A window glazing assembly that can convert an existing or already-installed window, or be used to assemble new construction windows as a multi-pane or multi-glazed window unit, is provided herein. In particular, the glazing assembly includes an attachment assembly (e.g., peel-and-stick double-sided adhesive tape) and one or more glazing layers. Some embodiments further include a spacer assembly comprising a plurality of spacer bars that may be individually installed, e.g., one by one, around the perimeter of the window such as, to the window sash, window frame, or glass window pane, itself. The glazing layer(s) can then be secured or adhered to the spacer assembly, for example, around the perimeter thereof. Some embodiments may include additional or intermediate glazing layers, providing additional insulating airspaces and enhanced performance.

A wing profile has a glass package including several glass plates, wherein the wing profile has a reinforcement element made of plastic, which substantially is mounted on the wing profile below the entire support surface of the glass package. Between the reinforcement element and the glass package, a cohesive connection is provided by a plurality of adhesive elements.

A wing profile has a glass package including several glass plates, wherein the wing profile has a reinforcement element made of plastic, which substantially is mounted on the wing profile below the entire support surface of the glass package. Between the reinforcement element and the glass package, a cohesive connection is provided by a plurality of adhesive elements.

An improved method of sealing a window into an aperture in a body uses a lubricant comprising polymer particles suspended in a volatile, low viscosity, low surface tension carrier fluid. The carrier fluid is applied to one or both of the sidewalls of the window and aperture, and the window is pressed into the aperture such that the carrier fluid evaporates, leaving the polymer particles to fill interstitial surface voids, while enabling the sidewall of the window to make intimate mechanical contact with the sidewall of the aperture. While having broader application, the present disclosure finds particular utility in optical characterization techniques based upon the Raman effect and fluorescence probes used in process monitoring and control.

An integrated sash unit including a first sash portion. The first sash portion a first body portion and a first receiving wall extending inwardly from the first body portion. The first receiving wall has a first inner wall surface and a first peripheral wall surface opposing the first inner wall surface. The first body portion defines a first receiving surface and a first coupling surface and a first body peripheral surface opposite the first receiving surface and the first coupling surface. The integrated sash unit also includes a second sash portion forming a second body portion and a second receiving wall extending inwardly from the second body portion. The second receiving wall has a second inner wall surface and a second peripheral wall surface opposing the second inner wall surface. The second body portion defines a second receiving surface and a second coupling surface and a second body peripheral surface. The first coupling surface of the first sash portion is coupled to the second coupling surface of the second sash portion. The integrated sash unit also includes a first glazing panel supported by and coupled to the first inner wall surface of the first sash portion without being coupled to the second sash portion and a second glazing panel supported by and coupled to the second inner wall surface of the second sash portion without being coupled to the first sash portion.

A window glazing system includes an elongate elastomeric element having a right triangular cross section defining two leg surfaces and a hypotenuse surface with chamfers on the legs at the hypotenuse. A window pane is placed in a window frame and the interior frame and the window pane are appropriately coated with construction adhesive. The legs of the elongate element are forced into the intersection of the pane and the interior frame to spread and to be retained by the adhesive. The adhesive is then additionally forced into the chamfers and the entire assembly cleaned with solvent.

A window glazing system includes an elongate elastomeric element having a right triangular cross section defining two leg surfaces and a hypotenuse surface with chamfers on the legs at the hypotenuse. A window pane is placed in a window frame and the interior frame and the window pane are appropriately coated with construction adhesive. The legs of the elongate element are forced into the intersection of the pane and the interior frame to spread and to be retained by the adhesive. The adhesive is then additionally forced into the chamfers and the entire assembly cleaned with solvent.

Refers to the present invention, a device (1) that will be fabricated with appropriate material, with several dimensions, to be adapted to a computerized numeric platform, for the structural glazing process, which is a technique of fixing the glass and the frame, through application of the high adhesion double-sided tape between them, the structure remains hidden on the inner side, in two basic steps, one being application and cutting of the high adhesion double-sided tape over the glass sheet, and the other is (applying) correct pressure on them, for the purpose of replacing the current manual process.

A molded door skin with integral divided light bars. The divided light bars are either true divided light (TDL) bars simulated divided light (SDL) bars or decorative grilles. The door skin includes a body portion and a divided light bar portion. The body portion and divided light bar portion are of one-piece construction which is preferably compression molded from fiberglass or other synthetic materials. Once assembled into a door with door glass installed, the divided light bars form a number of small windows for either simulating the appearance of traditional divided light windows in SDL applications, holding individual panes of insulating glass units in TDL applications, or for decorative purpose only.

Disclosed is a facade element having a first glass unit, in particular insulating glass unit, and at least one second glass unit, in particular insulating glass unit, arranged adjacently thereto, wherein the two glass units are connected to one another via their edges adjoining one another in an abutment region, preferably exclusively with the aid of an, in particular transparent, adhesive connection, wherein the adhesive connection is preferably formed by a two-component silicone material. The invention further relates to a corresponding production method.