DE949155C - Process and device for determining the flowability of granular mass - Google Patents

Description

The invention relates to a method and a device for determining the flowability of granular Mass, especially foundry sand.

One can in accordance with the American Foundrymen's Society's Foundry Sand Handbook Define the flowability of granular mass as the property which enables it to create indentations to be filled in in the model and to move under pressure in every direction towards the model surface.

To determine the flowability of granular mass, in particular of foundry sand, the state the technology applied by various methods so far, z. B. Shatter test, sand flow test, measurement the sieving time, the Dietert and Valtier method, measurement of the hardness differential or the hardness gradient Kyles, Rowell method, measurement of ejection friction, method of repeated impact loading, Graphite line method according to Diran, Shaler, Taylor, extrusion method according to Lyssel Ash and others.

Some of these known methods, while providing useful results in themselves, have the essential Disadvantage that they do not provide information about the sand flowability directly, but only with it

Need to be interpreted using an invoice size. Also is the context of these procedures not obvious with the molding process.

With the elimination of these disadvantages, there is the

Invention in a method for determining the

Flowability of granular mass, with which one

dosed amount of the granular mass by means of certain

Compression energy to a detached body

shapes and its volume with that of a smooth,

ίο resemble bodies condensed with the same energy

Weight to achieve an index of flowability compares.

The invention provides a device for determining the flowability of granular mass Protection, in which the device used to produce the remote body of sand expanded below consists of a base, which encloses the extended part of the detached sand body, space and has a centering pin at the bottom, as well as a pipe section with a flange, which extends the Part closes up to the pipe diameter.

As a result of the measure, a separate form for

Using exam one achieves in more advantageous

Show a sensitive response of the measured values

the nature of the granular mass, i.e. a steeper curve of the measuring points.

In the drawings are schematically examples of

Test specimens in section as well as exemplary embodiments

of the device according to the invention for exercising the

Process of the invention illustrated. It shows

Fig. Ι a stepped piece of pipe on a base and in the same a stepped test body; Fig. 2 shows a body with the volume F ₀ des

cylindrical standardized test specimen and the

remaining annulus in the expanded pipe part;

Fig. 3 shows a detached body with the volume F ,,. for certain sand;

4 shows a settled body with the volume F ₁₀₀ with one hundred percent flowability of the sand;

5 shows an apparatus for carrying out the method with the omission of the representation of measurement marks and scales in elevation;

6 shows the same device with an insert sleeve. This procedure now consists in that a certain Amount of sand with the application of a certain compression energy to a settled Body is shaped. This separated body consists z. B. according to FIG. 1 from an upper part 1 smaller cross-section and a lower part 2 of larger cross-section. The procedure can also be carried out if the stepped sand body or the stepped shape has an upper part larger and one has the lower part of smaller cross-section. A cylindrical sleeve is used to shape the body 1, 2 with an enlarged, recessed part 4 which is placed on a base plate 5. In an expedient manner the molded part can be included in the pipe section 3 as an integral part to form the stepped part 2 will. This extension 4 corresponds to the mold 3 used to produce the body 1, 2 the indentation of a model. Depending on the flowability of a sand, it becomes more of a stepped shape or fill in less evenly. The volume of the compacted, settled body of sand is now compared with that of a smooth sand body, which has the same weight as the deposited one Body and has been condensed with the same energy, and its cross-section that of the upper one Part of the separated sand body corresponds. With perfect flowability of the sand, both would have Body the same volume, with flowability 0 in both cases a smooth body with identical Dimensions arise. The smooth, compacted sand body can be compared to the cylindrical, standard compacted Test specimens for determining permeability, compressive strength and shear strength.

According to the standards, the sand test is used to determine permeability, compressive strength and shear strength z. B. a cylindrical test specimen with 50 mm diameter and 50 mm height (or 2 " Diameter and 2 "height in USA. And GB.), Which in a pile driver of known design by three times Dropping a weight of 6670 g from a height of 50 mm »norm; is compressed (or 6350 g and 2 ").

This standardized test specimen is used as a reference specimen and the separated, e.g. B. cylindrical bodies with the same weight as the standard test body under the same conditions condensed. The stepped sand body or the stepped shape and the smooth sand body can also have a polygonal cross-section.

The dimensions of the detached body can be chosen, for example, so that with the same volume as the standardized test body, ie 98.2 cm ³ , the expanded part of the detached body has a volume of 49.6 cm ³ , ie about half of the total volume . For technical reasons it is advisable to set the height of the enlarged part at 10 mm, so that its diameter is 79.5 mm; there in FIG. 2: F ₀ = volume of the cylindrical, standardized test specimen plus remaining annular space in the enlarged part of the pipe; Fig. 3: V _x = volume of the settled body for certain sand; Fig. 4: F ₁₀₀ = volume of the deposited body with flowability 100 = volume of the standard compressed test body. The flowability is calculated according to the formula

- [(DIh ₁ + DIh ₀ ) - [DIh ₁ + D \ h _a ) J

- [[DIh ₁ + DIh ₀ ) (DIh ₁ + DIh ₁₀₀ )]

4 hg - h _x

100,

where A ₁ = height of the extended part 2 of _{the recessed body (= 10 mm), A 0} = height of the standardized test body - A ₁ (= 40 mm), A ₁₀₀ = height of the recessed body for certain sand i »5 - A ₁ (= 25 mm), h _x - height of the detached body

with flowability F - A ₁ , D ₁ - diameter of the extended part of the recessed body (= 79.5 mm) D ₂ = diameter of the standardized test body (= 50 mm). With the dimensions given above, this results in:

40 - A ₁

p -

100.

