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Bonds phosphoric acid

ASTM D3933, Standard Guide for Preparation of Aluminum Surfaces for Structural Adhesives Bonding, Phosphoric Acid Anodization, A.STM, West Conshohocken, PA. El-Mashri, S.M., Jones, R.G. and Forty, A.J., Philo.s. Mag. A, 48, 665 (1983). [Pg.1005]

The only element that was discovered in body fluids (urine). This is plausible, as P plays a main role in all life processes. It is one of the five elements that make up DNA (besides C, H, N, and 0 evolution did not require anything else to code all life). The P-O-P bond, phosphoric acid anhydride, is the universal energy currency in cells. The skeletons of mammals consists of Ca phosphate (hydroxylapatite). The element is encountered in several allotropic modifications white phosphorus (soft, pyrophoric P4, very toxic), red phosphorus (nontoxic, used to make the striking surface of matchboxes), black phosphorus (formed under high pressures). Phosphates are indispensable as fertilizer, but less desirable in washing agents as the waste water is too concentrated with this substance (eutrophication). It has a rich chemistry, is the basis for powerful insecticides, but also for warfare agents. A versatile element. [Pg.40]

ASTM D3933-98 Standard practice for preparation of aluminum surfaces for structural adhesive bonding (phosphoric acid anodizing). [Pg.285]

The structures of phosphoric and phosphorus acid are shown in Figure 11.17 and again, in greater detail, in Figures 16.5a and 16.6a, respectively. Besides its one P=0 bond (involving a formal dir—pTr bond), phosphoric acid, H3PO4, has three hydroxyl hydrogen atoms (or P—O—H units) and is therefore triprotic. (Recall the discussion... [Pg.465]

Preparation of Aluminum Surfaces for Structural Adhesive Bonding (Phosphoric Acid Anodizing), Practice for (D 3933)... [Pg.421]

ASTM D 3933-80 Practice for Preparation of Aluminium Surfaces for Structural Adhesives Bonding (Phosphoric Acid Anodising). [Pg.380]

The O-S exchange method in presence of a-halogenated carbonyl compound is a very good one for thiazole compounds. The thioamide is prepared in situ by the action of amide upon phosphorus pentasulphide with solvent. The a-halogenated aldehyde reacts directly. But the O-Se exchange cannot be performed with a-halogenated carbonyl compounds because of the apparition of phosphoric acid. (Scheme 3), The C-Se bond is very sensitive to add pH. [Pg.220]

PhenylPhosphorothioa.te Esters. These are the most widely used OP iasecticides and iacorporate pseudoanhydride high energy phosphate bonds between phosphoric acid and phenols that are present ia the activated P=0 state. [Pg.281]

Extensive hydrogen bonding takes place in phosphoric acid solutions. In concentrated (86% H PO solutions, as well as in the crystal stmctures of the anhydrous acid and the hemihydrate, the tetrahedral H PO groups are linked by hydrogen bonding. At lower (75% H PO concentrations, the tetrahedra are hydrogen-bonded to the water lattice. Physical properties of phosphoric acid solutions of various concentrations are Hsted in Table 2 the vapor pressure of aqueous H PO solutions at various temperatures is given in Table 3. [Pg.325]

The tertiary metal phosphates are of the general formula MPO where M is B, Al, Ga, Fe, Mn, etc. The metal—oxygen bonds of these materials have considerable covalent character. The anhydrous salts are continuous three-dimensional networks analogous to the various polymorphic forms of siHca. Of limited commercial interest are the alurninum, boron, and iron phosphates. Boron phosphate [13308-51 -5] BPO, is produced by heating the reaction product of boric acid and phosphoric acid or by a dding H BO to H PO at room temperature, foUowed by crystallization from a solution containing >48% P205- Boron phosphate has limited use as a catalyst support, in ceramics, and in refractories. [Pg.335]

Curing. Some chemically bonded bricks requke some elevated heat treatment that is typically higher than the tempering process mentioned above, but less temperature than that requked to form ceramic bonds. One example is aluminosihcate brick bonded with phosphoric acid. A very strong... [Pg.31]

Phosphoric Acid Fuel Cell This type of fuel cell was developed in response to the industiy s desire to expand the natural-gas market. The electrolyte is 93 to 98 percent phosphoric acid contained in a matrix of silicon carbide. The electrodes consist of finely divided platinum or platinum alloys supported on carbon black and bonded with PTFE latex. The latter provides enough hydrophobicity to the electrodes to prevent flooding of the structure by the electrolyte. The carbon support of the air elec trode is specially formulated for oxidation resistance at 473 K (392°F) in air and positive potentials. [Pg.2412]

Rider and Amott were able to produce notable improvements in bond durability in comparison with simple abrasion pre-treatments. In some cases, the pretreatment improved joint durability to the level observed with the phosphoric acid anodizing process. The development of aluminum platelet structure in the outer film region combined with the hydrolytic stability of adhesive bonds made to the epoxy silane appear to be critical in developing the bond durability observed. XPS was particularly useful in determining the composition of fracture surfaces after failure as a function of boiling-water treatment time. A key feature of the treatment is that the adherend surface prepared in the boiling water be treated by the silane solution directly afterwards. Given the adherend is still wet before immersion in silane solution, the potential for atmospheric contamination is avoided. Rider and Amott have previously shown that such exposure is detrimental to bond durability. [Pg.427]

In primer formulations for adhesive bonding of metals, the coupling agents that are most frequently used are those based on epoxy and amine functionalities. Aqueous solutions of aminosilanes have been successfully used for obtaining stable adhesive bonds between epoxy and steel [10] and epoxy and titanium [11,12], while epoxy functional silanes are preferable for applications involving aluminum substrates [13,14], A simple solution of % epoxy functional silane in water is currently used for field repairs of military aircraft [15] where phosphoric acid anodization would be extremely difficult to carry out, and performance is deemed quite acceptable. [Pg.437]

Boeing Process Specification, BAC 5555 Issue M. Phosphoric acid anodizing of aluminum for structural bonding. Boeing Airplane Company, 1995. [Pg.463]

PAA. Phosphoric acid anodization (PAA) was developed by the Boeing Company in the late 1960s and early 1970s to improve the performance of bonded... [Pg.965]

See other pages where Bonds phosphoric acid is mentioned: [Pg.846]    [Pg.846]    [Pg.397]    [Pg.97]    [Pg.846]    [Pg.846]    [Pg.397]    [Pg.97]    [Pg.21]    [Pg.137]    [Pg.224]    [Pg.323]    [Pg.330]    [Pg.334]    [Pg.356]    [Pg.173]    [Pg.321]    [Pg.23]    [Pg.150]    [Pg.5]    [Pg.452]    [Pg.483]    [Pg.425]    [Pg.96]    [Pg.282]    [Pg.985]    [Pg.986]    [Pg.987]    [Pg.1144]   
See also in sourсe #XX -- [ Pg.122 ]



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Phosphoric acid derivatives, selective bond

Phosphoric acid hydrogen bonding

Phosphoric acid hydrogen-bonded complexes

Phosphoric acid—anhydrid bonds

Phosphoric acid—ester bonds

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