DE3734502C2 - - Google Patents

Description

The invention relates to a hardness testing machine comprising a weight column with stacked weights, which protrude at least with one radially outward Projection are provided with angular displacement of the projections consecutive weights, a load selector for Uncouple part of the weight of the weight column with at least one arranged in the area of the projections, bar running parallel to the weight column axis radially inward projecting names and with a Swivel device for swiveling the weight column and bar relative to each other about the weight column axis, where one of the Take-away noses under one of the projections then decoupling the one bearing this projection Weights as well as the weights resting on this weight.

A hardness testing machine of this type is known (e.g. in DE-OS 35 33 991). A disadvantage of this known arrangement is that the maximum number of individual weights is limited. The new claim 1 goes according to his The generic term continues from CH-PS 3 96 456  however also readable on DE-OS 35 33 991. Disadvantageous these two known arrangements is that with these the maximum number of individual weights is limited because in Trap two strips, radial from the individual weights outwardly projecting two projections each lengthways one that extends over an angle of almost 180 °, a helix following an arc are to be arranged and if the number of projections is too large, the angular distance from one another the following protrusions are not large enough to the two strips running parallel to the housing axis to be able to be differentiated with certainty. To with one single device the variety of measurement methods common today with the required fine weight gradation weight stack should be one accordingly have a large number of individual weights, for example up to twenty. The well-known arrangement, the shows 6-7 individual weights in the embodiment is for such a high number of weights is unsuitable.

The invention has for its object a hardness test machine of the type mentioned above improve that with a simple construction for an increased Number of individual weights is suitable.

This object is achieved in that the bar little at least two consecutive in the longitudinal direction Ledge sections each with a series of entrainment nose has that the ledge sections rigidly together which are connected with mutual angular displacement of the Driving noses of different groin sections that the Ledge sections around a common one, for weight columns axis parallel axis of rotation are rotatably mounted, and that by rotating the bar either one of the Ledge sections in the area of the projections and the remaining strip sections from the area of the projections are movable out.  

Depending on the number of bar sections, one can Multiple of the maximum number of single pieces possible up to now weights are used - when divided into two Strip sections, for example, double the number. There only a single strip section in the area the protrusions protrude, the protrusions (e.g. Pins) of the different bar sections assigned individual weights in the direction Align with each other parallel to the weight column axis. For the arrangement of the pins of a strip section assigned individual weights is the full screws line curve (in the case of two strips over almost 180 °) to Available. Simple construction of the device is guaranteed performs because the bar is only rotated accordingly must be to either one of the ledge sections of the Bring the bar into function.

When arranging the bar on a swivel frame preferably provided that the bar on the swing frame is rotatably mounted. This solution helps reduce of construction costs.

The rotary movement of the bar sections or the bar can be carried out by a separate rotary drive. You can save this, however, if the bar with at least one switching projection protruding outwards is provided, which with a first pivoting movement of the Swing frame beyond a switch pivot position strikes a stop part and the bar from one rotated first rotational position into a second rotational position. This arrangement also has the decisive one Advantage that the switching of the bar automatically takes place, so not by the operator must be triggered, for example by Actuation of a separate switching element. In the gradual weight adjustment by appropriate Rotation of the swivel frame is exceeded when the  Switching swivel position automatically rotates the bar, so that the next inguinal section to take effect is coming.

You get an automatic reset of the bar when the bar is provided with a second switching projection, the one with a pivoting movement of the frame in to the first Swinging movement in the opposite direction in the area Switching pivot position strikes the stop part and the Bar twisted from the second to the first rotary position.

For easy fixation of the bar in the respective Rotational positions are proposed that a Rasteinrich device for the bar in predetermined rotational positions is provided.

For simple construction and reliable function of the load voter also contributes if this, according to a continuation education of the invention, comprises a handwheel, which before preferably via a toothed belt with the swivel frame is coupled.

The invention is in the following preferred Ausfüh Examples explained.

It shows:

Figure 1 is a side view of the load selector of a first embodiment of a hardness testing machine according to the invention.

Fig. 2 is a section along line II-II in Fig. 1;

Fig. 3 is an isomentric simplified and partially broken view of the load selector of a second embodiment and

Fig. 4 shows a section according to line IV-IV in Fig. 3.

In FIG. 1 can be seen a weight column 10 and designated generally by 12 a simplified load selector shown. Weight column and load selector are part of a conventional hardness testing machine, not shown, as this can correspond to their structure, for example, CH-PS 3 96 456 or FR-PS 9 16 869. The structure must be supplemented accordingly.

