EP0626194A1 - Mixer with vibratory drive - Google Patents

Abstract

The invention relates to a mixer having a vibratory drive for a movably mounted object holder. A mixer which can perform multidimensional vibratory movements at frequencies of up to 20 kHz is characterised in that the object holder is mounted on a Y frame (7, 5) which is horizontally movable in the Y direction, which Y frame is supported on an X frame (4, 5) which is horizontally movable in the X direction by at least one Y spring (6) which can be deflected in the Y direction, in that the X frame is suspended on at least one X spring (3) which can be deflected in the X direction, which X spring is supported on a base plate and in that vibratory drives engage on the Y frame and on the X frame, which vibratory drives comprise permanent magnets (21) and drive coils (25) arranged opposite them. <IMAGE>

Description

The invention relates to a mixer with a vibratory drive for a movably mounted slide.

Mixers are known in various designs. Mixers with an agitator have the disadvantage that they act mechanically on the microstructure of the medium to be agitated, thereby destroying, for. B. can cause biological systems. Mixers of the type described at the outset, which work with vibratory drives, also include shaking containers which are set to oscillate in one direction, or rotating containers. However, these mixers only work at frequencies up to approx. 20 Hz. There are also ultrasonic mixers that work at frequencies above 20 kHz.

The object of the invention is to provide a mixer of the type described in the introduction which can carry out multidimensional oscillating movements at frequencies up to 20 kHz.

This object is achieved in that the specimen slide is mounted on a Y frame which can be moved horizontally in the Y direction is, which is supported with at least one Y-spring deflectable in the Y-direction on a horizontally movable X-frame, the X-frame is suspended from at least one X-spring deflectable in the X-direction, which is attached to a Base plate is supported, and that attack on the Y-frame and on the X-frame vibrating drives, which consist of permanent magnets and drive windings arranged opposite them. Such a mixer is particularly suitable for use in different laboratories for a wide variety of mixing purposes. Since the vibratory drives designed according to the principle of a direct current linear motor only work in one spatial direction and can be controlled according to frequency and amplitude, the operating parameters of the mixer can be adapted to the respective requirements without difficulty.

A preferred embodiment is one in which the Y springs and the X springs are designed as leaf springs. In particular, the Y-frame and the X-frame can have a rectangular to square outline, their associated leaf springs each being connected to opposite sides of the frame. Apart from spring losses, practical, friction-free storage or support is possible. It is understood that the springs should be designed so that they can absorb the attraction force caused by the permanent magnetic flux of the oscillating drive in question, without the desired direction-dependent spring deflection being impaired thereby.

The mixer according to the invention can also perform three-dimensional oscillating movements if in combination with the Measures described above, the X frame is supported on at least one Z spring which can be deflected in the Z direction and is connected to a frame which can move in the Z direction, and when at least one oscillating drive acts on the Z frame. To stabilize the specimen slide, it can be advantageous if the specimen slide is connected via hinges with a hinge axis extending in the X direction to a spring plate which can be deflected in the Z direction and is connected to the Y frame, the Z frame also being connected to these hinges Spring plates which can be deflected in the Y direction are connected.

According to a preferred embodiment of the invention, at least one device for changing the spring constant can be provided. This can be a device for two-dimensionally changing the spring constant from a spring bar clamped on one side and a mass adjustable along the spring bar, or a device for one-dimensionally changing the spring constant from a spring bar clamped on one side or from a leaf spring clamped on one side, the or which is guided in a fork which can be adjusted parallel to it, the fork being guided in a housing arranged next to the spring bar or the leaf spring and being adjustable with an actuating drive, in particular a spindle drive. The exact adjustability of the resonance point via the change in the spring constants allows to work with optimal efficiency with differently moving masses of the medium arranged on the slide within a certain range.

In particular, a device for one-dimensional Attack the change in the spring constant at least on one X spring of the X frame. In other embodiments, a device for changing the spring constant can be arranged between the X-frame or the Y-frame and a base plate, the spring bar being clamped on the base plate or a component connected to it and being guided in an articulated bearing of the frame.

An adjustment of the resonance point in the Z direction is possible if a device for changing the spring constant is arranged between the Z frame and a base plate, the horizontally extending spring rod being clamped on the base plate or a component connected thereto and in a spherical bearing of the Z -Frame is guided.

The vibratory drives should be able to be controlled and / or regulated independently of one another according to frequency, amplitude and phase. By adjusting the directional vibratory drives can be set so that they always work with optimal efficiency.

