DE10105793A1 - Method for evaluating the quality of a lubricant, uses measured values detected online for the lubricant's absorption and transmission properties in respect of infrared radiation while utilizing two spectral areas for evaluation - Google Patents

Abstract

A wavelength is used to show transmission values of infrared light for three different oil samples. A curve shown as a thick line shows transmission values for a fresh oil in an engine of minimum running power. A curve shown as a thin line shows the same oil after a running time of 250 hours. A curve shown as a dotted line shows transmission values for a used oil after 250 hours of running time for the oil but after a total engine running time of 500 hours.

Description

The invention relates to a method for evaluating the lubricant quality, preferably for lubricating oils of motor vehicles, according to the preamble of claim 1.

Methods for evaluating the lubricant quality are generally known, the Lubricant quality-characteristic parameters from the transmission or absorption of infrared light from the lubricant. Such methods are e.g. B. known from the document DE 32 12 734 A1.

DE 196 50 397.3 A1 describes a method for determining the Degrees of wear of oil described with the help of absorption of infrared radiation. to Evaluation uses a wavelength of 10.3 µm, in which the degradation necessary components contained in the fresh oil is detectable. To form a an absolute value independent evaluation value becomes a further absorption value at a Wavelength of 9.7 µm measured and a comparison of the absorption values Evaluation size calculated. In both spectral ranges there are measured values that characteristic of fresh oil components are used for evaluation. An interference the oil quality due to aging products, water or fuel input is affected by the Rating not recorded.

It is also previously known from the isolated detection of one contained in the oil Aging product to make an assessment of the lubricating oil quality. So z. B. in US 5,049,742 describes a process in which the proportion of nitrate esters determined from the transmission of the lubricating oil in the spectral range of 6.7 µm this aging product is inferred about the quality of the lubricating oil.

Furthermore, a method is known from US 4,649,711 in which the transmission of the Lubricating oil in the spectral range between 9.7 and 10.3 µm is used.

The methods according to the prior art each evaluate this separately Presence of aging products or fresh oil components. Their even  However, evaluation over the entire life of the engine leads to incorrect evaluations. In particular, the remaining components in the engine each time the oil is changed influence the transmission / absorption of the fresh oil.

Another problem with evaluating oil quality in rigid spectral ranges is that different oil qualities are characteristic in different spectral ranges Have characteristics for aging or fresh oil components. A safe assessment of the oil regardless of the oil quality is not guaranteed with the known methods.

The invention has for its object a method for evaluating lubricants to create, with measured values for its absorption or transmission of Infrared radiation in the spectral range for aging products and fresh oil components are equally used to form a quality criterion for oil quality.

Advantageously according to the invention, the respective absorption or Transmission value of the infrared light for different spectral ranges with different weighting, the influence of which in the respective spectral range measured component on the oil quality.

In an advantageous development of the invention, a reference measurement according to the Filling the fresh oil triggered on the basis of relevant spectral ranges for the Measurement determined and at the same time reference values are formed for their assessment. It can thus influence different oil qualities on the evaluation result can be reduced. It is possible to use quantitative reference values and / or to form measuring ranges for the evaluation of the fresh oil.

This task is performed in procedures for evaluating lubricants according to the Preamble according to the invention through the characterizing features of patent claims 1 and 5 solved.

Further advantageous embodiments of the invention are in the embodiment and in the Subclaims shown.

Further details of the invention are shown schematically in the drawing with reference to FIG illustrated embodiments described.  

Here shows:

Fig. 1 a diagram showing the transmission values of a fresh oil, as well as two used oils same oil quality every 250 hours of running time in dependence on the wavelength,

Fig. 2 shows the influence of registered in the oil water to the transmission in the spectral range between a wave number of 3000 cm ^-1 and 4000 cm ^-1.

Fig. 1, the transmission values is a diagram showing infrared light for 3 different oil samples as a function of wavelength. Curve 1 (heavily drawn) shows the transmission values for a fresh oil in an engine with minimal mileage. Curve 2 shows the same oil after a running time of 250 hours (thinly drawn). Curve 3 shows the transmission values of a used oil after 250 hours of running the oil, but after a total running time of the engine of 500 hours (shown in broken lines). Although both used oils have the same oil retention times, their transmission values are different. The remaining components in the engine after an oil change affect the oil quality of the fresh oil. In particular, the measurable fresh oil components are influenced by the remaining components.

The blackening of the oil is a characteristic evaluation parameter. This parameter can be measured in the entire spectral range. It is preferably measured for the motor oil used at a wavelength of 2000 cm ^-1 . The blackening is heavily weighted in the process according to the invention when forming an overall evaluation for the oil quality.

