DE10025242A1 - Pusher centrifuge has connecting rod pressure load measurement transducers mounted on connecting rod; transducer signals fed to control unit after conversion in measurement amplifier - Google Patents

Abstract

The device has one or more filter drums on a drum base, free to rotate on a hollow shaft in a machine frame and enclosed by a centrifuge housing. The measurement signals from one or more measurement transducers that detect the pressure load on a connecting rod and are mounted on the connecting rod are fed to a control unit after conversion in a measurement amplifier. The device has one or more filter drums (6) on a drum base (5), free to rotate on a hollow shaft (1) in a machine frame (2) and enclosed by a centrifuge housing (7). A thrust rod (14) passing through the hollow shaft has thrust elements inside the filter drums. A rotary drive (18) coupling system is arranged at the other end of the shaft. The thrust rod is arranged in a bearing system (20,21) linked to a connecting rod (22) mounted at the other end in the eccentric shaft (29) of a lifting drive supported on the machine frame. The measurement signals from one or more measurement transducers that detect the pressure load on the connecting rod and mounted on the connecting rod are fed to a control unit after conversion in a measurement amplifier.

Description

The invention relates to a push centrifuge according to the preamble of claim 1.

With push centrifuges of the type mentioned there is the problem that the pushing force with which the thrust elements the solid layer deposited on the sieve drums zyk Convey to the drum edges at the open end of the sieve drum, permissible Values may exceed if e.g. B. Product deposits between the screening drum and get the thrust member or when the procedural Randbe conditions such as the feed concentration or the product properties change. The Execution of the pushing movement on an eccentric shaft of a linear actuator articulated connecting rods has the effect that the torque of the linear actuator or the eccentric shaft is not proportional to the thrust. The one with the connecting rod device accompanying knee lever effect has the consequence that at a defined rotation torque of the linear actuator theoretically sets an infinite thrust. From this The problem arises from the need to monitor the thrust.

So far, the thrust force has not been monitored on smaller machines, since suchi machines, the components have been designed with such great certainty that they could also withstand excessive thrust loads.

In larger machines, it is known to push the thrust through a slip clutch in the Limit stroke drive.

The invention has for its object in a push centrifuge of the type mentioned, to create a thrust monitoring with which the Thrust over the entire stroke length and reliably even at the turning point  can be monitored. This task is ge in the generic centrifuge solved according to the characterizing part of claim 1.

Advantageous refinements are specified in the subclaims.

The connecting rod is preferably in the form of an H-shaped lifting cross with two parallel connecting rod arms and a central cross member. The thrust can be uniform are transferred from the linear actuator to the thrust bearing, with the parallel connecting rods spar both or as a single element for the arrangement of the thrust force Sensors are particularly suitable. In a preferred embodiment, the connecting rods are with recesses and / or cutouts, whereby the deformation of the Connecting rod elements increased and particularly clear measurement results at these points are achievable.

Embodiments of the invention are shown in the drawing and are explained in more detail below. They show a partial sectional view

Fig. 1 shows the basic scheme of a pusher centrifuge with rotary and lifting drive,

Fig. 2 is a plan view of that shown in Fig. 1 in the side view of connecting rods,

Fig. 3 is an enlarged detail view of the designated in Fig. 1 A site,

Fig. 4-sectional narrowing a partial section of the connecting rod of Fig. 1 with alternative cross,

Fig. 5 is a partial section of the connecting rod according to FIG. 1 with a further old native cross-sectional constriction and a laser path element as a transmitter and

Fig. 6 shows an alternative to the connecting rods according to FIGS. 1 to 5 in the form of a fluid piston-cylinder unit.

In Fig. 1, the basic diagram of a pusher centrifuge is shown, in which a hollow shaft 1 is rotatably mounted on a stationary machine frame 2 in rolling bearings 3 , 4 . At one end of the hollow shaft a sieve drum 6 is fastened via a drum base 5 , which housing 7 is located in a centrifuge which is firmly connected to the machine frame 2 . The centrifuge housing 7 is divided into a solids discharge space 8 and a filtrate collection space 9 . A distributor base 11 , which has a distributor cone 12 centrally, is fastened by means of spacer bolts 10 parallel to the drum base 5 . This lies in the opening of a feed tube 13 for suspension, which is firmly connected to the centrifuge housing 7 .