The amount 40 - _r h _x and thus also the size can be read directly from a height measuring device attached or attached to the pile driver.

That to carry out the determination of the sand flowability Device serving according to the method described above can expediently, as in FIG. 5 is shown to be executed. The base 6 has a centering pin 7 on its underside, which fits into a corresponding hole in the support plate of the pile driver, not shown, on his

Ao the top is a recess 8 with diameter D ₁ and height A ₁ and at least one clamping device is provided on its circumference. This clamping device preferably consists of a bolt 9 which is rotatably mounted in the base 6 parallel to its axis and which, in its cranked part, has a clamping screw, e.g. B. wing screw 10, but could also be designed as a radially pivotable clamping bracket or as a loose screw clamp or as a clamping ring with bayonet or screw lock.

The pipe 11 with diameter D ₂ is dimensioned so high that the amount of sand poured in, the weight of which corresponds to that of the standardized test specimen, can be accommodated in the enclosed space. At one end it has a flange 12 which fits into a recess 13 of the base 6 and which closes the recess 8 up to the diameter D ₂ . By means of the described clamping device 9, 10, the base 6 and the pipe section 11, 12 are held together and clamped and together form the mold for forming the separated sand body. An embodiment of the device in which the detached part is included in the pipe section (see Fig. 1) and where the base 5 has a flat top or in which the device is composed of more than two main pieces is well within the scope of the invention , as well as an embodiment in which the shape can be separated in a plane passing through the axis.

In Fig. 6 a variant is shown in which a sleeve 14 is provided. This sleeve will only leave it in the device when filling. Before starting the actual measurement and the pile driver actuated, this sleeve 14 is carefully removed from the apparatus. This sleeve ensures that the sand to be tested forms a cylindrical body as the starting point for the measurement. The determination of the sand flowability is now carried out as follows:

1. To determine the weight of the sand, a cylindrical, standardized test specimen is produced.

2. The appropriate amount of sand is poured into the separate mold and placed on the pile driver three pile-driving strokes compacted.

3. With the help of the height measuring device on the pile driver, the amount A ₀ - A ₃ . = Δ A as calibration quantity, possibly also the flowability read off directly or

Ah

the latter is calculated according to the formula F = · 100.

15th

Claims (16)

PATENT CLAIMS: ι. Method for determining the flowability of granular mass, characterized in that one dosed amount of the granular mass by means of certain compression energy to one forms a separate body and condenses its volume with that of a smooth body with the same energy Body of the same weight to achieve a. Comparing flowability index. 2. Device for performing the method according to claim 1, characterized in that the device used to produce the remote sand body (1,2), which is expanded below a base (5, 6) which encloses the enlarged part (2) of the separated sand body, Space (8) and below a centering pin (7) as well as a Rphrstück (11) with flange (12), which closes the extended part up to the pipe diameter. 3. The method according to claim 1, characterized in that that the flowability according to the formula F "-F _1C 100 is calculated. 4. The method according to claim 1, characterized in that (A ₀ - h _x ) = Δ A is used as a calibration variable, wherein h _{x is} the height of the upper part of the separated body. 5. The method according to claims 1, 3 and 4, characterized in that the separated sand body or the stepped shape has an upper part of smaller cross-section and a lower part having larger cross-section. 6. The method according to claims 1, 3 and 4, characterized in that the separated sand body or the stepped shape has an upper part of larger cross-section and a lower part having smaller cross-section. 7. The method according to claims 1, 3 to 6, characterized in that the cross section of the smooth sand body corresponds to the cross section of the upper part of the stepped sand body. 8. The method according to claims 1,3 to 7, characterized characterized in that the stepped sand body or the stepped shape and the smooth sand body have a cylindrical shape. 9. The method according to claims 1,3 to 7, characterized characterized in that the stepped sand body or the stepped shape and the smooth sand body have a polygonal cross-section. 10. The method according to claims 1, 3 to 9, characterized characterized in that the smooth, compacted sand body corresponds to the cylindrical, standardized compacted Test specimen for determining permeability, compressive strength and shear strength. 11. The method according to claims i, 3 to 10, characterized characterized in that the volume of the enlarged part of the settled, compacted Sand body is half the volume of the cylindrical, standardized test body. 12. Device according to claim 2, characterized in that that the pipe section (11) with the flange (12) by means of at least one clamping device (9,10) is held together positively with the base (6). 13. Device according to claim 2, characterized in that that the pipe section (11) with flange (12) inserted in a recess (13) in the base (6) is. 14. Device according to claim 2, characterized in that that the molded part to form the stepped part (2) in the pipe section (3) as with him integral part (4) is included. 15. Device according to claim 2, characterized in that that the device is equipped with an insertable sleeve (14) for filling. 16. Device according to claim 2, characterized in that that the smaller diameter of the stepped shape, expanded at the bottom, is 50 mm, the larger diameter is 79.5 mm and the height of the enlarged part of the pipe is 10 mm. 1 sheet of drawings O509 698/409 3.56 (609 609 9.56)