DE1162107B - Corrosion testing system - Google Patents

Description

Corrosion Testing System The invention relates to a system for testing the corrosion resistance of components. Such systems essentially exist from chambers in which the parts to be tested are those to be expected in use Environmental conditions, particularly with regard to temperature and humidity, exposed will.

When testing corrosion, it is particularly important to determine the value of the applied protective layers, such as galvanic coatings. Under use known devices such tests take a very long time.

They extend over periods of time from days to weeks or months. Such tests are to be used for quality control of ongoing production tedious because they cannot keep up with the production speed.

One has therefore switched to short test methods. These will be like this designed so that the components are resistant to attack by aggressive chemicals such as acetic acid, Exposed to saline solutions, sulfur dioxide, etc. Such an artificially induced one but increased attack on the surfaces to be tested gives test results, which depend very much on the type and amount of chemicals used. Comparable Results can only be obtained with difficulty because of the slight shifts the conditions can change the results significantly. Another disadvantage of this Method is that the artificial attack with the naturally occurring Attack is hardly comparable because other means are used in the test than those with the expected natural stress on the components act.

It is also known that the durability of surface protective layers also largely depends on the temperature fluctuations affecting them later. Therefore, devices have been proposed for performing a thermal cycling test can be carried out. During such tests, however, the components behave better than afterwards when actually used on the finished object.

This type of test is therefore not always satisfactory either Results.

The determination of the layer thickness, which is also sometimes used for determination the thickness of protective layers takes a lot of time. Besides, it doesn't bring any Provides information about defects that are present in other places on the layer.

With the known test methods it is also disadvantageous that only rarely a sufficiently large number of individual parts can be detected during quality monitoring can. So it is not possible to use an average value that is necessary for a reliable statement get.

In addition, it is disadvantageous that most of the known methods for Destruction of the applied protective coating, e.g. galvanic coating, on the components to be tested. This means either a post-processing of the checked Parts necessary, or their loss has to be accepted. It also became the testing of a larger average of components has hitherto been prevented.

According to the invention is a system for testing corrosion resistance of components in which the aforementioned disadvantages are avoided, characterized in that, that the support surface for the components to be tested means are assigned to this Surface or the components arranged on it at least briefly, preferably Maintain at a temperature below that temperature for 2 to 3 hours of the test room is that there is a condensation of moisture on the support surface or the components forms.

This rule according to the invention is based on the following findings: 1. Due to their small mass, the components to be tested have only a low heat capacity and can therefore quickly adapt to the respective ambient temperature. on In this way, no or only slight dew formation takes place on the components.

In the case of finished devices, however, the individual components are different Components associated and make such a complex bigger Heat capacity. A body with a larger heat capacity can, however, change external temperature do not follow as quickly as one with a small heat capacity. At a transition from low temperature to higher temperature the larger body becomes, d. H. the complex formed from several components, longer at a lower temperature linger as independent individual components that represent smaller bodies. So there will be stronger condensation on the surface of the complex.

However, the corrosion depends on the presence of the Condensation of condensation water that forms. Because the individual components are less fogged up than the parts built into devices, the individual components cut in the known Temperature change test performs better than its behavior on the finished object.

2. The lesson to be drawn from this is that the extent of corrosion of Components depends on the length of time over which they are at a temperature that is below room temperature. This length of time is decisive for the presence of moisture precipitation, which plays an important role in corrosion. For testing components under conditions that are adapted to those also occur in nature, it is therefore only necessary to extend the period that the independent components need to move from a lower temperature to the Temperature of the test room. Then it is also possible with the temperature change test of the components to achieve correct results.

It is already known to wash the components with water, for example by spraying, to wet.

However, this method has led to results that are similar to those of the later Experience on the finished object did not match. The reason for this is likely to be in the inevitable washing out and washing off of the surface when wetting. In the invention, however, washing out is avoided because the condensation water formed remains on the parts and dries slowly.

In the presence of a system according to the invention on the test parts Aggressive condensation water that has been precipitated and retained causes the corrosion processes on the coated parts, such as nickel-plated iron parts, quickly. Pores, polished Areas or other errors are already clearly visible after a few hours as brown rust spots. The test items can therefore in a short time, for example after 2 to 4 hours, assessed for their corrosion behavior through a simple visual inspection will. Another advantage is that the no parts exhibiting defects can be reused without reworking can because neither their appearance nor their strength has been changed during the test is.

A simple means of determining the temperature of the supporting surface or the components arranged thereon according to the invention at least briefly at one temperature to keep, which is below that of the test room, is that the Support surfaces for the components to be tested in connection with such a large mass be brought that they need the time required for condensation to to assume the higher temperature of the test room.

