DE7920551U1 - Rotational viscometer - Google Patents

Description

CONTRAVES AG
Schaffhauserstrasse 580
CH-8052 Zurich / Switzerland

Rotational viscometer

The invention relates to a rotary viscometer with a centrally arranged in a recess of a first shaft, rotatably mounted measuring cup and arranged with at least one eccentric to the axis of the first shaft Circular disc.

Devices for converting a rotary movement into a reciprocating movement are generally known which have at least one eccentrically arranged circular disk or a cam disk and a lever system designed as a crank drive. However, these devices are incapable of transmitting a movement or a force to a body rotatably mounted in a drive shaft with the same axis center and converting the rotational movement of the body.

The invention is based on the object of creating an additional device for a rotary viscometer which suitably has the advantages of an eccentrically arranged Kneecap and a lever system combined, so that the rotary movement of a measuring cup of a rotational viscometer arranged centrally in a continuously driven shaft, the measuring cup being rotatable in the shaft is mounted and is operatively connected by friction essentially with the shaft, in a back and forth around the axis of the first shaft forward movement converted with sinusoidal speed curve and also on a displacement recording device (transducer) can be transferred.

The solution to the task is characterized by the following features:

jij axially parallel and offset to the seen in the plane the first shaft is a second shaft rotatably mounted about its vertical axis,

b) on the first shaft there is an eccentric body with two circular disks and on the second shaft there are two transmission elements,

c) the first transmission element is operatively connected to the first circular disk by a push rod and the second transmission element is operatively connected to the measuring cup by a releasable steering lever, and

d) At a distance from the first shaft, a path recording device that is operatively connected to a scanning head ait of the second circular disk is arranged.

With the additional device according to the invention, in connection with a rotational viscosity and while maintaining the actual determination of the viscosity of a Hess substance, it is also possible to determine the elasticity of the Hess substance

to be determined, the additional device being designed in such a way that that the determination of the elasticity can be done optionally.

The invention is described below using an exemplary embodiment in conjunction with the drawing. It shows:

1 shows a partially sectioned side view of an additional device for a rotary viscometer for converting a rotary movement into a backward and moving motion with sinusoidal speed curve, and

FIG. 2 shows the additional device according to FIG. 1 in a top view.

In Fig. 1, 10 denotes a platform and 15 denotes a first shaft of a device not shown in detail, such as a rotary viscometer device, at which the shaft 15 is driven in the direction of arrow P about its vertical axis A by means not shown. To the To accommodate a measuring cup 20, the shaft 15, shown partially in section, has a correspondingly designed, centrally arranged recess 16. The measuring cup 20 i & t by friction with the shaft 15 and is for the introduction of a means not shown in the arrow direction ! device 1 movable measuring body 25 with a correspondingly differentiated, a measuring gap having blind hole 21, in which the substance to be measured is located or is filled.

An eccentric body 30 designed as a plug-on cap and shown in section has a first circular disk 31 as well as a second circular disk 32 and is non-rotatably connected to the first shaft 15 by means of screws 33. The eccentric 30 is centric, i.e. with the same axis A.

of the first shaft 15 «while the two are circular formed discs 31/32 an eccentric to the Axis A arranged to have axis A *.

At a distance from the first shaft 15 is on the platform 10 for converting a continuous rotary movement into a reciprocating movement with sinusoidal speed profile arranged additional device 50, which is built into a housing 40. The housing 40 is on the platform by means of a base plate 45 and screws 46 10 attached.

The additional device 50 consists essentially of the housing 40, the base plate 45, one at a distance and in the plane the base plate 45 is seen with an offset axis center B to the first shaft 15 arranged second shaft 55, a first and a second transmission element 56, 58 connected to the second shaft 55 in a rotationally fixed manner and one essentially A lever system consisting of a thrust lever 60 and a steering lever 70 as well as a lever system with the second circular disk 32 Operationally connected inductive displacement recorder (transducer) 65.

The second shaft 55, which can be moved back and forth about its vertical axis B in the direction of arrow P ^1, is rotatably mounted at one end in the base plate 45 and at the other end in a web 76 arranged parallel to the base plate 45 by stud bolts 75, 75 *.

In the example shown, the first transmission element 56 is designed as a roller on which the in the direction of the arrow (Axis of movement of the push lever 60) reciprocating push lever 60 is tangential. The axis of movement of the thrust lever 60 is seen radially in the plane of the base plate 45

arranged in the same direction to the axis A of the first shaft 15, in order to achieve an optimal transmission of movement from the thrust lever 60 to the roller and thus also to the second shaft 55 ensure, is in a not shown, arranged on the roller groove is essentially looped around the roller Cable 59 is provided, which is attached to the thrust lever 60 with elements 63 in a manner not shown is. In a variant, the thrust lever 60 and the transmission element 56 can also be used for the exact transmission of movement be provided with a correspondingly designed toothing (not shown). The push lever 60 is due to the force a spring 62, which is attached on one side essentially to the housing and on the other side to one on the thrust lever Arm 61 is suspended, constantly with the first circular disk 31 in operative connection.

The thrust lever 60 is furthermore on the side facing the first circular disk 31 with one resting against the circular disk Scanning element: 64 is provided, which, seen in the plane, is associated with one of the two axes A and A * essentially at right angles Has scanning surface 64 'which is at least twice as large as the distance between the two axes A and A' to one another is.

The push lever 60 is preferably on a guide block and is for precise guidance - the axis of movement of the push lever lies in the same direction to the axis A - guided between two spaced apart rollers 52,52 *. the Rollers are each rotatably mounted on a shaft 53, 53 * which is essentially fastened to the base plate 45. The roles can, however, also be rotatably mounted on a pin arranged on the guide block.

