DE2109594A1 - Moulding sand expansion testing - by heating preformed disc above photoelectric barrier - Google Patents

Abstract

The expansion behaviour of moulding sand is determined quantitatively by compressing a certain wt. of sand into a certain volume inside a ring. The ring is heated electrically or by a gas ring burner and the time elapsed until a shell of sand spalls off is measured by a photoelectric device.

Description

Method and device for the quantitative determination of the expansion behavior of foundry mold materials The invention relates to a method for quantitative determination the expansion behavior of foundry mold materials, especially molding sand, with the help of of a compacted test body, the invention consists in that a predetermined Weight amount of the molding sand or the like by pressure on a predetermined volume is compressed, the test specimen being picked up by a ring, which then by means of a ring burner) is heated until a school falls, under simultaneous measurement of that time from the introduction of the test body into the Heating zone passes by until the 'sling falls off.

The molding material to be tested is advantageous, Eg molding sand, compacted in the sample ring by an equal number of ramming blows or by an equal pressure over an equal period of time.

'An apparatus for carrying out the method now exists according to a proposal of the invention is that between an anvil and a sleeve Sample ring is inserted and a punch is guided in the sleeve, while for The sample ring is received in a sample holder above a ring burner with a burner nozzle is provided and below the ring burner a measuring device to record the time of the slag falling off, e.g. a light barrier, whereby electrical switching devices and a timepiece built into a base supporting the device parts are.

A design of the device according to the invention also provides that a column on the pedestal, e.g. 3. a steel tube, on which the light barrier is mounted and the ring burner are fixed, while a sample holder above the ring burner is provided, which can be pivoted by means of a lever. It is advantageous to equip the ring burner so that it alternates between 100 and ' 160 staggered Burner nozzles.

Finally, it is also advantageous to design the sample ring in such a way that that it narrows conically from its upper inner edge, while towards the lower Edge a conical extension adjoins. This ensures that the The surface layer that expands when heated is always towards the cone of the ring shuts down ..

The molds used in casting are naturally negative Castings to be produced by the casting process, whereby one forms from sand, clay and metal - generally used.'It is required of the form that it offers a high resistance to thermal and mechanical stress and remains as unchanged as possible in terms of its dimensions, so that it is true to the model and a flawless casting is obtained. But there with the casting of a metal the surface layers of the molds are strongly heated, forms, depending on Temperature and surface properties of the casting metal in these surface layers shape a temperature gradient. It is used as a casting mold material for various reasons predominantly sand is used, which mostly consists of a mixture of mainly Quartz sand with additives, the most outstanding additives being certain binders, Coal dust 'and water are to be mentioned.

Apart from the fact that every body expands when the temperature rises, A certain transformation will occur in many substances at elevated temperatures.

For example, quartz shows a change in specification at a temperature of around 5750 C. with which an abrupt expansion is connected, namely the transformation of K quartz in 5 quartz. But since the surface layers of a sand mold are not can expand freely, compressive stresses arise in the hot mold surface are caused by the expansion of the sand body. Through these tensions will be caused a number of casting defects, the so-called sand expansion defects, which then lead, for example, to the appearance of scabs, so you have to go to the foundry engaged be to choose the composition of the molding material so that the development of sand expansion defects is avoided as much as possible.

Whether a molding material tends to develop sand expansion defects, has been determined by test casts in the foundry for a long time. For this it was necessary to make various test castings, but it was always found that only It was possible to determine whether a sand forms faults or not, while a quantitative one Error measure could not be obtained in this way. It was therefore from W. Patterson and D. Boenisch a so-called compressive stress measuring machine and later Also a wet strength tester designed to use these two devices a quotient of the compressive stress to the tensile strength of a molding sand determine which is to be used as a measure of the tendency of the molding sand to fail. at these two devices are specially trained measuring devices, which consist of long parts and are particularly carefully adjusted and observed must be, so that they, especially in the very rough foundry operation, not very appear advantageous.

The H.G. Levelink described method for examining the Surface layers of a Xorm as well as that of Iaelink together with H. Schilders jointly developed processes give the desired and needed results not perfect. This is because Levelink proposed a flat, plane-parallel test specimen pressed into a cylindrical ring and this specimen then closed on one side Heat, the-cylindrical'ring -hinder the specimen from expanding target. The behavior and appearance the surface layer after the Temperature exposure 8011 can then be assessed. It is clear that such an evaluation may not provide accurate results.

But also the further procedure for determining the mechanical behavior of molding materials and molding material coatings at higher temperatures, the Levelink in common Using Schilders suggested does not give sufficient results because it will do so proposed to subject a test specimen to sudden heating in an oven, by placing it in an oven brought to a temperature of 14,000 C. became. At the same time, there should be an overpressure of nitrogen under the top layer to be assessed to rule. Now the pressure that is needed to make the top layer pop off let should be measured.

The object of the present invention is now to provide a method to create and an apparatus for performing the method that can be performed with simple Averages, within a short time, a measurement with comparable quantities at any time for the tendency of a molding material to develop errors ### ######### ## #####.

This object is achieved with the aid of the method according to the invention and the device created for it, because the fact that there is always the same sample volume within a sample ring, which is always achieved by the same compression work, one can assume the same conditions. Due to the special design of the specimen, a stress gradient builds up in the surface of the specimen, so that a sand bowl is created which, depending on the composition of the sand, sooner or later detaches from the specimen. The time, The VeE from the beginning of the temperature stress on the specimen to its detachment can be measured automatically or manually, for example with a stop watch.

Further features of the invention emerge from the following description an embodiment of a device in connection with the drawings and the demands.