If, in addition, a device is provided for detecting the operating parameters of the individual vibratory drives as a function of time, the mixer can also be used for other purposes, e.g. B. to determine the viscosity of the media to be treated. This device can include measuring loops integrated in the windings of the vibratory drives or the like. And downstream regulating and control devices. You can also see the changing viscosity of a medium during mixing via the change in the moment of inertia and the thus detecting the shifting of the resonance point. The amount to be adjusted at least one operating parameter of the oscillating drive or drives until the new resonance point is found is then a measure of the change in viscosity.

Fig. 1

schematisch und teilweise sowie in perspektivischer Darstellung einen Mischer für zweidimensionale Schwingbewegungen,

Fig. 2

schematisch und teilweise einen Schnitt durch einen Mischer für dreidimensionale Schwingbewegungen,

Fig. 3

einen Schnitt in Richtung III-III durch den Gegenstand nach Fig. 2,

Fig. 4

schematisch die Seitenansicht einer Einrichtung zur eindimensionalen Veränderung der Federkonstante eines Federstabes oder einer Blattfeder,

Fig. 5

den Gegenstand nach Fig. 4 in anderer Projektion.

Exemplary embodiments of the invention illustrated in the drawing are explained below; show it:

Fig. 1

schematically and partially and in perspective a mixer for two-dimensional oscillating movements,

Fig. 2

schematically and partially a section through a mixer for three-dimensional swinging movements,

Fig. 3

3 shows a section in the direction III-III through the object according to FIG. 2,

Fig. 4

schematically the side view of a device for one-dimensional change in the spring constant of a spring bar or a leaf spring,

Fig. 5

4 in a different projection.

1 includes a fixed base plate 1, which carries two mutually spaced and mutually parallel mounting bracket 2. At the mounting brackets 2 are each vertically downward, deflectable in the X direction and as leaf springs trained X-springs 3 attached, the lower ends of which are connected to the opposite sides of an X-frame from an X-frame plate 4 with lateral edge stiffeners 5.

Connected to the edge stiffeners 5 are vertically upwardly extending Y springs 6, which can be deflected in the Y direction and are designed as leaf springs, the upper ends of which are connected to opposite sides of a rectangular Y frame made of a Y frame plate 7 with lateral edge stiffeners 5 .

A slide for the medium to be examined, not shown in this embodiment, is arranged on the Y-frame plate 7. Vibratory drives (not shown), which consist of permanent magnets and drive windings arranged opposite them, act on the X-frame plate 4 and on the Y-frame plate 7. In this regard, reference is made to the embodiment shown in FIGS. 2 and 3. With the help of the vibratory drives acting on the X-frame, this X-frame, together with the components connected to it, ie also the Y-frame and the slide, is set in vibration in the X direction. In addition, the Y frame and also the specimen slide are set to oscillate in the Y direction with the aid of the associated oscillating drive.

In the embodiment according to FIG. 1, a device for the two-dimensional change of the spring constants of the X-springs 3 and the Y-springs 6 is shown with dashed lines. This device consists of a spring bar 8, the lower end of which in a on the base plate. 1 attached flange 9 is arranged and thereby clamped on the X-frame plate 4, and the upper end is guided in a spherical bearing 10 of the Y-frame plate 7. The lower end of the spring rod 8 is surrounded by a threaded bushing 11 which carries a nut 12 which can be adjusted thereon. The nut 12 has a guide 13 with little play for the spring bar 8.

During operation, the spring constant of the spring rod 8 is added to the spring constants of the X springs 3 and the Y springs 4. The entire spring constants for the X direction and the Y direction can be changed by adjusting the nut 12 to adjust a resonance point .

The mixer shown in FIGS. 2 and 3 is designed for three-dimensional oscillating movements. The X-frame plate 4 of the X-frame is connected on the underside via a spacer bar 14 in the center to a Z-spring 15 designed as a leaf spring, the ends of which via spring plates 16 which extend vertically upwards and can be deflected in the Y-direction in joints 17 with in X. -The direction extending joint axis are pivotally mounted. The joints 17 are attached on the underside to a specimen slide 18 and also carry a spring plate 19 which can be deflected in the Z direction and which is connected in the center to the upper side of the Y frame plate 7 via a spacer bar 20 extending in the X direction.

The vibratory drives for the different directions each include a permanent magnet arrangement 21, which has a highly permeable yoke 2 on the top of the X frame plate 4 or on the underside of the Y frame plate 7 and on the outside of the ends of the Z spring 15 with webs 24 connecting a Z frame 23 are arranged.

The oscillating drives 15 also include drive windings 25, each of which is connected to associated stator carriers 27 via an electrically non-conductive, highly permeable backflow 26, these stator carriers 27 being firmly connected to a housing 28.

