EP2100124A1

EP2100124A1 - Method for high-pressure pulsation testing of machinery components

Info

Publication number: EP2100124A1
Application number: EP08701049A
Authority: EP
Inventors: Eberhard Schlücker
Original assignee: Friedrich Alexander Univeritaet Erlangen Nuernberg FAU
Current assignee: Friedrich Alexander Univeritaet Erlangen Nuernberg FAU
Priority date: 2007-01-12
Filing date: 2008-01-09
Publication date: 2009-09-16
Also published as: WO2008083961A1

Abstract

The invention relates to a method for high-pressure pulsation testing of machinery components in which, through the use of a pressurized liquid as a testing medium, the components are tested for fatigue under pulsed high pressure. According to said method, an ionic liquid is used as the test medium in the high-pressure pulsation test.

Description

Method for high-pressure pulsation testing of mechanical components

The invention relates to a method for high-pressure pulsation testing of mechanical components, in which the components are tested under pulsating high pressure for fatigue using a pressure fluid as a test medium, according to the preamble of claim 1.

Generally speaking, in mechanical engineering, it is increasingly necessary nowadays to test mechanical components for fatigue. This is done by means of various testing machines, for example, connecting rods, turbine blades, camshafts and the like. Be checked for fatigue.

For example, modern common-rail diesel technology also requires pressure pulsation tests in automotive engineering to test the relevant engine components, which are preferably hydraulic and use pressures of up to 2,200 bar.

The most commonly used technique is the hydraulic testing principle. Here, with the help of a rotating positive displacement pump, usually a gear pump, oil circulates under pressure and fed via controlled valves, depending on the desired test frequency, a pressure booster unit. Due to the circulation as well as the amount of oil involved in the compression, the efficiency of the testing machine is only between 30 and 40%. The achievable test frequencies are in the range up to about 15 Hz. The advantage of this technique is the wide frequency range and the Adjustability of load characteristics, such as sinusoidal shape, almost rectangular shape, Einzelhubabruf etc., as well as the possibility of load-oriented or wegorientierten driving style. The disadvantage here, as already mentioned, the low efficiency of the testing machine.

As a testing machines mechanically acting pulsators are also known. These are based on the principle of Geradschubkurbeltriebs, which is usually equipped for use with a Hubverstellsystem. The stroke and thus the pressure can be adjusted during operation. The advantage here is the efficiency, which is over 80%. The disadvantage, however, is that a load-oriented driving style is not possible.

Finally, so-called resonators are known as testing machines, in which the pulsation stroke is generated by spring-mass systems excited by unbalance motors. This technique has only recently been transferred to high pressure pulsation testing. The stroke and the force are hereby adjustable in a certain way. In addition, the efficiency is similar to that of the mechanically acting pulsators.

A disadvantage of all known pulsators, however, is to be considered that oil is used as the test medium. The test pressures reach values of up to 4,000 bar, and it is also desirable or intended to use test pressures of up to 6,000 bar. At such test pressures, the compressibility of the test medium is of great importance, since this determines the required displacement volume of the pulsator. However, since the oil used as the test medium still has a not insignificant compressibility, the performance of the respective pulsators is not yet completely satisfactory.

The invention is therefore based on the object to avoid these disadvantages to provide an improved method for Hochdruckpulsationsprüfung of mechanical components. The object is solved by the invention with the features of claim 1. Advantageous embodiments thereof are described in the further claims.

In the method according to the invention for high-pressure pulsation testing of mechanical components, in which the components are tested for fatigue under pulsating high pressure using a pressure fluid as the test medium, it is provided according to the invention that an ionic liquid or a mixture of ionic liquids is used as test medium in the high-pressure pulsation test.

In a further development of the invention is used as an ionic liquid such that has a low compressibility. In this case, the ionic liquid may also be added to a chemical additive to reduce its compressibility.

It is within the scope of the invention that the ionic liquid used is one which has a high temperature resistance. This may be, for example, a temperature resistance of at least 300 ° C.

In an embodiment of the invention it can be provided that either an organic ionic liquid and / or an inorganic ionic liquid or a mixture of these two liquids is used as the ionic liquid.

Finally, special advantages arise if the ionic liquid used as the high-pressure test medium is simultaneously allowed to act on two or more specimens.

Numerous surprising advantages are achieved by the invention.

Thus, due to the low compressibility of the ionic liquids used, the displacement volume of the testing machines is also great correspondingly lower. It can thus be tested with an existing machine either more components at the same time parallel or larger individual components. The lower compressibility of the ionic liquids used allows thus to extend the test with existing testing machines to larger components. Therefore, if not only a single component, but simultaneously two or more components are tested with a single testing machine, this means a reduced inspection effort, which represents a convincing economic advantage.