Such support surfaces are z. B. surfaces of large heat-storing Bodies that can consist of a metal such as brass. With these bodies which can be removed from the test room, the components to be tested are Cooling the body to room temperature or below, around 15 up to 200 C, e.g. B. connected by hanging up. Then these bodies become brought into the test room together with the test items. The test room is located at a higher temperature than room temperature. Also in the test room set a higher humidity. When introducing into the example at 40 ° C 90 90 ° / o air humidity in the test room so the surfaces will be condensation water on the components. In the specified way can be without great effort, even in simple air-conditioned rooms and in large chambers with a constant climate achieve condensation. The separation of condensation water continues as long as until the test parts have assumed the temperature of the test room.

Then the water on the parts begins to slowly dry off.

An embodiment of a support surface to be used according to the invention, in which a lowering of the temperature can be maintained over a longer period of time can is indicated by this. that the support surface is artificially cooled. Such cooling can for example by circulation cooling by means of water or be done electrically (Peltier effect). By temporarily interrupted cooling condensation or even condensation of the Test specimens are effected. It is not necessary to specify the requirements of the test items to be taken out of the test room before each test and brought to room temperature or to a temperature below room temperature, about 0 ° C. In this embodiment of the invention, the bearing surfaces can therefore be fixed in the test space to be installed. In addition, it is not necessary to make the bearing surfaces themselves large To give mass. Rather, it is sufficient, the edition z. B. a sleeve-like structure to be given through which a coolant, such as water, flows. A comparable one Effect can also be achieved if the coolant is directly below the actual, designed as a sheet metal support surface in a serpentine back and forth Pipe is guided.

An advantageous development of the invention is that those for testing screws, nails or other parts that have a pen, used support surfaces are provided with holes in which the pins, z. B. the threaded parts of the screws can be inserted. The holes are in the surfaces of the supports and should be adapted to test pieces by at least the diameter of these holes is dimensioned so that the pins of the test pieces Fit straight in so that there is good thermal contact. The support surfaces can also an assortment of boreholes with different sizes and depths exhibit.

This makes it possible, for. B. Various screws size to check at the same time. The test items, especially screws, are given this Type of attachment in very close proximity a thermal behavior that corresponds to the one corresponds to what is to be expected in natural use.

With the device according to the invention are also other parts, such as Sheet metal parts, testable. To test these parts, it is advantageous to check the contact surfaces so large that they are at least about the largest dimension of the test Parts correspond. The advantage of this training is simply that it does Most of the component to be tested is exposed to the action of condensation water will. To increase the thermal contact, it is also possible to change the surface shape of the Requirements to adapt the shape of the test objects, for example sheet metal parts.

Further features and details of the invention are in the description the embodiments shown in the drawing included. The drawing comprises in Fig. 1 the schematic, perspective diagram of an inventive designed corrosion testing system, shown in Fig. 2 partially broken away Heat storage body in which recesses for testing screws etc. are introduced are, in FIG. 3 a support in which a conduit for cooling water is provided is, and in Fig. 4 a support with a sleeve-like structure that of water as a coolant is flowed through.

The test room is located in the cabinet 1 shown in FIG. 1 2, which can be locked with door 3. For setting an even temperature A thermostat controlled by the contact thermometer 4 is provided in the room 2. The setting of the desired degree of humidity of the air in room 2 is carried out by Turn the switch 5.

The switch 5 activates an evaporation system. On the switchboard 6 there are still switches for actuating an approximately to be switched on Cooling device of a fan and also the indicator lights 7 and 8, which as Signals for the functioning of the device are used. The utilities for the test room 2, i.e. the thermostat, the air humidifier, etc. are located in the lower part of the cabinet behind the blind 9.

On the surfaces of the supports 10, 11, 12 and 13, which by means of Holders on the side walls of room 2 are the test items stored. The pads 10 and 11 are solid brass blocks with a length of 300 mm, a width of 80 mm and a thickness of 50 mm. The block 10 has in its support surface, i.e. its one broad side, 35 mm deep drill holes, in which screws 14, 14 a are inserted as test objects. The edition 11 owns a smooth surface on which a sheet 15 is placed for testing. the Edition 12 largely corresponds to edition 10. The main one The difference is that they have a cooling line 29 (Fi G. 3) for water contains. The cooling water is supplied by means of the two hoses 16, 17 through the feed-throughs 18, 19 provided in the side wall of the room 2 added or derived (cf.

F i g. 3). There are test objects on the cooled support 12 20 screws and rivets (see also Fig. 3). The edition 13, on which as Test ling the sheet metal 21 is located electrically through a cooling technology known Peltier element cooled. Power is supplied via the line 22, which through the passage 23 in one side wall of the cabinet 1 in the room 2 is led into it. When door 3 is closed, the test items are passed through the Window 24 can be observed through.

