DE10107034B4 - Device for extending the chemical life of a filter medium - Google Patents

Abstract

Device for extending the chemical service life of a filter medium which is arranged in an oil circuit of an internal combustion engine, the oil being passed through a component arranged in the oil flow, and the component containing substances which are capable of nitrogen oxides or reaction products which are harmful to the filter medium chemically decomposing and / or binding nitrogen oxides, water and combustion residues from fuels from the oil stream, the substances being chemically bound to an impregnation of the component and the connection to the impregnation being realized by introducing a condensable chemical group into the impregnation substance, the impregnation is phenolic resin or acrylate.

Description

Field of the invention

The present invention relates generally to oil filter systems. It relates in particular to those filter systems which are used in the filtration of engine oils of gasoline engines. More particularly, the invention relates to a device for extending the life of such filter systems according to the claims.

Background of the Invention, Prior Art

Oil performs a number of important tasks in internal combustion engines. The engine lubricating oil reduces the friction and thus the wear of metallic components, dissipates heat, seals the combustion chamber and cleans the engine compartment by removing and dispersing impurities. Engine oils are thus contaminated during operation by combustion particles, foreign substances and abrasion particles. So that these so-called primary particles no damage in the engine, z. B. cause by blocking of lubrication gaps or on the generation of Sekundärverschleißpartikeln, which can lead to a reduction in engine life, these particles must be removed from the oil circuit.

The most widely used method of controlling such contaminants is the use of a mainstream filtration system. In such a system, oil that is moved by a pump will pass through a filter before being directed to the individual machine components. This ensures that all the oil is subjected to at least minimum filtration. However, such a mainstream system always compromises the ability of the oil to flow through the filter media and the filter's ability to remove particulate matter.

In a mainstream filtration system, particulate contaminants are removed from the oil by depth filtration. The arrangement of fibers in the filter medium results in openings or passages through which the oil can flow. In this case, particles that are larger than these openings or passages are retained, while smaller particles can pass through them. Currently known mainstream oil filters generally exhibit a 90-95% removal rate of particles larger than 40 microns. Although this removal rate greatly reduces the possibility of catastrophic damage to the machine by the circulation of large particles, these filters provide minimal protection against wear. Studies have shown that most of the wear of machine components is caused by the circulation of particles in the range of 5-20 microns. This particle size is much smaller than that which a conventional mainstream filtration system can remove with significant effectiveness. Although a closer arrangement of the fibers in the filters can increase the efficiency of the removal of smaller particles can be achieved, but at this point comes the already mentioned compromise situation into play.

As the fiber density in the filters is increased, it is more difficult for the oil to flow through the filter. As the flow resistance increases, the flow volume and oil pressure decreases downstream. To compensate for this reduction, one could increase the surface area of the now denser filter. However, in order to obtain a corresponding pressure drop, comparable to conventional mainstream systems, and at the same time be able to achieve a sufficient filtration rate of particles in the range of 5-20 microns, the surface would have to be increased many times. In general, however, this is impractical from the point of view of size and cost.

In addition, especially in the automotive industry, the trend is towards smaller and smaller units while at the same time increasing oil flow rates due to the limited space available. In addition, these oils are exposed to operating conditions in modern cars that can lead to increased thermal or chemical damage.

One way to improve oil filtration is therefore to provide a second or bypass filtration system. Secondary flow filtration systems are used in addition to existing mainstream systems and differ from these in several respects. First, only a small portion of the output of the oil pump is directed to the bypass filter. The volume is normally between 5 and 10% of the total amount supplied to the components of the machine. After the oil has passed the bypass filter, it is returned to the machine. Due to the fact that the bypass filter does not process large flow rates, the tightness of the filter medium can be much greater. Not only does this allow improved removal efficiency for smaller particles, it also often allows the removal of other contaminants that are not retained by conventional mainstream filters.

A major problem with the filter media used today is that particularly in the combustion in the gasoline engine substances are formed that are particularly harmful to the filter media. These are z. For example, reactive chemical compounds such as acids that are made Combustion gases and water are formed (eg, nitrous acid), oxidation products of the fuel (eg, organic acids, alcohols, ketones and aldehydes), water, hydroperoxides, and their reaction products with each other. These components can be the filter medium, which consists mainly of cellulose and a suitable impregnation, by z. As acid hydrolysis, esterification, etherification or radical attack so far weaken that the mechanical strength of the medium is greatly reduced. However, a minimum strength is imperative due to the operational safety. These substances therefore drastically reduce the chemical life of the filter media.