In addition, there is the fact that the reduction of the compressibility of the ionic liquid used is all the more effective, the more test liquid is simultaneously under pressure in the testing machine. This has an especially significant effect on hydraulic testing machines, since this, for example, increases the test frequency or makes the switching hydraulics more efficient.

As is apparent from Fig. 1, already exist some ionic fluids, which have about one-third of the compressibility of mineral oil. This is also clear with reference to FIG. 2, which shows the course of some Fördergradkurven depending on the delivery pressure. Here, by way of example only, the efficiency increase is shown on a hydraulic diaphragm pump, which results when using a low compressible ionic liquid.

It can thus, as already stated, be achieved by the use of ionic fluids as a test medium, a great economic advantage.

The ionic liquid [EMIM] [EtSO ₄ ], which is listed in third place in FIG. 1, has only one third of the compressibility of oil.

As already stated, further advantages result when the ionic liquid used is one which has a high temperature resistance. This is a typical mixture of lithium nitrate, potassium nitrate, Nitrite and residues of other ingredients. It can even be achieved with yet to be created ionic liquids of other types higher temperatures. Another advantage of the group of ionic liquids is their chemical inertness, so that hardly any attacks on materials are to be feared.

For the sake of comprehension, it should be stated at this point that the ionic liquids to be used according to the invention (lonic liquids = IL) are liquids which contain only ions. They are therefore liquid salts whose melting points are below, for example, 100.degree. Thus, ionic liquids should be understood as meaning substances which consist of cations and anions. In this case, mixtures of several cations and anions are possible.

In the application of the method according to the invention, the pressure build-up in a pulsator is approximately as follows: a) A loading system sets the piston working space under a boost pressure, which represents a lower pressure value. This piston working space is completely filled and has no gas bubbles. b) The mechanical components used as test specimens are connected to the piston working space. These are also completely filled and gas-free. c) The volume of the test specimen, the piston working space and possibly installed pipelines forms the compression volume V. d) The piston of the pulsator compresses this compression volume V until - set by the stroke volume (stroke x piston cross section) - the desired maximum test pressure is reached. Then the piston goes into his

Starting position back. Pressure fluid, which was lost as a leak via the piston seal, is supplemented by the charging system at the end of the return stroke. Due to the low compressibility of the ionic liquid used according to the invention, this results in a lower stroke or an achievable higher pressure. e) The usual piston movement follows a sinusoidal course. Here, the pressure amplitude follows from maximum pressure - boost pressure. A typical pressure level for the test of common-rail components is 3 000 bar At this pressure level, oil had a compressibility of 25 to 30%

Each test specimen must withstand a certain pressure amplitude at least 5 million load cycles Some test rules require 10 million load changes. This corresponds to a test run time of 11, 5 days or 24 hours at a test frequency of 10 Hz

Since the ionic liquids used according to the invention can also have a high temperature resistance, it is also possible to carry out the high pressure pulsation test at higher temperatures

In the case of high-pressure pulsation testing, there is also a tendency to test larger and larger components. Existing testing machines reach their limits when using oil as a test medium. These can now be exceeded when using ionic liquids as the test medium

Due to the achievable Kompressibihtatsreduktion of the reaching ionic liquid now, for example, two or more specimens in parallel - instead of only one specimen - to be examined Thus, either the use of a hitherto required further testing machine or there is only half of the test costs Instead, it is It also makes it possible to complete the test faster, so that the market release for the components concerned can be faster than before

The above-mentioned possibility of testing at higher temperatures finally offers the possibility of carrying out high-pressure tests at 600 ° C. and above. This makes it possible to test entire engine blocks at the typical high wall temperatures

Claims

claims:

1. A method for Hochdruckpulsationsprüfung of mechanical components, in which using a pressure fluid as a test medium, the components are tested under pulsating high pressure for fatigue, characterized in that an ionic liquid is used as the test medium in the Hochdruckpulsationsprüfung.

2. The method according to claim 1, characterized in that a mixture of ionic liquids is used as the ionic liquid.

3. The method according to claim 1 or 2, characterized in that the ionic liquid is added to a chemical additive for targeted modification of their property.

4. The method according to any one of the preceding claims, characterized in that is used as the ionic liquid such that has a low compressibility.

5. The method according to claim 4, characterized in that the test liquid is an ionic liquid with a chemical additive for reducing the compressibility is used.

6. The method according to any one of the preceding claims, characterized in that is used as the ionic liquid such that has a high temperature resistance.

7. The method according to claim 6, characterized in that is used as the ionic liquid is one which has a temperature resistance of at least 300 ° C.

8. The method according to any one of the preceding claims, characterized in that an organic ionic liquid is used as the ionic liquid.

9. The method according to any one of the preceding claims, characterized in that the ionic liquid is an inorganic ionic

Liquid is used.

10. The method according to any one of the preceding claims, characterized in that a mixture of organic and inorganic liquids is used as the ionic liquid.