DE1648533B2 - Portable device for testing the pill tendency of substances - Google Patents

Description

The present invention relates to a portable device for testing the pill tendency of Substances that have a friction disc that can be rotated by the motor and gear train, recessed in the depressions which separate individual friction surface areas from one another, as well as one consisting of a plate Material underlay, which on the one hand in the work

Beitsbereich of the friction disc forms a raised base and on the other hand with an annular groove is provided, through which the fabric with the help of a counterpart engaging in the groove on the base is clamped.

Various devices for pilling testing of substances are already known, which are devices with a friction surface or drum devices.

A known fixed device for testing the pill tendency of substances has a back gear and a disc-shaped friction element driven by a motor. A material underlay of the device in the form of a plate has a raised base and an annular groove in the working area of the friction disk, through which the material is attached to the material underlay with the aid of a counterpart that engages in the groove. The fibers pulled from the swatch by the friction material tend to cling to the threads of the fabric friction material, gradually losing contact with the swatch of the friction surface as a result of the picking up of the pulled fibers. It is therefore not possible to use the friction surface over a longer period of time without significant changes being noticeable in the condition of the surface. When replacing the friction surface, it is necessary to partially dismantle the fixed device.

In a further known device for determining the wear resistance of textiles with a friction disk which is rotatable about an axis of a drive shaft mounted in a bracket, there is a fixed connection between the hill and a Kieuz slide, which has a support upper part and lower part. The back and forth movement of the two support parts is brought about by an eccentric seated on a hollow shaft which interacts with at least one of the support parts perpendicular to the drive shaft, such a movement parallel to the guidance of the support lower part and perpendicular to the guidance of the support upper part and to the shaft or a circular movement around the axis of the hollow shaft depending on the position of the two support parts and the eccentric to each other. Above all, compound movements in the form of loops that are created by superimposing several movements are not possible.

It is the object of the present invention to provide a portable device with which on Reason for the anoidisation of the movement sequence of the The parts of the substance to be tested that determine the friction disc are exposed to a wide variety of friction movements can be. In addition, the device is designed to pull out fibers without wear of the fabric and a direct test on the fabric without cutting off a test piece must become.

This object is achieved according to the invention by the measures mentioned in claim 1 above solved.

Due to the resulting new structure of the mobile and portable device for the piling test of fabrics, the fabric sample can be clamped without having to cut the sample from the associated, complete piece or the ready-made article. Because the housing of the device, on which the motor, the intermediate transmission and the friction disc are attached, can be easily removed, the friction disc can be easily accessed and thus replaced quickly. As a result of the new movement paths, the friction surface itself no longer acts as an abrasive to determine the wear and tear of the material, but moves mechanically when fibers with weak cohesion are pulled out.

Further details of the present invention are explained in more detail using the exemplary embodiment shown in the drawing. It shows

F i g. 1 is a schematic elevation section of a device according to the invention,

F i g. 2 a plan view of the friction surface,

F i g. 3 an elevation de. Friction surface, partly in section along the line HI-IU in FIG. 2,

4 shows a vertical section of a detail of the friction surface and

F i g. 5 is a perspective view of a part outer working surface of the friction surface.

From Fig. 1 shows that the mobile or portable device for the pilling test on fabrics consists of a removable cylindrical housing 1 on which an electric motor 2, a transmission mechanism 3 and a friction surface 4 are mounted. The untce end of the housing 1 rests on a base 5 which, on the one hand, has a cylindrical part 6 of low height in its center, which is raised against the inside of the housing 1 and that of the support of a to be tested Fabric part 7 is used. On the other hand, the base 5 has an annular groove 8 on the circumference, in which the lower end of the housing 1 engages. The fabric 7 is held on the support surface 6 that A piece of fabric is clamped in the groove 8 between the edge of the housing 1 and the groove.

The motor 2 is arranged in a cylindrical opening 9 in the central upper part of the housing 1. A drive shaft 10 is provided with a pinion 11, which is connected to a gear 12 of the transmission mechanism 3 combs.