A special role is played by the nitrogen oxides, which are generally designated NO _x . Some processes for denitrification have been developed, such. As the SCR (Selective Catalytic Reduction), a technique in which the exhaust gas stream ammonia (NH ₃ ) or urea (CO (NH ₂ ) ₂ ) is added. However, this method is mainly used in stationary systems. Conversion rates of up to 80% have become known, however, the NO content must be known, since an excessive addition of the reducing agent would lead to an ammonia emission. For example, it will open US 6077491 A and the JP 06126131 A directed.

From the pamphlets WO 96/02617 A1 . US 4997546 A . US 5225081 A . US 5478463 A and US 5042617 A Devices are known with substances which chemically bind or decompose harmful substances from lubricating oil. In particular, the describes US 5042617 A a filter paper which is treated with a dimethylsulfoxide solution of a diisocyanate and then with a solution of tetraethylene-pentamine.

Summary of the invention

Accordingly, it is an object of the present invention to provide a device which allows to increase the chemical life of filter media used in internal combustion engines of motor vehicles.

These and other objects are achieved by the device according to claim 1.

Further advantageous embodiments are contained in the subclaims.

Detailed description of the embodiment

By a detailed analysis of the aging reactions of waste oils, it is possible to identify the harmful for the filter medium compounds that are formed during the driving operation of the motor vehicle. These are similar to those that can be made harmless in the catalytic converter by urea. According to the invention are also reaction products of NO _x , water and combustion residues from fuels.

By using chemical substances in the oil circuit of internal combustion engines, which can chemically decompose or bind these pollutants, thus, the substances harmful to the filter medium can be removed from the oil stream.

These substances may, for. B. be introduced as bulk material in a main or Nebenstromölfilter or -bauelement. According to the invention, however, the addition of chemical compounds takes place in that the substance is chemically bound to the impregnation of the filter medium. According to the invention, this is done with frequently used Phenolharzimpragnierungen by introducing a condensable chemical group, eg. B. an alkylol group. Comparable solutions for acrylate as alternative impregnant according to the invention are conceivable analogously.

In principle suitable for binding and decomposition are substances, as u. a. also be used as support materials in chromatography, such as silica gel, diatomaceous earth, calcium carbonate and alumina. Furthermore, substances are suitable which make the pollutants harmless via adsorption and subsequent decomposition via acidic or basic functional groups, such as. B. zeolites. Furthermore, catalytically active substances, such as metals and metal compounds, for example metal oxides, are suitable. The selection of the (filling) substance is based on the chemical resistance of the pollutants to be destroyed. So z. B. acids from the combustion process by basic substances harmless. If these substances are used as bulk material in a component, the grain size must be so high that flooding into the oil circuit is reliably prevented. Useful are particle sizes from 10 microns, preferably in the range of 20-100 microns.

The device according to the invention allows an extension of the chemical life of filter materials used in gasoline engines. In order to guarantee the required mechanical strength of the filter medium at extended oil change intervals, the conventional cellulose is reinforced by the addition of synthetic fibers in modern filter materials, however, which leads to cost increases for these so-called mixed fiber media. By lowering the chemical load due to the thermal decomposition of the pollutants can be dispensed with these reinforcing fibers, so that cheaper filter media can be used.

Claims (5)

Apparatus for extending the chemical life of a filter medium disposed in an oil circuit of an internal combustion engine, wherein the oil is passed through a device arranged in the flow of oil, and wherein the device contains substances which are capable of harmful nitrogen oxides or reaction products for the filter medium Chemically decompose and / or bind from nitrogen oxides, water and combustion residues from fuels from the oil stream, wherein the substances are chemically bonded to an impregnation of the device and the connection to the impregnation is realized by the introduction of a condensable chemical group in the impregnation substance, wherein the impregnation is phenolic resin or acrylate. Apparatus according to claim 1, characterized in that the substances consist of substances which have acidic or basic functional groups. Apparatus according to claim 2, characterized in that the substances are catalytically active substances. Apparatus according to claim 3, characterized in that the catalytically active substances include metals and metal compounds. Device according to one of the preceding claims, characterized in that it is the chemical group is an alkylol group.