EP1227890B1

EP1227890B1 - Roller mill for grinding granular materials, particularly cereals

Info

Publication number: EP1227890B1
Application number: EP00974411A
Authority: EP
Inventors: Silvano Barbieri
Original assignee: AGREX SpA
Current assignee: Agrex SpA
Priority date: 1999-11-02
Filing date: 2000-10-18
Publication date: 2005-12-21
Anticipated expiration: 2020-10-18
Also published as: DE60025025T2; AU1273101A; MXPA02004340A; BR0015253B1; IT1307416B1; ITPD990243A1; EP1227890A1; WO2001032312A1; DE60025025D1; RU2264261C2; BR0015253A

Description

Technical Field

The present invention relates to a roller mill for grinding granular materials, particularly cereals such as corn, wheat and the like, according to the preamble to main Claim 1.

A mill of this type, such as is known from GB-A-369 477, typically comprises one or more pairs of contrarotating rollers defining, between their cylindrical surfaces, a gap into which the material to be ground is fed, and a feed device disposed above the rollers for feeding the flow of material to be ground into the gap.

Background art

Within the specific technical field of the present invention, one of the main requirements during the use of roller mills for grinding cereals is to ensure maximum uniformity of the supply of the material to be ground between the rollers in order to optimize the output yield of ground material. This requirement translates into the aim of achieving a supply of material which is as steady as possible, is free of fluctuations, and is distributed as uniformly as possible over the entire longitudinal extent of the rollers.

There are known mills for grinding granular materials which provide for the use of vibrating feed devices in which the material is supplied to the mill by falling from a feeder in which a vibratory motion is produced. An example of such a vibrating feeder is known from German patent application No. 3741-984. This provides specifically for the flow of material supplied to the crushing members of the mill to be modulated by the vibratory motion imparted to the feeder so that it is supplied in successive waves generated in sequence and in phase with the frequency of rotation of the mill. However, this solution is not optimal for use in mills for grinding cereals in which a uniform and steady supply of the flow of material to be ground is required.

Disclosure of the invention

The object of the present invention is to provide a roller mill for grinding cereals which is designed structurally and functionally so as to overcome the disadvantages complained of with reference to the prior art mentioned and to satisfy the requirements indicated, achieving an improved uniformity of distribution and supply of the material being ground.

This object is achieved, according to the present invention, by means of a roller mill having the characteristics set out in the appended claims.

Brief description of the drawings

The characteristics and the advantages of the invention will become clearer from the detailed description of a preferred embodiment thereof, described purely by way of non-limiting example with reference to the appended drawings, in which:

Figure 1 is a partially-sectioned, perspective view of a mill with contrarotating rollers, according to the invention,

Figure 2 is a partially-sectioned, perspective view of a detail of the mill of Figure 1,

Figures 3 and 4 are partially-sectioned, perspective views of a detail of Figure 2,

Figure 5 is a side elevational view of the detail of Figures 3 and 4,

Figure 6 is a front elevational view of a detail of Figure 5.

Best mode of carrying out the invention

With reference initially to Figure 1, a mill with contrarotating rollers 2 for grinding granular materials, particularly cereals such as corn, wheat and the like, is generally indicated 1. The rollers 2 are supported rotatably on a fixed framework 3 of the mill.

A working gap 4 is defined between the cylindrical surfaces of the rollers and the flow of material to be ground is fed into the gap 4 by means of a feed device generally indicated 5. The device comprises a hopper 6, defined by a partially inclined base 6a and side walls 6b, for holding the material to be ground. The material is loaded into the hopper through a loading hole 7 and is supplied to the rollers 2 from an opening 8 having a gate 9 which can pivot to a limited extent and the function of which will become clearer from the following description.

Deflector plates 10a, 10b, 10c are provided between the feed device 5 and the rollers 2 for directing the flow of material being ground into the working gap 4 of the rollers.

The hopper 6 is supported so as to be pivotable on the framework 3 of the mill by support means comprising respective first and second pairs of

arms

11, 12.

The support arms 11 are articulated, at their opposite axial ends, to the fixed framework 3 and to the hopper 6, in the region of the opening 8 for supplying the material. Each support-arm articulation point preferably has a flexible coupling, for example, made of rubber. Each support arm 11 is also arranged axially along an axis substantially parallel to the direction, indicated by the arrow A in Figure 4, in which the material to be ground falls from the hopper, thus permitting a pivoting movement predominantly along an axis transverse the direction of falling A.

The support arms 12 have opposite axial ends articulated to the fixed framework 3 and to the hopper 6, respectively, on the side remote from the opening 8. These support arms 12 also preferably have flexible couplings at their articulation points and each extends axially along an axis, indicated B in Figure 5, which intersects the direction of falling A and is therefore such as to allow the hopper to pivot transverse the axis B.

The pivotable support of the hopper 6 by means of the

arms

11 and 12 enables it to perform a combined pivoting movement given by the resultant of the individual pivoting movements permitted by the

arms

11 and 12, respectively.

Each support arm 12 is also acted on resiliently by a respective spring 13 acting between the framework 3 and an intermediate portion of the corresponding arm 12. The spring 13 is arranged in a manner such that its resilient action has a predominant component directed perpendicularly to the axis B of the axial extent of the arms 12, as well as tangentially relative to the path of pivoting of the arms.

The mill according to the invention further comprises drive means, generally indicated 14, associated with the hopper for bringing about a vibratory motion thereof, as will be explained in the following description.