The weight column 10 consists of a series of Ge weights 14 , which lie one above the other on a weight plate 16 , which in turn is attached to the lower end of a weight rod 18 . The weight rod 18 is shown broken off and accordingly extended to the top, with connection to a power transmission linkage for applying the desired test force to the test specimen. As well as Fig. 2, passes through the weight rod 18 central Durchgangsöff voltages 21 of the same cross-section having, failed benförmigen weights fourteenth With regard to the required high accuracy of the respective weight mass with the easiest possible manufacture, the simplest shape, namely that of a flat cylinder, is chosen for the weights.

When the test force is applied via the lever linkage not shown, the weight column 10 describes a downward movement. The load selector 12 now has the task of intervening in the weight column in such a way that the weights not currently required are picked up by the load selector during the downward movement and are supported on this. In this way, the test force is generated only by the other weights.

Each of the weights 14 is provided with two pins 20 serving as driving projections, which run in the radial direction and are inserted diametrically opposite one another with respect to the positions of the cylindrical outer circumference 24 of the respective weight 14 opposite the weight column axis 22 in corresponding radial bores. The pins of successive disks are offset from one another by the same angle. The pins 20 thus lie on two helical lines 28 on the outer circumference of the weight column 10 , the two helical lines running in the same direction, but being offset from one another by 180 °.

The load selector consists of a swivel frame 30 , the axis of rotation 32 of which coincides with the already mentioned axis 22 of the weight column 10 . The swivel frame 30 is formed by a lower horizontal leg 32 , an upper horizontal leg 34 and two, the respective legs connecting connecting, vertically extending strips 36 and 38 . A vertical pivot pin 39 is rotatably connected on the one hand to the lower horizontal leg 32 in the region of the center of the length of the leg and on the other hand rotatably mounted in a base plate 40 of the test machine housing, which is otherwise not shown. A handwheel 42 likewise rotatably mounted on the base plate 40 has a toothed belt pulley 44 . A toothed belt 46 connects this pulley 44 to a toothed belt pulley 48 mounted on the bearing shaft 32 so that it can rotate, so that the swivel frame 30 can be pivoted by rotating the handwheel 42 . A locking pin 50 attached to the base plate engages in predetermined pivoting positions of the pivot frame 30 in associated locking recesses 52 on the base plate 52 facing side 54 of the handwheel 42 in order to facilitate the approach to these predetermined pivoting positions and to make it difficult to accidentally pivot out of the respective pivoting position .

The upper horizontal leg 34 is provided in the region of its center length with a through opening 56 which is penetrated by the weight rod 18 .

The two strips 36 and 38 are designed like a comb, with a series of recesses 62 which are open in the radial direction towards the axis 22 and whose horizontal, upward-facing recess side can also be viewed as the upper side 64 of a projection (driving nose) 63 . The two strips 36 and 38 are, except for the other orientation, designed the same way, so that an upper side 64 of one of the two strips has a corresponding upper side 64 'on the other strip at the same height. The Ausnehumgtiefe and height is so matched to the pins 20 that they can penetrate unhindered into the recesses 62 , they remain in contact in Fig. 1 Darge rest position of the weight column 10 out of contact with the side surfaces of the recesses 62 . Due to the particularly clearly visible in Fig. 2 Win angular displacement of successive pins 20 and correspondingly narrow strips 36 and 38 in the circumferential direction, only the pair of pins of a single weight 14 engages in the two strips 36 , 38 .

If the weight column is then lowered from the rest position shown, the said pair of pins finally comes to rest on the relevant top 64 , 64 ', so that this weight is held by the two strips 36 , 38 when the weight column 10 is further lowered via the pair of pins. including the weights resting on the weight in question. Only the weights below half the weight fixed on the bars now burden the weight adjuster 16 . The latter weights thus determine the test force with which the workpiece to be tested is examined.

If the weight column 10 is raised again to the rest position after the test method has been carried out, the weights carried by the two strips 36 , 38 are carried along again in the course of the upward movement, so that the swivel frame 30 can be freely rotated to set a different test force.

