DE102015213826B4 - Compression test device and compression test method - Google Patents

Abstract

A compression test device (100) for performing compression tests on test objects (104), the compression test device (100) comprising a receptacle (102) for receiving a test object (104), the receptacle (102) comprising at least one support portion (124) for supporting the test object (104) in at least one support direction perpendicular to a compression direction (110), the compression test device (100) comprising at least one test object (104) having a test section (126) and one or more support sections (124) for supporting the test object ( 104) on at least one support section (124) of the receiving device (102), characterized in that the receiving device (102) comprises a viewing section (122) in which a test section (126) of the test object (104) in the assembled state, in particular at performing the compression test, is visually observable, and that the test object (104) in the test section (126) has a smaller material thickness (T) than the same spatial directions in the one or more support sections (124) in one or two spatial directions taken perpendicular to the compression direction (110).

Description

The present invention relates to a compression test device, in particular for carrying out examinations of test objects subjected to pressure.

The DE 10 2010 052 815 A1 , the DE 10 2011 055 953 B3 , the US 5,297,441 A , the DE 37 35 484 A1 , the DE 10 2008 050 652 A1 and the US 6,389,876 B1 disclose various apparatus and methods for material testing.

The object of the present invention is to provide a compression test device by means of which an object to be tested can be examined simply and reproducibly for its compression properties.

This object is achieved by a compression test device for performing compression tests on test objects according to claim 1.

By virtue of the fact that the compression test device comprises both a support section and a viewing section, preferably both a stable recording of the test object for carrying out reproducible examinations and a visual observation during the execution of the compression test can take place. In comparison to conventional, visually inaccessible compression test devices, this results in additional investigation possibilities.

It may be favorable if the test portion of the test object in the assembled state, in particular when performing the compression test, is supported at most on two sides, in particular only on one side, in one or more spatial directions perpendicular to the compression direction on the receiving device.

The spatial directions are arranged in particular perpendicular to each other.

The test portion of the test object is not supported in the assembled state, in particular when performing the compression test, preferably in two or three directions extending perpendicular to the compression direction, but preferably visually accessible, in particular completely freely accessible.

In this case, visual accessibility is to be understood in particular as meaning that light in the visible spectrum can reach the test object and be emitted and detected by it. Completely free accessibility is to be understood in particular as meaning that no barriers, not even transparent barriers, are provided which prevent direct contact with the test object in the visible section.

According to the invention, it is provided that the compression test device comprises at least one test object which comprises a test section and one or more support sections for supporting the test object on at least one support section of the receiving device.

The test section of the test object is preferably set back with respect to one or two directions running perpendicular to the compression direction, at least on one side, in particular two-sided or three-sided, relative to the one or more support sections.

In particular, it can be provided that the test section of the test object comprises one or more indentations or recesses, which extend in particular at least approximately completely over the test section of the test object along the compression direction.

It may be favorable if the test section of the test object comprises a recess or recess extending on three sides around the test object.

A recess and / or indentation extends in particular in a direction perpendicular to the compression direction plane on three sides around the test object.

Preferably, a recess and / or recess with respect to a plane taken perpendicular to the compression direction plane is formed substantially C-shaped.

It can be provided that the test section and the one or more support sections of the test object form at least one flat, continuous support surface of the test object.

A support surface of the test object is in particular a rear side of the test object.

The support surface preferably extends at least approximately over an entire length of the test object in a direction parallel to the compression direction.

It may be favorable if the support surface extends parallel to the compression direction, in particular extends parallel to the compression direction.

The support surface preferably extends in a plane which is parallel to the compression direction and perpendicular thereto.

The test object is in the assembled state, in particular when performing the compression test, preferably with the support surface on a supporting body of the receiving device.

The support body preferably extends beyond the one or more support sections and the test section of the test object with respect to the compression direction.

In particular, the support body extends from a support portion of the test object across the test portion of the test object to another support portion of the test object.

The support body is in particular continuous and / or continuous, so that the test object preferably rests continuously and / or uninterruptedly with its support surface on the support body.

It may be favorable if the test object can at least partially slide along the support body when the compression test is carried out.

In an embodiment of the invention, it can be provided that a longitudinal central axis of the test section of the test object extending parallel to the compression direction is offset parallel to a longitudinal central axis of the one or more support sections of the test object extending parallel to the compression direction.

The longitudinal central axis in particular passes through a geometric center or center of gravity in a plane taken perpendicular to the compression direction.

In particular, due to the at least one recess and / or indentation in the test section of the test object, preferably results in an offset longitudinal center plane.

The test object has a lower material thickness in one or two spatial directions taken perpendicular to the compression direction in the test section than in the same spatial directions in the one or more support sections.

