LABORATORY MILL

Abstract

A laboratory mill is shown and described with at least one oscillatably mounted grinding bowl holder for at least one grinding bowl and with at least one line for transporting a liquid or gaseous medium, the line having at least one compensating element for compensating relative movements between the grinding bowl holder and/or the grinding bowl and a stationary part of the laboratory mill. In accordance with the invention, a rigid compensating element is provided for compensating relative movements, wherein the compensating element is elastically deformed at least in regions during an oscillating movement of the grinding bowl holder and wherein the compensation of relative movements is effected free of parts of the compensating element connected to one another so as to be movable, in particular rotatable and/or pivotable, relative to one another and only by elastic deformation of the compensating element.

Claims

1. Laboratory A laboratory mill with at least one oscillatably mounted grinding bowl holder for at least one grinding bowl and with at least one line for transporting a liquid or gaseous medium, the line having at least one compensating element for compensating relative movements between the grinding bowl holder and/or the grinding bowl and a stationary part of the laboratory mill, wherein a compensating element is provided for compensating relative movements, wherein the compensating element is elastically deformed at least in regions during an oscillating movement of the grinding bowl holder and wherein the compensation of relative movements takes place free of parts of the compensating element which are connected to one another movably, in particular rotatably and/or pivotably, relative to one another.

2. The laboratory mill according to claim 1, wherein the compensating element is designed as a substantially rigid tubular body.

3. The laboratory mill according to claim 1, wherein the compensating element consists of metal, in particular of stainless steel or a light metal, such as aluminum, and/or wherein the compensating element consists of a material resistant to cold at temperatures of less than 150° C., in particular at temperatures of less than 190° C., and/or is resistant to cold for the transport of liquid nitrogen.

4. The laboratory mill according to claim 1, wherein the compensating element is designed or acts as a torsion spring.

5. The laboratory mill according to claim 1, wherein the line is designed over its entire length as a pipeline and the compensating element is a pipeline section of the line.

6. The laboratory mill according to claim 1, wherein the line is elastically deformed during an oscillating movement of the grinding bowl holder substantially only and/or predominantly in the region of the compensating element and wherein the deformation of the compensating element decreases in the direction towards a line end connected to the stationary part.

7. Laboratory A laboratory mill with at least one oscillatably mounted grinding bowl holder for at least one grinding bowl and with at least one line for transporting a liquid or gaseous medium, the line having at least one compensating element for compensating relative movements between the grinding bowl holder and/or the grinding bowl and a stationary part of the laboratory mill, wherein the line length of the line is increased by the compensating element compared with a line length in the case of rectilinear line guidance, and wherein the compensation of relative movements takes place free of parts of the compensating element which are connected to one another movably, in particular rotatably and/or pivotably, relative to one another.

8. The laboratory mill according to claim 7, wherein a ratio of the line length of the compensating element to the line length in the case of straight-line guidance is at least 5, further preferably at least 10.

9. The laboratory mill according to claim 1, wherein the compensating element has at least one curved and/or angled line section, wherein, preferably, the compensating element is designed as a helical line section or a line section designed in the form of a flat or spatial spiral.

10. The laboratory mill according to claim 1, wherein the grinding bowl holder and/or a grinding bowl is connected and/or connectable to at least two lines for the supply and discharge of a liquid or gaseous medium, each line having at least one compensating element.

11. The laboratory mill according to claim 10, wherein the compensating elements of the at least two lines are designed as line sections nested within one another and/or interspersed with one another.

12. The laboratory mill according to claim 10, wherein the compensating elements of the at least two lines are each designed as a helical line section or in the form of a flat or spatial spiral and wherein, preferably, the line sections have a different number of turns and/or a different circumference.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0047] The drawing shows examples of the invention, which are described below.