In Fig. 2, the support 10 is shown enlarged. At the broken corner, the drill hole 26 is visible in the fracture surface 25. The screw 14 a is inserted with its threaded part 27 in this borehole. The remaining screws 14 are inserted into drill holes, of which those marked 28 have remained free, so that only their heads can be seen on the surface of the support 10.

The application of an edition 10 or 11, i.e. one that only acts through the heat capacity of its mass, takes place in such a way that this Conditions 10, 11 can be removed from the test room 2 in the morning. After this they have reached room temperature (around 200 C), they will be with the in the evening samples to be tested, which are taken from the daily production, loaded and in introduced the test room 2. A temperature of 400 C prevails in test room 2 about 900/0 relative humidity. After inserting it begins to work on the screws 14 and to condense moisture on the sheet metal part 15 until the conditions 10 and 11 and the associated test items 14 and 15 show the test room temperature Have accepted. In the above-mentioned execution of the supports as brass blocks is the condensation water that precipitates on the parts long enough, about 2 hours, present on the specimens, so that the corrosion processes take place can. The flaws in the nickel-coated iron screws 14, 14 a can the next morning in a simple way as clearly visible brown rust spots to be identified.

The edition 12 is shown in FIG. 3 shown enlarged.

A part of the test objects 20 is omitted in order to trace the course of the cooling line 29 connected to the hoses 16, 17 and shown in dashed lines is to be able to represent clearly. Through the hose 16, which is attached to the connector 30 is infected, the cold water enters the cooling line29, which is in the lower Part of the edition 12 is a. From the nozzle 30, which is at one end of the one small narrow side of the support 12, the cooling line 29 leads along the one long narrow side and is then over the turns 31, 32 and 33 in the form of a M guided back and forth until it is again at the other end of the narrow side at nozzle 34 exit. The hose 17 through which the Water can drain away again. The M-like routing of the cooling line 29 is good cooling of the support 12 is achieved. The test items20, screws and rivets are inserted into the drilled holes in the upper part of the brass support 12, which correspond to those which are introduced in the support 10 (26 in FIG. 2).

The sleeve-like structure of the support 35, which is shown in FIG. 4 shown is made of 2 mm thick nickel-plated brass sheet. In the dashed lines Interior 36 of the sleeve is located, separated by baffles 37, 38 and 39, the M-shaped winding flow path for the cooling water. The cooling water will fed through the hose 41 attached to the connector 40 and flows through it the hose 43 attached to the connector 42 is removed again. The two nozzles 40. 42 are located at the two ends of a narrow longitudinal side 44 of the support 35. The baffles 37, 38 and 39 are arranged in the interior of the sleeve parallel to the small narrow sides and alternately only leave a passage for the Water free, thereby creating the M-like flow path in a manner known per se for the cooling water and good cooling. By inserting additional baffles more frequent turns of the flow path and thus an increased cooling effect be achieved.

The supports 12, 13 and 35 which can be cooled by coolant can be used as desired often and for any length of time at a lower temperature than that of the test room being held. The results achieved in the editions 10 and 11 are z. B. with editions 12 and 13 if these editions cool down to 15 takes place up to 200 C and is maintained for 2 hours.

The randomly coolable conditions make it possible to test the corrosion abbreviate. For this purpose z. B. the support surface 12, which is located in the at 400 C (at about 90 ° / o relative humidity) heated test room 2 is at a distance of 2 hours with water at about 140 C for 5 minutes each time. At this When designing the procedure, it is possible to make the assessment after 4 to 6 hours of the test objects to be carried out with sufficient certainty in most cases.

Claims: 1. System for testing the corrosion resistance of Components, characterized in that the support surface for the components to be tested Means are assigned to this area or the components arranged thereon at least briefly, preferably two to three hours at a temperature, which is so far below the temperature of the test room that it is on the contact surface or the components form a moisture deposit.

Claims (1)

2. Plant according to claim 1, characterized in that the bearing surface for the components to be tested can be removed from the device and such a large one Mass has that it needs the time required for condensation to reach the temperature of the test room to be accepted. 3. Plant according to claim 1, characterized in that the at least Brief lowering of the temperature of the support surface compared to the temperature of the Test room by artificial cooling of the support surface, for example by circulating cooling by means of water or by electrical means (Peltier effect). 4. Plant according to claim 1, characterized in that the bearing surface provided with drill holes for inserting the threaded part of screws and the like is. 5. Plant according to claim 1, characterized in that the bearing surface is chosen so large that it is at least about the largest dimension of the test Parts corresponds.