The drive means 14 comprise a transmission having one or more belts 15 and disposed between first and second parallel and spaced-apart shafts, indicated 16 and 17 respectively. The shaft 16 is supported for rotation on the hopper 6 by means of a pair of bearings 18 so as to have an axis of rotation X parallel to the axes of articulation of the

arms

11, 12. An eccentric mass 19 is mounted on the shaft 16 between the bearings 18 and is formed by two disks 19a, 19b which are keyed to the shaft 16 and fixed together releasably so that their relative angular positions can be adjusted. This adjustment serves to vary the eccentricity of the mass 19 relative to the axis of rotation X.

A pulley 20 is keyed to the shaft 16 outside the bearings 18 and is engaged by the belts 15 for transmitting the rotary motion to the shaft 16. The belts 15 extend in endless loops around a second pulley 21 keyed to the second shaft 17 which has an axis of rotation Y and constitutes the drive shaft of the belt transmission. The drive shaft 17 is preferably the shaft provided for transmitting the drive to the rollers 2 of the mill.

As shown in Figure 5, the axes of rotation X, Y of the

shafts

16, 17 are disposed in a plane, indicated by the axis C, which is approximately parallel to the longitudinal axis B of each support arm 12, or has a slight inclination to the axis B. Moreover, the positioning of the belt transmission relative to the hopper is selected in a manner such that the axis X of rotation of the eccentric mass 19 is offset, relative to the axis of articulation of the arm 12 to the hopper 6, on the side remote from the spring 13 (see Figure 5). The shaft 17 is rotated in the direction of rotation indicated by the arrow E of Figure 4 so that respective pulling portions 15a of the belts 15 are defined, relative to the plane containing the axes X and Y, on the side remote from the arms 12.

In operation, by virtue of the pulses generated by the rotation of the eccentric mass, the hopper 6 is subjected to a combined vibratory motion limited by the pivoting permitted by the

support arms

11, 12. Within the limits of the pivoting motion permitted by the arms 12, two predominant components are defined in the vibratory motion of the hopper and are directed substantially perpendicularly to the plane C, in the direction of the arrow D and in the opposite direction D' of Figure 5, according to the angular position of the eccentric mass during its rotation. It should be noted that, during the pivoting movement in the direction D, the springs 13 act on the hopper in compression, contributing to the pivoting in this direction, whereas the belts 15 and, in particular, the portions 15a, act as travel-limiting elements. When the motion is reversed from the direction D to the direction D', however, the portions 15a of the belt help to return the hopper resiliently, by means of the tension present in them, contributing to the rapid reversal of the pivoting movement of the hopper.

In operation, by virtue of this vibratory motion, the material in the hopper 6 is conveyed to the opening 8 and is supplied through the opening in order to fall towards the rollers 2. The pivoting gate 9 serves to even out the flow of material towards the opening 8 and has front apertures 9a for the outlet and discharge of accumulated material should the hopper 6 reach an "over filled" condition.

Experimental tests carried out by the Applicant have shown that the combined effects of the belt transmission in bringing about the vibratory motion of the hopper produced by the rotation of an eccentric mass achieve many advantages in comparison with known arrangements.

In particular, a substantially continuous, fluctuation-free supply of the material is achieved. The material to be ground is supplied to the rollers in the form of a continuous "film" distributed uniformly over the entire axial extent of the cylindrical surfaces of the rollers. This advantageously reduces production costs considerably and achieves high output rates with larger output yields of ground material than in known arrangements. It was also found that there were fewer fluctuations in the distribution and supply to the rollers in the presence of materials with different characteristics of weight and moisture content.

Claims

A roller mill for grinding granular materials, particularly cereals, comprising:

at least one pair of contrarotating rollers (2) between which a gap (4) is defined for the passage of the material to be ground,

feed means (5) arranged for supplying a flow of material to be ground between the rollers (2), and

drive means (14) associated with the feed means (5) for bringing about a vibratory motion of the feed means so that the flow of material to be ground is fed by falling into the gap (4) between the rollers (2),

characterized in that the drive means comprise:

a shaft (16) which is supported rotatably on the feed means (5) and on which there is at least one mass (19), eccentric relative to the axis of rotation of the shaft (16) and fixed for rotation with the shaft (16), and

belt transmission means (15) for rotating the shaft (16) about its axis of rotation and bringing about the vibratory motion of the feed means (5) by the rotation of the eccentric mass (19).
A mill according to Claim 1, in which the feed means comprise a hopper (6) for holding the material to be ground, and support means (11, 12) are provided for supporting the hopper (6) pivotably on a fixed framework (3) of the mill.
A mill according to Claim 2, in which the support means comprise at least one support arm (12) having opposite axial ends articulated to the framework (3) and to the hopper (6), respectively, the transmission means comprising at least one first pulley (20) mounted on the shaft (16) and at least one second pulley (21) mounted on a second shaft (17), the transmission belt (15) extending in a closed loop around the two pulleys (20, 21) and the plane containing the axes of rotation of the shafts (16, 17) being substantially parallel to the longitudinal axis of the support arm (12).
A mill according to Claim 3, in which there is at least one pair of support arms (12) for supporting the hopper (6) so that it can pivot relative to the fixed framework (3) of the mill, the arms (12) being spaced apart and parallel to one another and having opposite axial ends articulated to the hopper and to the fixed framework, respectively, resilient means (13) acting between the framework (3) and each respective support arm (12).
A mill according to Claim 4, in which the resilient means comprise, for each support arm (12), at least one spring (13), the resilient action of which has a component which is directed along an axis substantially perpendicular to the plane containing the axes of rotation of the shafts (16, 17), and is disposed between their axes of rotation.
A mill according to any one of Claims 3 to 5, in which the first shaft (16) is arranged for receiving the rotary drive from the second shaft (17) by means of the belt transmission (15).
A mill according to any one of Claims 3 to 6, in which the second shaft (17) is arranged for rotating the rollers (2).