the metal strip is bent into a channel shaped elongated frame member having side walls. Further downstream a leading strip of channel shaped material is severed or separated front succeeding material still passing through the notching and bending station.

A spacer construction for insulating glass for windows comprised of thin sheets of metal, such as stainless steel, formed with a first bottom side panel wherein the first bottom side panel joins first and second spaced, typically diverging, lateral side walls or panels. A second inside wall of the spacer assembly is spaced from the bottom side of the first section or channel and joins, typically by welding, to the lateral side walls of the first section thereby forming a tube or chamber into which desiccant may be placed. A cushion material layer is positioned over and on the bottom side panel and is covered by a polymeric sheet affixed or bonded to the lateral sides to form an internal chamber filled with desiccant. The desiccant is positioned to impact against the film or sheet bonded to the bottom side panel and at least a portion of the lateral side walls of the channel enabling the assembly to effectively accommodate bending forces and stress upon bending of the spacer.

A joiner clip for use in a spacer frame assembly and method of assembly are disclosed herein. The joiner clip includes first and second arms coupled to and extending away from a body, the first and second arms comprising mirror images of each other across a first mirror image axis. The first and second arms are housed within a first channel end of a linear spacer frame when assembled. The joiner clip further includes third and fourth arms coupled to and extending away from the body and away from the first and second arms, the third and fourth arms comprising mirror images of each other across the first mirror image axis. The third and fourth arms are housed within an opposite frame end of the linear spacer frame when assembled. When assembled, the body spaces the first channel end from the opposite frame end.

Method and Apparatus for fabricating a spacer frame for use in an insulating glass unit. One of a multiple number of possible spacer frame materials is chosen for the spacer frame. An elongated strip of the material is moved to a notching station where notches are formed at corner locations. The character of the notches is adjusted based on the selection of the metal strip material and more particularly to achieve bending of the material in an repeatable, straightforward manner. Better control over the notching process is also achieved by exhaust flow control of a double acting cylinder. A positioning spacer achieve very accurate side to side positioning of a die and anvil to precisely notch and deform the metal strip. Downstream from the notching station the metal strip is bent into a channel shaped elongated frame member having side walls. Further downstream a leading strip of channel shaped material is severed or separated from succeeding material still passing through the notching and bending station.

A spacer for an insulated glazing unit (IGU) is provided herein, along with an IGU and methods of making the spacer and IGU. The spacer imparts high thermal insulation to the IGU. Also provided are methods of preparing an insulating glazing unit, as well as methods of preparing a spacer for an IGU.

A spacer construction for insulating glass for windows comprised of thin sheets of metal, such as stainless steel, formed with a first bottom side panel wherein the first bottom side panel joins first and second spaced, typically diverging, lateral side walls or panels. A second inside wall of the spacer assembly is spaced from the bottom side of the first section or channel and joins, typically by welding, to the lateral side walls of the first section thereby forming a tube or chamber into which desiccant may be placed. A cushion material layer is positioned over and on the bottom side panel and is covered by a polymeric sheet affixed or bonded to the lateral sides to form an internal chamber filled with desiccant. The desiccant is positioned to impact against the film or sheet bonded to the bottom side panel and at least a portion of the lateral side walls of the channel enabling the assembly to effectively accommodate bending forces and stress upon bending of the spacer.

A spacer frame assembly and method of assembly includes a substantially linear channel having first and second ends. The substantially linear channel that when assembled includes at least four sides and corresponding corners between each of the sides. The spacer frame assembly also has a connecting structure located at one of the first and second ends and an opposite frame end located at the other of the one of first and second ends. The opposite frame end has an inner channel for receiving a nose portion of the connecting structure. The spacer frame assembly also includes a stop extending from the connecting structure for locating the opposite frame end when in the assembled position.

A spacer frame assembly and method of assembly includes a substantially linear channel comprising two lateral walls and a base wall. The channel has first and second ends that when assembled, includes at least three sides and corresponding corners between each of said sides. The first end includes a connecting structure and the second end includes an opposite frame end. The opposite frame end has an opposite channel for receiving a nose portion of said connecting structure The opposite channel includes stiffening flanges extending inwardly from the lateral walls relative to the channel. The connecting structure further includes a first aperture in the base wall comprising a first projection into the channel and the opposite channel comprises a second aperture in the base wall comprising a second projection into the channel. Wherein the first projection. tactilely interweaves with the second projection when the spacer frame is assembled.