[0048] It shows

[0049] FIG. 1 is a perspective view of a laboratory mill according to the invention,

[0050] FIG. 2 is a top view of the laboratory mill from FIG. 1,

[0051] FIG. 3 is a view of the laboratory mill from FIG. 1 from below,

[0052] FIG. 4 is a side view of the laboratory mill from FIG. 1 and

[0053] FIG. 5 is a perspective view of several lines of the laboratory mill shown in FIG. 1, which are provided for the supply and discharge of liquid or gaseous tempering media in the direction of the grinding bowl support or away from the grinding bowl support, each line being connected with one-line end to the grinding bowl support and with another line end to a stationary part of the laboratory mill.

DETAILED DESCRIPTION

[0054] FIG. 1 shows a top view of a oscillating mill 1 for two grinding bowls 2, 3 oscillating in a horizontal position. A pendulum drive of the oscillating mill 1 is of multi-part design with an eccentric shaft 4 mounted so as to be rotatable about a vertical eccentric axis and with two swing arms 5, 6, each mounted so as to be able to oscillate about vertical oscillation axes and connected to the eccentric shaft 4 via couplings. Grinding bowl holders 7, 8 for the grinding bowls 2, 3 are attached to the swing arms 5, 6. In addition, a motor unit 10 coupled to the eccentric shaft 4 via a V-belt 9 is provided for torque transmission. The eccentric shaft 4 is rotatably mounted on a base plate 11. In addition, two bearing bolts 12, 13 are attached to the base plate 11, around which the swing arms 5, 6 are rotatably mounted. Finally, the motor unit 10 is located on the base plate 11. The eccentric shaft 4, the bearing bolts 12, 13 and the motor unit 10 together with the base plate 11 thus form a construction unit which can stand on a floor or subsoil via damping elements.

[0055] The motor unit 10 transmits a torque via the V-belt 9 to the eccentric shaft 4. A rotary motion of the eccentric shaft 4 is converted via the couplings into an oscillating motion of the swing arms 5, 6. The oscillation frequency can be between 3 and 50 Hz, preferably up to 35 Hz. The oscillation path (double amplitude deflection) of the grinding bowl can be between 20 and 50 mm, preferably between 20 and 30 mm.

[0056] A tempering device not shown in detail can be used to temper grinding bowls 2, 3. To transport a tempering medium, which can be liquid or gaseous, from a stationary part 14, 15 of the oscillating mill 1 to a grinding bowl holder 7, 8 and to discharge the medium from the respective grinding bowl holder 7, 8 to the stationary part 14, 15, each grinding bowl holder 7, 8 is connected to two lines 16, 17. In each case, one of the two lines 16, 17 is pro-vided for the supply line, the other of the two lines 16, 17 for discharging a gas or liquid medium, in particular liquid nitrogen, to the respective grinding bowl holder 7, 8.

[0057] The lines 16, 17 are preferably designed as continuous uninterrupted pipelines. Lines 16, 17 can be made of stainless steel or plastic, for example, or have stainless steel and/or plastic.

[0058] The design of the line routing is the same for both grinding bowl holders 7, 8, so that only one-line routing is described below as an example. The line arrangement with the lines 16, 17 of one grinding bowl holder 7 is mirror-symmetrical to the line arrangement of the second grinding bowl holder 8.

[0059] To compensate for relative movements between a grinding bowl holder 7, 8 and the stationary part 14, 15 assigned via the lines 16, 17 during operation of the oscillating mill 1, each line 16, 17 has a compensating element 18, 19. The entire length of each line 16, 17 is designed as a rigid pipeline, with the compensating element 18, 19 being formed by a pipe-line section of line 16, 17.

[0060] During operation of the oscillating mill 1, the relative movements cause an oscillating de-formation of the pipeline sections forming the compensating elements 18, 19, whereby the pipeline sections of the respective line 16, 17 adjacent to the compensating elements 18, 19 are deformed comparatively less. The design of the compensating elements 18, 19 as rigid pipeline sections enables the compensation of relative movements without using line sections which are connected to each other in a rotatable and/or swiveling manner relative to each other. In particular, it is not necessary to use the rotary unions known from the state of the art to compensate for relative movements, so that a hermetically sealed, uninterrupted connection and a permanently leakage-free transport of the tempering medium be-tween the grinding bowl holders 7, 8 and the stationary parts 14, 15 is ensured in a simple manner. In particular, it is not necessary to use sealing elements to compensate for relative movements, as is the case with rotary unions.