It shows, in schematic sketches, Figures 1 and 2, the device for performing the method according to the invention, namely a device for manufacturing of the specimen as well as the device for determining the wrapping time and FIG. 3 a graph showing the influence of the binding content on the packing density sbwI'e to show the schülpzeit.

To produce the specimen, a sample ring 4 is on a Anvil 3 put on and then. in a sleeve 1 that fits on the ring 4 that previously weighed amount of sample material filled. This amount of sand depends on the sand composition, taking into account the final volume of the sand sample 5 should always be the same as compression.

This amount of sand filled loosely in the sleeve 1 is then with the help of a stamp 2 is compressed, with the different samples also being uniform should proceed, i.e. the compaction is carried out e.g. by three ramming strokes each time. The volume of such a specimen is e.g. 31 + 0.2 cm3.

It should be noted that the sample ring 4 is designed -'- that the surface layer, which expands when heated, always against the cone of the ring shears off. The sample ring 4 has a shoulder on its end face 13 provided, with the help of which the held in the opening 14 of a sample holder 6, n will. The sample holder-6 is mounted on a column 11 and can be adjusted with the help of the lever 12 can be pivoted. Below the sample holder 6 is a ring on the column 11 - burner 7 with burner nozzles 8 attached, which are alternately offset by 100 or 160 are. Below the ring burner is a measuring device; Record the point in time the falling of the scab arranged, z.3. B a light barrier 9, and 'in one Pedestal 10, which supports the column 11, are a timing device and electrical switching devices built-in.

The one produced in the sample ring 4 by the same compression work The test body is swiveled out into the opening 14 of the ring burner 7 Sample holder 6 used. Then when the flame of the burner is lit, will the plasma temperature, kept constant with the help of a pressure control of the compressed air. Now the sample holder 6 is pivoted over the flame of the burner 7, 8 and at the moment when the test specimen is centrally located above the burner briefly a circuit is closed and this pulse is used to relay a stopwatch to set in motion. As a result of the effect of temperature, the sample 5 a shell that falls off after a certain time and through the light barrier 9 must fall through. This becomes an impilis of the recipient the Photoelectric barrier triggered, which is then amplified accordingly and as an impulse for switching off the stopwatch is used. The time now read on the stopwatch is a characteristic for the expansion behavior of the examined molding material.

At the 30th International Foundry Congress in Prague was about a extensive investigation reported to the applicant and found that the packing density of the quartz grains of a test body is an essential parameter to describe defects caused by molding material. The packing density was used as g-quartz per cm3 of the sample defined.

FIG. 3 now shows the influence of the binder content on the packing density shown in a curve table. The parameter is that with the device described determined Schülpzeie "s" entered.

As can be seen, the lines of the same schooling times "s" run hyperbolic.

The curve board was set up when bentonite was used as a binder. The binder is in parts by weight of bentonite (G.B.) on the abscissa, the packing is dense the quartz grains in g quartz / cm3, (P.Q.) shown on the ordinate. The compression work expressed by the number of rams (A.d.R.), in the curve sheet for two, three, five, six and nine ramming strokes.

Description of previous results: Influence of the binder content in constant number of RammschläRe The illustration shows that with increasing Binder content (G.B.) the packing density of the quartz grains is reduced and the peeling time is increased will. In the case of mixtures with an insufficient proportion of binder, the addition of bentonite is effective with regard to the development time and packing density of the mixture. For the area investigated, a certain addition of bentonite is the schülp time The higher the bentonite level in the mixture, the more effective it can influence lies.

2) Influence of compaction on the pumping time with a constant bentonite content With increasing compaction work (A.d.R.) and / with a comparable proportion of binder in the mixture increases the tendency to scuff. It also shows that the compaction work on "lean" and "fat" sands of different strengths Has influence. If you change the compression work by a certain amount, so the schülpseit of a rich mixture is influenced more than that of a mixture with only an insufficient proportion of binder. 3) Accuracy of the method The spread is the single word. based on the corresponding mean value and expressed as a percentage been (variance). The variance of the test procedure is t 7.5%; 95 ffi all Individual values are in the range + 14% of the mean.

Claims (1)

Claims , 1) 'Method for the quantitative determination of the expansion behavior of foundry mold materials, especially Pormsand, with the help of a compacted Test body, characterized in that a predetermined amount by weight of the molding sand or the like. by pressure on a predetermined volume. is compressed, the test specimen being received by a ring which is then heated by means of a ring burner) until a school drops, while at the same time measuring the time that has elapsed from the introduction of the test body passes into the heating zone until the scab falls off, 2) method according to claim 1, characterized in that the molding material to be tested, e.g. Pormsand, -in the Test ring by an equal number of ramming blows or by an equally large one Pressure is compressed over an equal period of time. 3) Device for performing the method according to claim 1 and 2, characterized in that a sample ring (4) is inserted between an anvil (3) and a sleeve (1) and a punch (2) is guided in the sleeve (1) , while a sample holder @ (6) above a ring burner (7) with burner nozzles (-8) is provided to hold the sample ring (4) and, below the ring burner, a measuring device to record the time when the school dropped out, e.g. a light barrier ( 9), being electrical Switching devices and a timing device are installed in a base (10) carrying the Yorrichtungsteile (6, 7, 9). 4) Device according to claim 3, characterized in that on the Pedestal (10) a column (11), e.g. 3. a steel tube is mounted on which the 'light barrier (9) and the ring burner (7) are fixed, while above the ring burner the Sample holder (6) is attached as an arm which can be pivoted by means of a lever (12). 5) Apparatus according to claim 3 and 4, characterized in that the ring burner (7) with 3 nozzle nozzles alternately offset by 100 or 160, for example is equipped. 6) Device according to claim 3, characterized in that the sample ring (4) narrows conically from an upper inner edge, while towards the lower Edge a conical extension adjoins. Blank page