The two indicated in Fig. 1 helical lines 28 , 28 ', along which the pins 20 of the pairs of pins of the weights 14 are arranged, can each extend at most within an angular range (in the projection of FIG. 2) from just below 180 ° to to avoid an overlap of the two in the projection of FIG. 2, ie an alignment of pins in the axially parallel direction of the two rows of pins along the lines 28 and 28 ' angeord Neten rows of pins. In the case of an alignment, two different weights would be lifted simultaneously by the bars 36 , 38 when the weight stack 10 was lowered, so that the test force level corresponding to the upper of these two weights could no longer be selected separately. Looking at example in FIGS . 2 and 3 of CH-PS 3 96 456, it can be seen that no more than eight or nine weights can be used there. The formation of the projections as relatively narrow pins according to the present FIGS. 1 and 2 allows the use of a larger number of weights, but this number is again limited.

With the large number of common test methods (Vickers, Brinell, Knoop, Grodzinsky, Rockwell) each with different test force levels, a large number of weights, for example over 20, are required in order to be able to carry out all test methods with one device. The second embodiment shown in simplified form in FIGS. 3 and 4 enables a corresponding increase in the number of weights. Components which correspond in function to those in FIGS . 1 and 2 are provided with the same reference numbers, each increased by the number 100 .

Only a single weight 114 of the weight column designated 110 is shown. The weight 114 is in turn provided with a pair of pins 120 which project radially outward from the cylindrical outer circumference 124 of the disk-shaped weight 114 at diametrically opposite locations. The weight rod passing through the central opening 121 of the weight 114 is omitted for the sake of simplicity. Only half of the swivel frame 130 is indicated.

You can see the upper horizontal leg 134 with through hole 156 for the weight rod and the lower horizontal leg 132 with a central receiving bore 135 for the omitted bearing pin for pivoting the pivot frame 130 on the housing. The vertical leg of the swivel frame 130 is now formed by a bolt 170 , the two ends of which are rigidly connected, in particular screwed, to the legs 132 and 134 . The bar 138 now consists of two differently shaped bar sections 172 , 174 . The strip 138 is rotatably mounted on the swivel frame 130 , which is indicated by bearing bolts 176 on both strip ends, which engage in corresponding bearing openings in the legs 132 and 134 , respectively. The bar 138 is movable between two rotational positions (movement arrow A ), a first of the two rotary positions being indicated in FIGS . 3 and 4 with a solid outline, and the second rotary position with a dotted outline in FIG. 3. For simple and automatic table switching between the two rotational positions in the course of the pivoting movement of the pivot frame 130 , the bar 138 is provided with two pin-shaped switching projections 180 , 182 , which cooperate with a stop 184 fixed to the housing, which in the illustrated embodiment has the shape of a vertically extending rod. A shorter rod is of course also sufficient for the function, only in the area of the switching projections 180 , 182 . A locking device (not shown) can be provided, in particular in the form of a spring-loaded locking ball, for example at the lower end of the bar 138 at a distance from the axis of rotation 186 of the bar 138 , which cooperates with locking recesses on the top of the lower horizontal leg 132 in the two rotational positions.

The two strip sections 172 , 174 differ in the orientation of their recesses 162 or the projections 163 with upper sides 164 adjoining each recess upwards and downwards for abutment on the pins 120 . While the projections 163 of the upper strip section 174 project in the first rotational position shown from the strip 138 in the direction of the axis 122 of the weight column 110 , the projections 163 of the lower strip section 172 are in a 90 ° in the projection of FIG Clockwise direction from the bar 138 (approximately in the circumferential direction with respect to the pivot axis 122 ). The pin-like switching projection 180 protrudes radially with respect to the axis 122 to the outside and the pin-like switching projection 182 again in the circumferential direction with respect to the pivot axis 122 , but opposite to the projections 163 of the lower section 172 .

The arrangement described makes it possible to optionally pivot one of the two strip sections 172 , 174 into the region of the pins 114 . The weight stack can therefore be divided into two weight stack sections, with each weight stack section being moderately assigned to one of the two strip sections 172 , 174 . Due to the arrangement made, it can no longer be ruled out that the pin pair of one weight of one weight stack section is aligned in the direction parallel to axis 122 with the pin pair of a weight of the other weight stack section. Each weight stack section can therefore be formed with so many weights that the two helical lines corresponding to the helical lines 28 , 28 'in FIG. 1 each include almost 180 ° in the projection of FIG. 2. The possible number of weights of the entire column 110 can therefore easily be doubled. If the strip 138 is further subdivided, for example into three strip sections offset by 120 ° from one another, there is the possibility of a corresponding multiplication (in the example: tripling) of the possible number of weights.