The transmission mechanism comprises three pairs of gears 2, 13 and 14, 15 and 16, 17, which sit on the shafts 18, 19 and 20 which advance parallel to the drive shaft 10. They are frictionally connected to a cage 21 located inside the housing 1 and are arranged to be rotatable about an axis coinciding with the drive shaft 10. A pinion 11 is located inside the cage and sits on the shaft 10. Above the cage 21 is a gear? '. arranged coaxially with the drive shaft IO, which is firmly connected to the housing 1 and which is connected to a small gear 23 of a gear pair 23, 24, which is keyed on a connecting shaft 25. The shaft 25 is mounted in a shoulder 26 of the cage 21. The large tame ad 24 acts on the small gear 17 of the third gear pair 16, 17, of which the large gear 16 cooperates with the small gear 15 of the second gear pair 14, 15 mounted on the shaft 19 coaxial with the drive shaft 10. The large wheel 14 receives its drive from the small wheel 13 of the first pair of gears 12, 13. Two identical eccentrics 27 are present, each of which is on one in the shoulder 29 of the cage 21

stored shaft 28 is seated below the cage 21. The rotation of the pinion II is due to the ineindem other end protruding through the cage of the other meshing of the gears 12, 13, 14, 30 and the Shaft 29 is a gear 30, which reciprocates with eccentric 27 in a straight line the gear 14 meshes. The eccentrics are converted into motion. At the same time will with respect to the central axis of the housing 1, the cage 5 through the interaction of the wheels 11, 17, 22, 24, Figs 21 and the drive shaft 10 diametrically opposite 25 of the cage 21 and the guideways 32 and 33 over and are intended to alternate on one on the organ 31 a slow rotation around the Control member 31 of the friction surface 4 to act. Axis of the device (or shafts 10 and 19) This organ is movable and is applied in a straight line, because the gear 22 cannot move leads and follows this rotate in a horizontal plane io and consequently the wheel 23 rolls on his two guide tracks 32, 33, which depend on the lower circumference and thus acts via the shaft 25 to form a surface of the cage 21 in a plane that is on the rotary back.

Pass the axis of the cage and at the same distance. The friction surface 4 is shown in FIG. 1 in one of their ex-

voltage from this axis are provided. Treme positions with respect to axes 10 and 19

In order to simplify the drawing, FIG. 15 shows the device, the other extreme position

F i g. 1 only a single eccentric 27 is shown and the friction surface is shown by dashed lines

den, and shafts 17, 18 and 25 and the corresponding.

The relevant organs are shown in the same planes, as shown in FIGS. 2 and 5 can be seen in detail

like that of the axes of the shafts 10, 19 and 28, the friction surface 4 consists of the disc 37,

specified. In reality, the shafts 17, 18 20 which are in the middle of their upper part with the an

and 25 displaced at an angle, for example by 90 °, drive shaft 38 is provided and at its lower

for space for the second, not shown eccentric part with a friction equipment 42. This equipment

ter 27 to let. 42 is removable and is preferably made of plastic

The rotatable cage 21 rests under the intermediate formwork table: m material and places one in front of the disk 37

tion of a bearing 35 on an inner annular as frustoconical shape, which is in a cylindrical

Shoulder 34 of the housing 1 and is laterally merged by the form and in a beaded edge 43

a second bearing 36 is guided, which ends between the lateral. It goes without saying that the internal form

The walls of the cage 21 711m on the one hand and the equipment 42 on the other hand, in each case by the external shape

Ren of the housing 1 is switched. the disk 37 is specified.

The friction surface 4 consists of a disk 37, which becomes the effective part of the friction equipment 42

ren edge is curved upwards and a variety of small surface pieces 48

drive shaft 38, which can move axially, but is shown opposite that of small square prisms 44

Rotation secured to the control member 31 exist, which are separated from one another by gaps 45

is. which are separated and at their upper ends by a

The control member 31 consists on the one hand of a 35 connecting bed 46 connected to one another.
Wheel hub 39, in the opening of which the shaft 38 is guided axially on the upper surface of the equipment in front of the friction surface 4, with a nose 47, not shown, going through a nose that is presented in the disk into an axial groove 40 of the shaft 38 Opening through to engage slipping and thereby prevent any rotation of the same in.

with respect to the organ 31 prevented and on the other hand 40 The effective part of the equipment 42 is at its

from two laterally aligned \ ηηεη 41, the nem circumference of a convex edge or groove

are fastened on both sides to the hub 39 and both 49 are limited.

freely in their corresponding guideway 32, 33 The equipment 42 can also be provided with basic work glides and alternately with one of the eccentric surfaces 48 with a different shape.
27 work together. Thanks to this arrangement, the structure of the effective surface, which is applied by the friction surface to the fabric 7 only by its own interstices, and leads to the weight of the surface piece, enables the realization of the first fabric Superimposed movement, which is composed of slight changes in pressure on the fibers and in front of a straight shift and a three-dimensional relaxation of the fibers and thus the reproduction. 50 availability of the pilling states.