The test object preferably has a sectionally constant material thickness.

The test section is preferably an area of minimum material thickness of the test object.

It can be advantageous if the test object between at least one support section and the test section comprises at least one transition region which tapers from the respective support section in the direction of the test section and / or which comprises one or more, in particular three, obliquely or curved to the compression direction surfaces ,

In particular, it can be provided that the at least one transition section tapers continuously and / or evenly and / or arcuately from the respective support sections in the direction of the test section.

It can be advantageous if the test object is substantially strip-shaped.

Under a strip-shaped test object is in particular an elongated flat element to understand.

A length taken along the compression direction is preferably at least approximately three times a width. A width is preferably at least about three times a thickness / depth.

It may be favorable if the test object is formed from a metallic material.

In particular, the test object is a metal strip.

The present invention further relates to a compression test method.

The invention is in this respect the task of providing a compression test method, by means of which an object to be tested is easily and reproducibly examined for its compression properties out.

This object is achieved by a compression test method for testing test objects for their compression properties according to claim 11.

The compression test method according to the invention preferably has one or more of the features and / or advantages described in connection with the compression test device according to the invention.

In particular, the compression test method is preferably practicable on the compression test apparatus.

It may be favorable if the test section is detected visually during the application of the pressure force by means of a camera device.

It may be advantageous if the test object is introduced as a single element in the receiving device and tested independently of other test objects.

The compression test device is thus preferably a single object test device.

Favorable may be one or more of the following dimensions:
The length of the test section taken along the compression direction is preferably between about three times and six times a material thickness in the support section of the test object.

A width of the test portion perpendicular to the compression direction is preferably between about 8 mm and about 12 mm.

A width in the support portion is preferably at least about 1.5 times and / or at most about 2.5 times the width of the test portion.

In particular, a lower support portion preferably has a length taken along the compression direction of between about 10 mm and 25 mm.

An indentation and / or recess for producing the test section preferably has a depth of at least approximately 5% and / or at most approximately 10% of a material thickness in the support section, in particular in a direction perpendicular to the support surface.

It may be favorable if the test object has a section projecting beyond the receiving device, which has, for example, a length taken parallel to the direction of compression between approximately 4 mm and approximately 8 mm. The maximum length of the free end is determined in particular by the Eulerian formula.

Further preferred features and / or advantages of the invention are the subject of the following description and the drawings of an embodiment.

In the drawings show:

1 a schematic perspective view of a compression test device;

2 a schematic plan view of a front of the compression test device 1 ;

3 a schematic section through the compression test device 1 along the line 3-3 in 2 ;

4 an enlarged view of the area IV in 3 ;

5 a schematic plan view of a front of a test object;

6 a schematic side view of the test object from 5 ;

7 an enlarged view of the area VII in 6 ;

8th a schematic side view of the test object to illustrate the introduction of force when performing a compression test; and

9 a schematic section perpendicular to the compression direction through the test object 8th in the area of a test section of the test object.

Identical or functionally equivalent elements are provided with the same reference numerals in all figures.

One in the 1 to 9 illustrated embodiment of a whole with 100 Specified compression test device is used in particular to perform material tests, for example, to obtain more detailed information about a deformation behavior of a material to be tested.

The compression test device 100 includes a receiving device 102 for receiving a test object 104 ,

The cradle 102 is in particular on a base plate 106 the compression test device 100 arranged.

Preferably, the receiving device comprises 102 a support body 108 , which on the base plate 106 arranged, in particular screwed, is and differs from the base plate 106 against a compression direction 110 the compression test device 100 extends away.

Furthermore, one or more sliding guide elements 112 , for example guide bars 114 , the compression test device 100 intended.

These sliding guide elements 112 are in particular by means of a screw device 116 on the support body 108 the cradle 102 fixable.

By means of the sliding guide elements 112 and the support body 108 is in particular a sliding guide device 118 the compression test device 100 educated.

The sliding guide device 118 in particular, serves the length of the compression direction 110 guided recording of the test object 104 ,

The test object 104 is in particular between the support body 108 on the one hand and the one or more sliding guide elements 112 on the other hand movable introduced.

The sliding guide device 118 is in particular a guide device 120 to guide the test object 104 when performing a compression test. In particular, by means of the guide device 120 an undesired evasive movement of the test object 104 in a deformation of the same avoidable.

The compression test device 100 preferably allows a visual observation of the test object 104 while performing a compression test.

This includes the compression test device 100 preferably a viewing section 122 ,

The sight section 122 is in particular between two Gleitführungselementen 112 educated.

As in particular from 4 shows, is the test object 104 preferably formed substantially strip-shaped. For example, the test object 104 a metal strip.