The two bars 138 must be switched over simultaneously. For this purpose, the design and arrangement of the opposite strip 138 (not shown in FIGS. 3 and 4) and the arrangement of the switching projection 184 can be point-symmetrical to the arrangement shown with respect to the axis 122 .

The arrangement described also ensures that the switching of the bar 138 takes place automatically in the course of the adjustment. Starting from a swivel position of the swivel frame 130 , in which none of the pins 120 is gripped, and the maximum weight is applied, the swivel frame 130 is swiveled in the direction of arrow C from weight level to weight level, provided that the screw direction of the screw lines 28 , 28 'of FIG corresponds. 1,. The bar 138 is in the Fig. 3 and 4 with a solid outline Darge presented first rotational position. To further reduce the test weight, the swivel frame 130 is rotated further and further until the pins of the lowermost weight of the upper weight column section come into engagement with the lowermost recess of the upper bar section 138 . During the subsequent further pivoting of the pivot frame 132 , the pin-like stop projection 180 abuts the stop part 184, with the result that, during the further pivoting movement of the pivot frame 132, the bar 138 is turned 90 ° counterclockwise by the stop part 184 in FIG. 1. The bar 138 now assumes the second rotational position indicated by dotted lines in FIG. 3. In this second rotational position, only the lower section 172 is in the area of the pins 114 . The weights of the lower weight column section can therefore be selected next. In order to obtain a seamless transition from one weight stack section to another, the helix of a weight stack section forms the continuation of a helix of the previous weight stack section.

The second switching projection shown in FIGS. 3 and 4 projects radially outwards in the second rotational position and therefore in turn strikes the stop part 184 when the pivot frame 132 is pivoted back towards the starting position, again in the region of the transition between the two weight column sections . In the course of the further pivoting movement, the strip 138 is turned back by the stop part 184 via the switching projection 182 into the first rotational position.

Claims (6)

1. Hardness testing machine, comprehensive

• a weight column with weights stacked on top of one another, which are provided with at least one radially outwardly projecting projection with angular displacement of the projections of successive weights,
• - A load selector for uncoupling a part of the weights of the weight column with at least one bar arranged in the area of the projections and running parallel to the weight column axis with radially inward projecting driving lugs and with a swivel device for swiveling movement of the weight column and bar relative to one another about the weight column axis, with selectable ones Swiveling positions each of the driving lugs engages under one of the projections, for the subsequent decoupling of the weight carrying this projection and the weights resting on this weight, characterized in that
• - that the strip ( 138 ) has at least two consecutive strip sections ( 172 , 174 ) in the longitudinal direction of the strip, each with a series of driving lugs ( 163 ),
• - That the strip sections ( 172 , 174 ) are rigidly connected to one another with mutual angular displacement of the driving lugs ( 163 ) of different strip sections ( 172 , 174 ),
• - That the strip sections ( 172 , 174 ) are rotatably mounted about a common axis of rotation ( 186 ) parallel to the weight column axis ( 122 ),
• - And that by rotating the bar ( 138 ) either one of the bar sections ( 172 , 174 ) in the area of the projections ( 120 ) and the remaining bar sections ( 174 , 172 ) from the area of the projections ( 120 ) can be moved out.

2. Hardness testing machine according to claim 1, wherein the bar ( 138 ) is arranged on a swivel frame ( 132 ), characterized in that the bar ( 138 ) on the swivel frame ( 132 ) is rotatably mounted. 3. Hardness testing machine according to claim 2, characterized in that the bar ( 138 ) is provided with at least one outwardly projecting switching projection ( 180 , 182 ) which, upon a first pivoting movement of the pivoting frame ( 132 ) via a switching pivoting position, to a stop part ( 184 ) stops and the bar ( 138 ) rotates from a first rotational position into a second rotational position. 4. Hardness testing machine according to claim 3, characterized in that the bar is provided with a second switching projection ( 182 ) which strikes with a pivoting movement of the frame ( 132 ) in the direction opposite to the first pivoting movement in the region of the switchover pivoting position on the stop part ( 184 ) and rotates the bar ( 138 ) from the second to the first rotational position. 5. Hardness testing machine according to one of the preceding claims, characterized by a latching device for the bar ( 138 ) in predetermined rotational positions. 6. hardness testing machine according to one of claims 2 to 5, wherein the load selector ( 12 ) comprises a handwheel ( 42 ) which is coupled to the swivel frame ( 30 ), characterized by a handwheel ( 42 ) with the swivel frame ( 30 ) coupling toothed belt ( 46 ).