[0061] For the connection of lines 16, 17 to the grinding bowl holders 7, 8 on the one hand, and for the connection to the stationary parts 14, 15 on the other hand, connection and accessory parts of the assembly technology known from the state of the art may be provided. The connection of the lines as such, i.e. decoupled from the compensation of relative movements, can be made by means of sealing material to enable a sealing connection between the respective line 16, 17 and the grinding bowl holders 7, 8 on the one hand and the stationary parts 14, 15 on the other hand.

[0062] Each compensation element 18, 19 is designed as a helical pipeline section with several coils or windings and is formed by essentially straight-line sections 20 and curved corner sections 21. During the compensation of movement, the deformation of the line sections forming the compensating elements 18, 19 decreases from coil to coil, so that the pipeline sections at the end of the respective last coil are essentially no longer deformed. As a result, the compensation of movement essentially takes place exclusively in the area of the compensating elements 18, 19.

[0063] The formation of the compensating elements 18, 19 is done, for example, by forming, such as bending, straight pipe sections of the lines 16, 17.

[0064] The compensation elements 18, 19 of two lines 16, 17 connected to a grinding bowl holder 7, 8 are designed as nested helixes. This compensates for relative movements in all spatial directions while requiring little space for the installation of the lines 16, 17 inside the oscillating mill 1.

[0065] The helically bent compensating element 18, 19 or the respective pipeline section of the line 16, 17 allows an increase in the line length compared to the line length with straight line routing. This is shown schematically in FIG. 5. The ratio of the actual line length of a compensating element 18, 19 to the line length L in the case of straight-line routing can be at least 5, preferably at least 10. This provides a sufficiently long cable length to compensate for relative movements, to enable the compensation of relative movements with low stress and low deformation resistance.

[0066] In order to reduce the space required for the arrangement of the compensating elements 18, 19 inside the mill 1, the compensating element 18 is formed by a helix with, for example, four windings, while the nested internal compensating element 19 has five windings with a smaller circumference. It goes without saying that the type and design as well as the number of windings are to be understood as examples for the design of the oscillating mill 1 shown in FIGS. 1 to 5.

[0067] Two lines 16, 17 running parallel on each side of a grinding bowl holder 7, 8 are connected to each other via screwed clamping and holding parts 22, 23. This prevents relative movements between the lines 16, 17 from occurring in these line sections and compensates for movement primarily in the area of the helically bent compensating elements 18, 19.

[0068] The stationary parts 14, 15 are rigid blocks of e.g. polytetrafluoroethylene (PTFE), which are fixed to the base plate 11. The stationary parts 14, 15 are decoupled from the vibrating movement of the grinding bowl holders 7, 8. Inside the stationary parts 14, 15, channels are provided for the passage and transfer of the tempering medium to or from a supply and/or disposal device 24 for the tempering medium. For this purpose, the stationary parts 14, 15 are connected to the supply and/or disposal unit 24 via further pipelines.

REFERENCE CHARACTER LIST

[0069] 1 Oscillating mill [0070] 2 Grinding bowl [0071] 3 Grinding bowl [0072] 4 Eccentric shaft [0073] 5 Swing arm [0074] 6 Swing arm [0075] 7 Grinding bowl holder [0076] 8 Grinding bowl holder [0077] 9 V-belt [0078] 10 Motor unit [0079] 11 Base plate [0080] 12 Bearing bolt [0081] 13 Bearing bolt [0082] 14 Stationary part [0083] 15 Stationary part [0084] 16 Line [0085] 17 Line [0086] 18 Compensating element [0087] 19 Compensating element [0088] 20 Line section [0089] 21 Corner section [0090] 22 Holding part [0091] 23 Holding part [0092] 24 Supply and/or disposal device