The test object 104 preferably comprises two support sections 124 between which a test section 126 of the test object 104 is arranged.

Especially in the mounted state of the compression test device 100 in which a test object 104 in the cradle 102 is received, are preferably a support portion 124 , the test section 126 and another support section 124 along the compression direction 110 arranged consecutively.

The test object 104 includes in particular a recess 128 which are substantially C-shaped in a direction perpendicular to the compression direction 110 extending plane around the test object 104 herumerstreckt.

By means of this indentation 128 is in particular the test section 126 of the test object 104 specified.

The test section 126 is thus preferably a region of lesser material thickness T, W.

One not with a dent 128 provided side of the test object 104 preferably forms a support surface 130 with which the test object 104 preferably continuous, flat and / or flat on the support body 108 the cradle 102 can be applied.

As in particular from 3 shows, is the test object 104 in the assembled state with its two support sections 124 between the sliding guide elements 112 and the support body 108 along the compression direction 110 movably guided. In the area of the test section 126 is the test object 104 however, preferably three-way freely accessible.

As in particular from the 5 to 7 indicates the test object 104 preferably two support sections 124 with different lengths D, H along the compression direction 110 on. A transition area 132 between the support sections 124 and the test section 126 is preferably rounded, in particular such that the material thickness (width W), starting from the test section 126 forming dent 128 up to the respective support section 124 steadily increasing.

It may be advantageous if in the respective transition region 132 provided rounding on the opposite sides, which with the indentation 128 are provided, larger (deeper) fails than in the support surface 130 opposite side of the test object 104 ,

As in particular the 5 to 7 can be seen, is a length L _{0 of} the test section 126 parallel to the compression direction 110 between about three times and six times a material thickness T in the region of a support section 124 ,

A perpendicular to the compression direction 110 and taken perpendicular to the material thickness T width W _{0 of} the test section 126 is preferably between about 8 mm and about 12 mm.

In the support sections 124 Preferably, the width W is between about 1.5 times and about 2.5 times the width W _{0 of} the test portion 126 intended.

An assembled state of the base plate 106 facing support section 124 of the test object 104 preferably has a direction parallel to the compression direction 110 taken length D between about 10 mm and about 25 mm.

A depth G of the indentation 128 in a direction perpendicular to the support surface 130 The direction taken is preferably between about 5% and about 10% of a material thickness T in the support section 124 ,

A length S on the receiving device 102 protruding portion of the test object 104 is preferably between about 4 mm and about 8 mm.

A length H of one of the base plate 106 turned away supporting section 124 of the test object 104 is preferably between about 14 mm and about 33 mm (including the free end with the length S).

The compression test device 100 works preferably as follows:
First, the test object 104 in the cradle 102 introduced and by means of Gleitführungselemente 112 the sliding guide device 118 movably recorded.

With an end 134 lies the test object 104 then on the base plate 106 at.

Another end 134 stands over the receiving device 102 in the compression direction 110 out.

At this (free) end 134 can be a pressure applicator 136 the compression test device 100 Attack to the compression test on the test object 104 perform.

The pressure applicator 136 this is done along the compression direction 110 in the direction of the base plate 106 moved, leaving the test object 104 is loaded on pressure. The two ends 134 are moved towards each other.

Due to the design of the test object 104 , in particular due to the indentation 128 formed test section 126 , results in a maximum load of the test object 104 in the area of the test section 126 ,

The special geometry of the test object 104 This leads to the fact that the test object 104 also in the area of the test section 126 Reliable to the support body 108 applies and in particular not deformed by unwanted folds.

This is especially due to the transition areas 132 guaranteed.

Like that 8th and 9 it can be seen lead the transition areas 132 namely, that in the test section 126 initiated forces the test section 126 fix in the original position. An evasion of the test section 126 due to the compressive forces actually acting in the direction of the support body 108 respectively. The supporting body 108 however, prevents just this evasion.

Despite the one-sided support of the test object 104 in the test section 126 Therefore, a reliable and reproducible material test can be performed while the test section 126 even visually (visually) accessible for visual monitoring.