One end of the steering lever 70 is operatively connected to the second transmission element 58 designed as a disk, the point of application of the steering lever on the disc is eccentric is arranged to the axis B. At the other end, the steering lever 70 has a not shown, for example designed as a ball head joint on plug element 71, which is arranged in an eccentric to the axis A on the measuring cup 20 Opening 23 can be inserted. The opening 23 is provided in a tab 22 formed on the measuring cup flange 24. The steering lever 70 transmits the to-and-fro movement of the disk that is connected to the second shaft 55 on the measuring cup 20.

The distance from the axis A to the point of application of the plug element 71 on the measuring cup flange 24 is equal to the distance from the axis B to the point of application of the steering lever 70 on the transmission element 58 and the diagonal distance from the axis A of the first shaft 15 to the axis B of the second shaft 55 equal to the distance between the two points of application of the steering lever (Fig. 2).

The path recording device 65 is attached to the base plate 45 by means not shown and has one in one Tube 67 guided scanning head 66 (not shown in FIG. 2), which is operatively connected to the second circular disk 32 is.

The mode of operation of the additional device in connection with a rotary viscometer is described below:

Starting from the first driven rotating around its axis A in the direction of arrow P by means not shown Shaft 15 is supported by the eccentric body which is provided with the same axis A, but which is arranged eccentrically to the axis A. Has circular disks 31,32, the movement of the circular

Transfer discs on the one hand to the thrust lever 60 and on the other hand to the scanning head 66 of the displacement recording device 65, whereby the push lever 60 and also the scanning head are moved back and forth in the direction of arrow 2. Because of the active connection of the thrust lever 60 with the first transmission element 56, which is arranged non-rotatably on the second shaft 55, is the Shaft 55 and thus also the second transmission element arranged by a spacer sleeve 57 at a distance from the first element 56 58 and at the same time the attached steering lever 70 is actuated, so that the back and forth movement transmits synchronously to the measuring cup 20 when the Lerik lever 70 is engaged or suspended. The real, through The rotational movement transmitted from the first shaft 15 to the measuring cup 20 thus becomes a reciprocating motion Movement converted with a sinusoidal speed curve. The additional to the known viscosity determination The elastic properties of a substance to be measured are measured essentially by comparing the The phase of an electrical signal from the actuated travel recording device 65 to the phase of the measuring body 25 - the measuring body is in which moved back and forth with a sinusoidal speed curve Measuring cup immersed - measuring monwmtes that occur.

The patent attorney

summary

The invention relates to an additional device for a rotational viscometer, with a centered in a recess (16) a first shaft (15) arranged and rotatably mounted measuring cup (20), which is used to shape the actual rotating rotary movement of the measuring cup into a reciprocating movement with a sinusoidal speed curve is trained. On the shaft (15) one with two is arranged eccentrically to the axis of the shaft (15) Eccentric bodies provided with circular disks (31, 32) (30) and also a second shaft (55) is provided axially parallel to the shaft (15), on which two transmission elements (56,58) are non-rotatably arranged. The circular disk (31) is connected to the transmission element via a thrust lever (60) (56) and the circular disk (32) with a path recording device (65) and the transmission element (58) a steering lever (70) is operatively connected to the measuring cup (20).

Fig. 1

Claims (8)

Protection claims 1. Rotatxonsviscometer with a centrically arranged in a recess of a first shaft, rotatable mounted measuring cup and with at least one circular disc arranged eccentrically to the axis of the first shaft. characterized by an additional device with the following features: a) axially parallel and offset from the first shaft (15) seen in the plane is one about its vertical axis (B) rotatably mounted second shaft (55) is provided, b) on the first shaft (15) is an eccentric body (30) with two circular disks (31, 32) and on the second shaft (55) there are two transmission elements (56,58). ~ Dnet, c) the first transmission element (56) is through a push rod (60) with the first circular disk (31) and the The second transmission element (58) is operatively connected to the measuring cup (20) by a releasable steering lever (70), and d) at a distance from the first shaft (15) is an operatively connected to a scanning head (66) with the second circular disk (32) Position recording device (65) arranged. 2. Viscometer according to claim 1, characterized in that the thrust lever (60) is arranged with its axis of movement in the same radial direction to the axis (A) of the first shaft (15) and a scanning element (64) assigned to the first circular disk (31) having. 3. Viscometer according to claim 1 and 2, characterized in that the scanning element (64) is at least twice as large as the distance between the axis (A) of the first shaft (15) and the axis (A ¹ ) of the circular disks (31, 32) is (Fig. 2). 4. Viscometer according to claim 1 or 2, characterized in that the thrust lever (60) between two rollers (52,52 ') is guided and tangentially on the first transmission element (56) and is operative with the element by a rope (59) looping around the element. 5. Viscometer according to claim 1, 3 or 4, characterized characterized in that the push lever (60) with the first transmission element (56) by one on the push rod as well as the toothing provided on the element is operatively connected. 6. Viscometer according to claim 1, characterized in that the distance from the axis (A) of the first shaft (15) to the point of application of the steering lever (70) on the measuring cup (20) and the distance from the axis (B) of the second shaft (55) to the point of application of the steering lever (70) on the second transmission element (58) is the same size. 7. Viscometer according to Claimi or 6, characterized in that the measuring cup (20) has an integrally formed tab (22) with an opening (23) into which the steering lever (70) provided with a plug-in element designed as a spherical head joint (71) is lockable. 8. Viscometer according to claim 1 or 6, characterized in that the diagonal distance from the axis (A) of the first shaft (15) to the axis (B) of the second shaft (55) equal to the distance between the two points of application on the steering lever (70) is.