The hollow shaft 1 is centrally penetrated by a push rod 14 which is connected via an inner drum base 15 to an inner drum element 16 . The inner drum base 15 lies between the drum base 5 and the distributor body 11 and is penetrated by the spacer bolts 10 . At the centrifuge housing 7 facing away from the hollow shaft 1 , the pulley 17 of the Rotationsan drive 18 is flanged, which is driven by a motor 19 via V-belts. The push rod 14 projects above the hollow shaft 1 and carries a thrust bearing 20 at its end. In this thrust bearing 20 , the push rod 14 is rotatably supported by means of roller bearings (not shown), the thrust bearing housing 21 surrounding the roller bearing being held in a rotationally fixed manner by a connecting rod 22 . The connecting rod 22 shown in plan view in FIG. 2 consists of an H-shaped lifting cross with two parallel connecting rod arms 23 and 24 and a central cross beam 25 . The connecting rod 22 grips at one end in a fork-like manner in the thrust bearing 20 and is pivotally mounted thereon with the ends of the connecting rod arms 23 , 24 in two thrust bearing bolts 26 . The other end of the connecting rod 22 engages with the other ends of the connecting rods 23 , 24 also fork-like a Huban 27 , and is mounted in the bearing pin 28 of an eccentric shaft 29 . The eccentric shaft 29 is in the housing 30 of the linear actuator 27 with a gear worm (not shown) in gear engagement, which is driven by a motor 32 via a pulley 31 .

Fig. 1 shows the connecting rod 22 in its rearmost position, in which the push rod 14 has reached the rear turning point. Between the rear turning point and the front turning point, the connecting rod runs through the entire stroke H. Due to the crank movement of the bearing pin 28 , the connecting rod performs limited swiveling movements, which, relative to the axis of the connecting rod, lead to a slight inclination of the connecting rod in the central region of the stroke. The associated deviation of the force measured in the connecting rod from the actual thrust is negligible or can be regarded as additional security.

One or more sensors for determining the pressure loads are arranged on the connecting rod 22 .

In the embodiment according to FIGS. 1 to 3, the connecting rod 22 is reduced in cross-section in certain sections, which increases the deformation of the connecting rod caused by the thrust load and is therefore more suitable for measurement purposes.

As can be seen from the enlargement of the detail A ( FIG. 1) in FIG. 3, the cross-sectional reduction in one or in both connecting rod arms 23 and 24 each consists of a circular recess 33 and four cutouts 34 open to the outside. In the recess 33 , four strain gauges 35 are arranged diagonally opposite one another, the combined measuring lines 36 of which are fed to a control unit 37 , in which the measured values, after passing through a Wheatstone measuring circuit and a measuring amplifier, are converted into control signals which display the given thrust force or, after exceeding a first limit value, triggering an alarm or, after exceeding a second limit value, generating a control signal with which the power of motor 32 is reduced or is completely switched off via control line 38 .

The connecting rod 22 according to FIG. 4 essentially corresponds to the H-shaped lifting cross according to FIGS . 1 to 3, but the connecting rod 23 'has only two opposite cutouts 34 '. In one measurement variant, strain gauges 35 'are arranged at the base of the cutouts 34 ' and in an alternative measurement variant piezoelectric force transducers 39 are arranged. Measuring lines 36 lead both from the strain gauges 35 ′ and from the piezoelectric force transducers 39 to the control device 37 according to FIG. 1.

The connecting rod 22 according to FIG. 5 also essentially corresponds to the H-shaped lifting cross according to FIGS . 1 to 3, but the connecting rod 23 "has a circular recess 33 'and only two cutouts 34 ". With this arrangement, only the area of the connecting rod stubs provided with the recess 33 'and the cutouts 34 ", which otherwise remain aligned with the center line M, rotates under pressure. A laser displacement measuring element 40 and a reflector 41 are arranged on the underside of the connecting rod stub 23 " . From the analysis of reflected, frequency-modulated laser radiation, the compression of the connecting rod 23 "generated by the thrust is determined and passed as a measured value via the measuring line 36 to the control unit 37 ( FIG. 1).

In Fig. 6 is one of one or two fluid piston-cylinder units 42 Va riante of the connecting rod 22 is shown. It consists of a cylinder 43 which is articulated on the bearing bolt 28 of the eccentric shaft 29 according to FIG. 1. In the cylinder 43 , a piston 44 is reversibly mounted, the piston rod 45 of which is articulated on the pressure bearing pin 26 of the pressure bearing 20 according to FIG. 1. The piston 44 divides the cylinder space into two fluid-filled sub-spaces 46 and 47 in which the pressure can be measured by means of fluid pressure measuring devices 48 , 49 . The measured values are fed via a measuring line 36 to a control unit 37 according to FIG. 1. The fluid-piston-cylinder unit can be constructed similarly to the H-shaped lifting cross according to FIGS . 1 and 2, wherein a connecting rod consists of a fluid-piston-cylinder unit and the two cylinders of the fluid-piston-cylinder unit are connected by a crossbar .