LIST OF REFERENCE NUMBERS

100

Compression tester

102

cradle

104

test object

106

baseplate

108

support body

110

compression direction

112

sliding guide

114

Gleitführungsbalken

116

screwing

118

sliding guide

120

guiding device

122

overview section

124

support section

126

test section

128

indentation

130

support surface

132

Transition area

134

The End

136

pressure applicator

D

length

G

depth

H

length

L ₀

length

S

length

T

material thickness

W

width

W ₀

width

Claims (13)

Compression test device ( 100 ) for performing compression tests on test objects ( 104 ), wherein the compression test device ( 100 ) a receiving device ( 102 ) for receiving a test object ( 104 ), wherein the Receiving device ( 102 ) at least one support section ( 124 ) for supporting the test object ( 104 ) in at least one direction perpendicular to a compression direction ( 110 ) comprises the supporting direction, wherein the compression test device ( 100 ) at least one test object ( 104 ) comprising a test section ( 126 ) and one or more support sections ( 124 ) for supporting the test object ( 104 ) on at least one support section ( 124 ) of the receiving device ( 102 ), characterized in that the receiving device ( 102 ) a viewing section ( 122 ) in which a test section ( 126 ) of the test object ( 104 ) is visually observable in the assembled state, in particular when performing the compression test, and that the test object ( 104 ) in the test section ( 126 ) in one or two perpendicular to the compression direction ( 110 ) has a smaller material thickness (T) than with respect to the same spatial directions in the one or more support sections (FIG. 124 ). Compression test device ( 100 ) according to claim 1, characterized in that the test section ( 126 ) of the test object ( 104 ) in the mounted state, in particular when carrying out the compression test, at most on two sides, in particular only on one side, in one or more perpendicular to the compression direction ( 110 ) extending spatial directions on the receiving device ( 102 ) is supported. Compression test device ( 100 ) according to one of claims 1 or 2, characterized in that the test section ( 126 ) of the test object ( 104 ) in the mounted state, in particular when carrying out the compression test, in two or three directions perpendicular to the direction of compression ( 110 ) extending spatial directions not supported, but visually accessible, in particular completely freely accessible, is. Compression test device ( 100 ) according to one of claims 1 to 3, characterized in that the test section ( 126 ) of the test object ( 104 ) with respect to one or two perpendicular to the direction of compression ( 110 ) extending directions at least one-sided, in particular two-sided or three-sided, relative to the one or more support sections ( 124 ) is set back. Compression test device ( 100 ) according to one of claims 1 to 4, characterized in that the test section ( 126 ) and the one or more support sections ( 124 ) of the test object ( 104 ) at least one flat continuous support surface ( 130 ) of the test object ( 104 ) form. Compression test device ( 100 ) according to claim 5, characterized in that the support surface ( 130 ) parallel to the compression direction ( 110 ). Compression test device ( 100 ) according to one of claims 5 or 6, characterized in that the test object ( 104 ) in the assembled state, in particular when carrying out the compression test, with the support surface ( 130 ) flat on a support body ( 108 ) of the receiving device ( 102 ) is applied, wherein the supporting body ( 108 ) with respect to the compression direction ( 110 ) over the one or more support sections and the test section ( 126 ) of the test object ( 104 ) extends. Compression test device ( 100 ) according to one of claims 1 to 7, characterized in that a parallel to the direction of compression ( 110 ) extending longitudinal central axis of the test section ( 126 ) of the test object ( 104 ) is offset parallel to one another parallel to the compression direction ( 110 ) extending longitudinal central axis of the one or more support sections ( 124 ) of the test object ( 104 ). Compression test device ( 100 ) According to one of claims 1 to 8, characterized in that the test object ( 104 ) between at least one support section ( 124 ) and the test section ( 126 ) at least one transitional area ( 132 ) extending from the respective support section ( 124 ) in the direction of the test section ( 126 ) is tapered and / or which one or more, in particular three, obliquely or curved to the compression direction ( 110 ) comprises extending surfaces. Compression test device ( 100 ) according to one of claims 1 to 9, characterized in that the test object ( 104 ) is substantially strip-shaped and / or formed from a metallic material. Compression test method for testing test objects ( 104 ) on their compression properties, the compression test method comprising: - introducing a test object ( 104 ), which in a test section ( 126 ) in one or two perpendicular to the compression direction ( 110 ) has a smaller material thickness (T) than with respect to the same spatial directions in one or more support sections ( 124 ), in a receiving device ( 102 ) a compression test device ( 100 ), so that the test section ( 126 ) of the test object ( 104 ) is visually accessible and the one or more support sections ( 124 ) of the test object ( 104 ) on at least one support section ( 124 ) of the receiving device ( 102 ) are supported; Applying a compressive force on the test object 104 ) along a compression direction ( 110 ); - Observing the test section ( 126 ) of the test object ( 104 ) while applying the pressing force. Compression test method according to claim 11, characterized in that the test section ( 126 ) is visually detected during application of the pressing force by means of a camera device. Compression test method according to one of claims 11 or 12, characterized in that the test object ( 104 ) as a single element in the receiving device ( 102 ) and independently of other test objects ( 104 ) Is tested.

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