Various characteristic measuring ranges can be identified for the oil quality used. It is known that in the range between 1650 cm ^-1 and 1790 cm ^-1 , carboxylic acid fractions formed by the nitration, as well as ketones between 1650 cm ^-1 and 1780 cm ^-1 and aldehydes between 1645 cm ^-1 and 1765 cm ^-1 are.

The intensity of the development of these aging products is strongly dependent on the condition of the oil. There are strong peaks for both used oils with wave numbers of 1620 cm ^-1 and 1720 cm ^-1 . These can be assessed using the baseline method. The evaluation of the peaks independent of the basic value of the curve allows a quantitative statement even with different total running times of the engine.

The measured values for nitrates and acids with wave numbers in the range between 1610 cm ^-1 and 1625 cm ^-1 are included in the overall evaluation according to the invention with a higher weighting than that of other oxidation products.

The influence of the fuel entered on the oil quality can be seen in the example used with a wave number of 760 cm ^-1 . It goes into the assessment according to the invention with a lower weighting than the water input and the blackening.

The fresh oil components which can be measured in the spectral range between wave numbers of 900 cm ^-1 and 1500 cm ^-1 are included with the lowest weighting in the evaluation criterion according to the invention. A pronounced peak can be seen for the fresh oil quality used with a wave number of 960 cm ^-1, which cannot be measured for the used oils after 250 h and 500 h total engine running time. The baseline method is used again for the evaluation, whereby the height of the peak is evaluated in relation to the further course of the curve.

In a possible embodiment of the evaluation method according to the invention, the absolute measured values of transmission / absorption of the oil in characteristic spectral ranges for fresh oil components (wave number 900-1000 cm ^-1 ), oxidation products (wave number 1650-1750 cm ^-1 ), water input (3200-3600 cm ^-1 ), Fuel input (wave number 760 cm ^-1 ) and for nitrates and acids (1620 cm ^-1 ) added. An evaluation quantity for the oil quality is formed from the overall evaluation. The ratio of the weightings can be flexibly adapted to the type of engine, sensor system and evaluation platform used. A possible evaluation variant is the formation of a total, whereby the proportions, the water input and the nitrates and acids contained are each weighted by a factor of 3, the oxidation products and the fuel input by a factor of 2, and the fresh oil components. The sum thus obtained represents a measure of the performance properties of the oil. Threshold values can be formed for individual components, preferably for the components to be heavily weighted, in which, for. B. in the event of a fault, the oil is rated as used up in the event of a greatly increased water input.

Fig. 2 shows the transmission of infrared light in the spectral range between wavenumber 3000 cm ^-1 and 4600 cm ^-1 . In the spectral range between 3200 cm ^-1 and 3600 cm ^-1 , a clear weakening of the transmission for a used oil (heavily underlined) can be seen, which is due to a water input.

The present invention should not be based on the foregoing Embodiments are limited, but can be in many other directions be modified without departing from the spirit of the invention.

Claims (7)

1. Method for evaluating the quality of a lubricant by means of preferably online measurements for its absorption or transmission properties with respect to infrared radiation, at least two characteristic spectral ranges being used for the evaluation, characterized in that the spectral ranges each consist of at least one characteristic band for im contains unused lubricant, components that are consumed by the aging of the oil and a characteristic band for the aging products that arise in the oil, the overall assessment of the lubricant quality being formed from a joint assessment of both measured variables. 2. The method according to claim 1 characterized, that in addition a measured value in one for registered foreign substances such as water and / or fuel characteristic spectral range to form the Overall assessment of the lubricant quality is used. 3. The method according to claim 1 characterized, that the measured values for aging products being formed are weighted higher than the ingredients in the fresh oil. 4. The method according to claim 2 characterized, that for the evaluation, the measured values of those caused by nitration and acids Aging products, and the measured value from the characteristic for the water entry Band highest, the measured values of the bands for oxidation products and Lower fuel input and the measured values for those that are consumed in the fresh oil Components are least weighted. 5. Method for evaluating the quality of a lubricant, preferably by means of Measured values determined online for its absorption or transmission properties with respect to infrared radiation, with at least two characteristic ones Spectral ranges are used for evaluation,  characterized, that the unused lubricant is analyzed and from the result characteristic spectral ranges for assessing the state of consumption to be selected. 6. The method according to claim 5 characterized, that the spectral ranges selected for assessing the state of consumption according to the result of the analysis of the unused lubricant, from a Number of specifiable spectral ranges characteristic of different oil qualities he follows. 7. The method according to any one of the preceding claims characterized, that quantitative statements on oil quality in the spectral range in question can be made using the Baseline method can be obtained.