Reference list

1

Hollow shaft

2

Machine frame

3rd

roller bearing

4

roller bearing

5

Drum bottom

6

Sieve drum

7

Centrifuge housing

8th

Solids discharge room

9

Filtrate collecting space

10th

Spacer

11

Distributor floor

12th

Distribution cone

13

Feed tube

14

Push rod

15

Drum bottom

16

Screen drum element

17th

Pulley

18th

Rotary drive

19th

engine

20th

Thrust bearing

21

Thrust bearing housing

22

Connecting rod

23

,

23

',

23

"Connecting rods

24th

Connecting rods

25th

Cross bar, in the middle

26

Thrust bearing pin

27

Linear actuator

28

Bearing bolt

29

Eccentric shaft

30th

casing

31

Pulley

32

engine

33

,

33

'Recess

34

,

34

',

34

"Excerpts

35

,

35

'' Strain gauges

36

Test leads

37

Emergency unit

38

Control line

39

Force transducer, piezoelectric

40

Laser path measuring element

41

reflector

42

Fluid piston cylinder unit

43

cylinder

44

piston

45

Piston rod

46

Subspace

47

Subspace

48

Fluid pressure measuring devices

49

Fluid pressure measuring devices

Claims (14)

1. pusher centrifuge with one or more on a drum base ( 5 ) angeord designated sieve drums ( 6 ), which are freely rotatable by means of a hollow shaft ( 1 ) in a machine frame ( 2 ) and are closed by a centrifuge housing ( 7 ) and with a the push rod ( 14 ) passing through the hollow shaft ( 1 ), which has push elements in the form of a push floor and / or in the form of sieve drum elements with a pushing edge inside the sieve drums, the hollow shaft ( 1 ) at the end facing away from the sieve drums ( 6 ) a coupling system for has a rotary drive ( 18 ) and the push rod ( 14 ) is arranged in a thrust bearing ( 20 ) with a pivot bearing and a non-rotating thrust bearing housing ( 21 ), to which a connecting rod ( 22 ), preferably in the form of a lifting cross, is articulated, which is connected to the other End in the eccentric shaft ( 29 ) of a lifting drive supported on the machine frame ( 2 ), characterized in that an ode on the connecting rod ( 22 ) r several pressure sensors of the connecting rod ( 22 ) are arranged, the measured values of which, after conversion, are fed to a control unit ( 37 ) in a measuring amplifier. 2. A pusher centrifuge according to claim 1, characterized in that the sensors consist of strain gauges ( 35 , 35 '). 3. A pusher centrifuge according to claim 1, characterized in that the sensors consist of fluid piston-cylinder units ( 42 ) which are provided with fluid pressure measuring devices ( 48 , 49 ). 4. A pusher centrifuge according to claim 1, characterized in that the sensors consist of piezoelectric force transducers ( 39 ). 5. A pusher centrifuge according to claim 1, characterized in that the sensors consist of laser displacement measuring elements ( 40 ). 6. Push centrifuge according to one of claims 1 to 5, characterized in that the connecting rod ( 22 ) consists of a substantially H-shaped lifting cross with two parallel connecting rod arms (23, 23 "23"; 24) and a central cross member ( 25 ) , in which the ends of the two parallel connecting rods (23, 23 "23 '; 24) are mounted on the one hand on the non-rotating thrust bearing housing ( 21 ) and on the other hand on the eccentric shaft of the lifting drive ( 27 ). 7. A pusher centrifuge according to one of claims 1 to 6, characterized in that the connecting rods ( 22 ) have recesses ( 33 , 33 '; 34 ) and / or cutouts ( 34 , 34 ', 34 ") in certain partial areas in which the Sensors are arranged. 8. A pusher centrifuge according to claims 6 and 7, characterized in that the parallel connecting rods ( 23 ") each have a central circular recess ( 33 '), each of which has two U-shaped, outwardly open recesses on the two outer edges of the parallel connecting rods ( 34 ") are assigned. 9. A pusher centrifuge according to claim 8, characterized in that in the circular recess ( 33 ) of one or both connecting rods ( 23 , 24 ) four strain gauges ( 35 ) are arranged diagonally opposite for a Wheatstone measuring circuit. 10. A pusher centrifuge according to claim 8, characterized in that in the four U-shaped recesses ( 34 ) of one or both connecting rods ( 23 , 24 ) four piezoelectric force transducers are arranged diagonally opposite for a Wheatstone measuring circuit. 11. A pusher centrifuge according to claims 6 and 7, characterized in that the parallel connecting rods each have a central circular recess ( 33 '), in each of which a U-shaped recess ( 34 ") with oppositely directed openings is arranged on both sides. 12. A pusher centrifuge according to claim 11, characterized in that in at least one opening of a U-shaped recess in an opposing arrangement a laser path measuring element ( 40 ) and a reflector element ( 41 ) are attached to the connecting rod ( 23 "). 13. A push centrifuge according to one of claims 1 to 12, characterized in that control signals for controlling a display and / or alarm unit are generated in the control unit ( 37 ) if a first thrust force limit value is exceeded. 14. A push centrifuge according to one of claims 1 to 13, characterized in that when a second thrust limit value is exceeded in the control unit ( 37 ) control signals for reducing the drive power of the linear drive (motor 32 ) are generated.