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• 15935 Answers SOURCE: It appears your timer/main controller/CCU has failed in this instance. For replacement parts - head on over to PartSelect.com or RepairClinic.com and enter in your full model number for a full parts listing. I recommend both sites because. FixYa has no affiliation with either site - I have been using and recommending them for years - trouble free.
PartSelect has a great schematic database for locating the part on your unit and great 'testimonials' for each part that often times includes HOW-TO information. RepairClinic has pictures of each part they sell and also a great how-to and troubleshooting for basic repairs. If your unit has never been serviced - there should still be an original service manual enclosed in plastic taped to the inside of the shell. In the service manual are Error codes, maintenance procedures, and troubleshooting steps you can follow. Anything too complicated or beyond your scope should be handled by a professional.
If you think you want to tackle the repair - and have gotten stuck on a step - reply to your question and I will be glad to help you out. Thanks for using FixYa - a 4 THUMBS rating is appreciated for answering your FREE question!!!!!!!! Posted on Sep 16, 2010.
[Co(dmgBF 2) 2(H 2O) 2] 1 (where dmgBF 2 = difluoroboryldimethylglyoximato) was used to synthesize [Co(dmgBF 2) 2(H 2O)(py)]0.5(CH 3) 2CO 2 (where py = pyridine) in acetone. The formulation of complex 2 was confirmed by elemental analysis, high resolution MS, and various spectroscopic techniques. The complex [Co(dmgBF 2) 2(solv)(py)] (where solv = solvent) was readily formed in situ upon the addition of pyridine to complex 1. A spectrophotometric titration involving complex 1 and pyridine proved the formation of such a species, with formation constants, log K = 5.5, 5.1, 5.0, 4.4, and 3.1 in 2-butanone, dichloromethane, acetone, 1,2-difluorobenzene/acetone (4: 1, v/v), and acetonitrile, respectively, at 20 °C. In strongly coordinating solvents, such as acetonitrile, the lower magnitude of K along with cyclic voltammetry, NMR, and UV-visible spectroscopic measurements indicated extensive dissociation of the axial pyridine. In strongly coordinating solvents, [Co(dmgBF 2) 2(solv)(py)] can only be distinguished from [Co(dmgBF 2) 2(solv) 2] upon addition of an excess of pyridine, however, in weakly coordinating solvents the distinctions were apparent without the need for excess pyridine.
The coordination of pyridine to the cobalt(II) centre diminished the peak current at the E pc value of the Co I/0 redox couple, which was indicative of the relative position of the reaction equilibrium. Herein we report the first experimental and theoretical 59Co NMR spectroscopic data for the formation of Co(I) species of reduced cobaloximes in the presence and absence of py (and its derivatives) in CD 3CN.
From spectroelectrochemical studies, it was found that pyridine coordination to a cobalt(I) metal centre is more favourable than coordination to a cobalt(II) metal centre as evident by the larger formation constant, log K = 4.6 versus 3.1, respectively, in acetonitrile at 20 °C. The electrosynthesis of hydrogen by complexes 1 and 2 in various solvents demonstrated the dramatic effects of the axial ligand and the solvent on the turnover number of the respective catalyst. Introduction The production and use of clean, renewable and high-energy-density sources are growing in demand to circumvent the use of fossil fuels, thus reducing the effects of carbon dioxide emissions and global warming.
Hydrogen has been suggested as the leading candidate – and its production through the reduction of water appears to be a convenient solution for long-term storage and accessibility. Traditionally, noble metals of the platinum group metal series have been employed as catalytic centres in hydrogen production; – however, the high cost associated with these metals has led to searches for viable catalysts based on cheap and abundant first-row transition metals, such as nickel and cobalt.