K'erzu 1 sheet of drawings

Claims (9)

Patent claims: 1. A portable device for testing the pill tendency of substances, which has a friction disc rotatable by the motor and the back gear, in which recesses are cut out, which separate individual friction surface areas from one another, as well as a material underlay consisting of a plate, which on the one hand is in the working area of the friction disc forms a raised base and on the other hand is provided with an annular groove, by means of which the material is clamped on the base with the aid of a counterpart engaging in the groove, characterized in that the plate having the groove (8) has the base plate (S) of the device, the counterpart engaging the groove (8) being a housing (1) which can be removed from the base plate (S). on which the motor (2), the ao countershaft (3) and the friction disc (4) are attached, that the countershaft (3) has a plurality of interacting gears (11, 12, 13, 14, 15, 16, 17, 24 ; enclosing cage (21) which is connected to it in a drive manner and is rotatably mounted in the housing (1) and which is arranged on its underside with a friction disk shaft (38) which is axially parallel ^{to its axis of rotation with respect to the 1st housing (1).} is connected in the direction of rotation, and that the Reibscheibenschaft (38) on the K? ^f ig (21) forcibly guided in at least approximately radial direction with respect to the cage axis through a bearing on the cage (21) drive (27) is reciprocally movable. 2. Apparatus according to claim 1, characterized in that the cage (21) by means of a to its axis of rotation axially parallel and arranged on its underside wheel hub (39) with the Friction disc shaft (38) is positively connected in the direction of rotation, which is in the wheel hub (39) axially movable, but is rotatably mounted with respect to this. 3. Apparatus according to claim 2, characterized in that the wheel hub (39) in both sides the latter arranged in a stationary manner on the cage (21) and perpendicular to the axis of rotation of the cage standing plane lying guides (32, 33) is mounted and the drive for reciprocating movement of the friction disk shaft (38) in the radial direction by two in the extension of the Guides (32, 33) opposing each other and arranged in the cage (21) gear wheels (10 to 17 and 24) driven, acting in opposite directions and alternately on the wheel hub (39) Eccentric (27) is formed, which is provided at the same distance from the axis of rotation of the cage (21) are. 4. Device according to at least one of claims 2 and 3, characterized in that the Wheel hub (39) on both sides cantilevered, aligned arms (41) which in the Guides (32, 33) are stored and each with ;, one of the two eccentrics (27) cooperate in a non-positive manner. 5. Device according to at least one of claims 3 and 4, characterized in that the central plane of the guides (32, 33) and the arms (41) of the wheel hub (39) and the cage axis lie in one plane. 6. The device according to one or more of claims 1 to S, characterized in that the countershaft (3) three on the motor shaft (10) parallel shafts (18, 19, 20) wedged and interacting with each other Za! wheel pairs (JU, 13, 14, 15, 16, 17) and the cage (21) surrounding the gear wheel pairs and rotatably mounted in the housing (1), one (79) of the shafts (18, 19) supported in the cage (21) , 20) * o how a ring gear (22) attached to the housing (1) is arranged coaxially to the motor shaft (10) and the axis of rotation of the cage (21) and a small gear (13, JS) each of the first and second of the cage ( 21) mounted gear pairs (13 to 17) meshes with the corresponding large gear (14, 16) of the adjacent second or third gear pair (14, 15, 16, 17) and that the large gear (12) of the first gear pair (12 , 13) with the pinion (11) of the motor shaft (10) and the small gear (17) of the third gear pair (16, 17) with the large gear (24) of a gear pair (23, 24) keyed on a connecting shaft (25) mesh, the connecting shaft (25) being mounted in the cage (21), penetrating this on one side and a small gear wheel at the end lying outside the cage (21) (23) which meshes with the ring gear (22). 7. The device according to at least one of claims 1 to 6, characterized in that im Cage (21) two to the motor shaft (10) parallel in the central plane of the guides (32, J3) and on both sides of the same lying shafts (28) are mounted, each of which on inside the cage lying end one with the large gear (14) of the second arranged coaxially to the motor shaft (10) Gear pair (14, 15) meshing gear (30) and lying outside the cage The end of the eccentric (27) acting on the wheel hub (39). 8. Apparatus according to claim 1, characterized in that the in Ro-bfläche areas (48) subdivided friction disc (4) can be detachably attached to a friction disc holder (37), with a rim bead (43) protruding radially inward at the upper end, the friction disc holder (37) and by means of a surface facing away from the friction surface protruding and in a recess of the friction disc holder (37) engaging nose (47) with respect to the latter against Rotation is secured. 9. Apparatus according to claim 8, characterized in that the friction surface areas (48) the friction disc (4) formed by the end faces of a number of small square prisms (44) are.