Horizontal adjustment Clause Samples
A horizontal adjustment clause allows for the modification of contract terms or pricing based on changes that occur across a group of similar contracts or projects, rather than adjustments tied to a single contract. In practice, this clause might be used in industries where multiple contracts are affected by the same external factors, such as changes in regulatory requirements or market-wide cost fluctuations. Its core function is to ensure consistency and fairness across related agreements, preventing discrepancies and disputes that could arise if only individual contracts were adjusted in isolation.
Horizontal adjustment the cut-off line shall be so positioned that the projected beam pattern appears approximately symmetrical to the V-V line. When the front fog lamp is designed for use in pairs or has otherwise an asymmetric beam pattern, it shall be horizontally aligned according to the specification of the applicant, or otherwise in such a way that the cut-off line appears symmetrical to the V-V line.
Horizontal adjustment the beam with the "cut-off" line shall be so positioned that the projected beam pattern appears approximately symmetrical to the V-V line.
Horizontal adjustment. The applicant shall specify one of the following horizontal aim methods:
(a) The "0.2 D line" method (see figure 2 below). A single horizontal line at 0.2° D shall be scanned from 5° left to 5° right after the lamp has been aimed vertically. The maximum gradient "G" determined using the formula G = (log Eβ – log E(β + 0.1°)) where β is the horizontal position in degrees, shall not be less than 0.08. V H H
Horizontal adjustment. The applicant shall specify one of the following horizontal aim methods:
(a) The "0.2 D line" method (see Figure A5-III). A single horizontal line at 0.2° D shall be scanned from 5° left to 5° right after the lamp has been aimed vertically. The maximum gradient "G" determined using the formula G = (log Eβ - log E(β + 0.1°)) where β is the horizontal position in degrees, shall not be less than 0.08. The inflection point found on the 0.2 D line shall be positioned on the line A. Figure A5-III Note: The scales are different for vertical and horizontal lines.
(b) The "3 line" method (see Figure A5-IV) Three vertical lines shall be scanned from 2° D to 2° U at 1°R, 2°R, and 3°R after the lamp has been aimed vertically. The respective maximum gradients "G" determined using the formula: G = (log Eβ – log E(β + 0.1°))
Horizontal adjustment. 2.3.2.1. Horizontal adjustment of passing-beam headlamp designed to provide asymmetric “cut-off” line The applicant shall specify one of the following horizontal aim methods:
(a) The "0.2°D line" method (see Figure A6-III). A single horizontal line at 0.2°D shall be scanned from 5° left to 5° right after the lamp has been aimed vertically. The maximum gradient "G" determined using the formula G = (log Eβ - log E(β + 0.1°)) where β is the horizontal position in degrees, shall not be less than 0.08. The inflection point found on the 0.2°D line shall be positioned on the line A. Figure A6-III Instrumental vertical and horizontal adjustment for asymmetric “cut-off” line- horizontal line scan method Note: The scales are different for vertical and horizontal lines.
(b) The "3 line" method (see Figure A5-IV) Three vertical lines shall be scanned from 2°D to 2°U at 1°R, 2°R, and 3°R after the lamp has been aimed vertically. The respective maximum gradients "G" determined using the formula: G = (log Eβ – log E(β + 0.1°))