In the embodiment shown in FIGS. 2 and 3, a device for changing the spring constant in the Y direction is provided. The device includes a housing 28 which is connected to the X-frame plate and which has a lateral flange 29 at the lower end into which the spring rod 8 is clamped, the upper end of which is guided in the spherical bearing 10 of the Y-frame plate 7. A spindle 30 is mounted in the housing 28 and can be rotated with a rotary knob 31. A spindle nut 32 is guided on the spindle 30 and has a fork 34 extending through a housing opening 33, in the fork slot 35 of which the spring rod 8 is guided. As already explained in connection with the embodiment according to FIG. 1, the spring constant of the spring bar 8 is added to the spring constant of the Y-springs 6 and the entire spring constant can be changed by adjusting the fork 34.

In the embodiment shown in FIGS. 2 and 3, the spring constant can also be changed in the Z direction. For this purpose, the device described with reference to FIGS. 4 and 5 is aligned horizontally, the housing 28 on the associated stator carrier 27 for the Sterndrive is arranged while the free end of the spring rod 8 is guided in a spherical bearing 10 of the web 24.

It is not shown that the vibratory drives can be controlled and / or regulated independently of one another according to frequency, amplitude and phase. Furthermore, it is not shown that a device for detecting the operating parameters of the individual vibratory drives can be provided as a function of time.

The mixer shown enables contactless, targeted, controllable and time-influenced energy input into liquid, viscous, pasty or granular media and can be used for dispersing, mixing, segregating, sedimenting and separating materials.

Claims (12)

Mixer with an oscillating drive for a movably mounted specimen slide, characterized in that the specimen slide (18) is mounted on a Y frame (7, 5) which can be moved horizontally in the Y direction and which has at least one Y spring which can be deflected in the Y direction (6) on a horizontally movable in the X-direction X-frame (4, 5) that the X-frame (4, 5) is suspended on at least one X-spring deflectable in the X-direction (3), the is supported on a base plate (1), and that vibrating drives act on the Y-frame (7, 5) and on the X-frame (4, 5), which consist of permanent magnets (21) and drive windings (25) arranged opposite them. Mixer according to claim 1, characterized in that the Y-springs (6) and the X-springs (3) are designed as leaf springs. Mixer according to claim 1 or 2, characterized in that the Y-frame (7, 5) and the X-frame (4, 5) have a rectangular to square outline and that their associated leaf springs are each connected to opposite sides of the frame . Mixer according to one of claims 1 to 3, characterized in that that the X frame (4, 5) is supported on at least one Z spring (15) which can be deflected in the Z direction and is connected to a Z frame (23) movable in the Z direction, and that on the Z frame (23) attacks at least one vibratory drive. Mixer according to one of Claims 1 to 4, characterized in that the specimen slide (18) is connected via hinges (17) with a hinge axis extending in the X direction to a Y frame (7, 5) which can be deflected in the Z direction Spring plate (19) is connected, and that these hinges (17) and also the Z frame (23) are connected via spring plates (16) which can be deflected in the Y direction. Mixer according to one of claims 1 to 5, characterized by at least one device for two-dimensionally changing the spring constant from a spring bar (8) clamped on one side and a mass (12 or 34) adjustable along the spring bar (8). Mixer according to one of claims 1 to 5, characterized by at least one device for one-dimensionally changing the spring constant from a spring rod (8) clamped on one side or from a leaf spring clamped on one side, which is guided in a fork (34) which can be adjusted parallel to it, the fork (34) being guided in a housing (28) arranged next to the spring bar (8) or the leaf spring and being adjustable with an actuating drive, in particular a spindle drive (30, 32). Mixer according to one of claims 1 to 7, characterized in that a device for one-dimensional Changing the spring constant acts on at least one X-spring (3) of the X-frame (4, 5). Mixer according to one of claims 1 to 8, characterized in that a device for changing the spring constant is arranged between the X frame (4, 5) or the Y frame (7, 5) and a base plate (1), wherein the spring rod (8) is guided in a spherical bearing (10) of the Y-frame (7, 5). Mixer according to one of claims 1 to 9, characterized in that a device for changing the spring constant is arranged between the Z-frame (23) and a base plate (1), the horizontally extending spring bar (8) on the base plate (1 ) or a component connected to it and clamped in a spherical bearing (10) of the Z-frame (23). Mixer according to one of claims 1 to 10, characterized in that the oscillating drives can be controlled and / or regulated independently of one another according to frequency, amplitude and phase. Mixer according to one of claims 1 to 11, characterized in that a device is provided for detecting the operating parameters of the individual vibratory drives as a function of time.

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