ITSA20070008A1 - TERTIARY, QUARTAR AND SECONDARY HAMMER MILLS FOR CRUSHING INHERENT AND FURTHER MATERIALS, CRUSHING, REVERSIBLE AND NOT, COMPLETELY IMPACT AND INCLINED LAUNCH, WITH ADDITIONAL IMPACT SPEED, WITH ANTIUSUR INVITATION PLATES - Google Patents

Description

Description of the industrial invention entitled:

"TERTIARY, QUARTAR AND SECONDARY HAMMER MILLS FOR CRUSHING INERT MATERIAL AND FURTHER CRUSHABLE MATERIAL, REVERSIBLE AND NOT, FULLY WITH IMPACT AND INCLINED LAUNCH, AT ADDITIONAL IMPACT SPEED, WITH ANTI-WEAR INVITATION PLATES WITH ANTI-WEARING POSITIONING FIXED BY MEANS OF DOVETAIL ATTACHMENT AND SYNCHRONIZED

Al MAIN HAMMERS, WITH ADJUSTABLE ECCENTRICS FOR WEAR COMPENSATION "

DESCRIPTION

The subject of this technical / illustrative report is the conception and the

operating principle of a "new" class of hammer mills (of which

the application patent is requested through this documentation

industrial) called: "TERZIARI HAMMER MILLS, QUARTARI E

SECONDARY FOR CRUSHING OF INERT MATERIAL AND FURTHER MATERIAL CRUSHERS, REVERSIBLE AND NOT, COMPLETELY WITH IMPACT AND INCLINED LAUNCH, AT ADDITIONAL IMPACT SPEED, WITH ANTI-WEAR INVITATION PLATES WITH VARIABLE POSITIONING, WITH ACCELERATING INSERTS OF SYNCHRANTING ATTACHED TO THE MAIN HAMMERS, WITH ADJUSTABLE ECCENTRICS FOR WEAR COMPENSATION ", The following will form part of this report:

- an introduction on the state of the art relating to mills for crushing inert material and further crushable material;

- the technical field and the purposes to be achieved with the present invention:

- a description and exposition of the operating principle of the present invention;

- the claims for which industrial protection is requested.

STATE OF THE ART: l HAMMER MILLS

The term crushing refers to the operation by which the inert material and / or further crushable material is reduced in size until marketable size is obtained. The machines used for crushing operations are called mills or crushers. Mulino is the noun used to define the invention in question.

In the course of this report, reference will continuously be made to inert materials only, thus highlighting the main field of application of the present invention, but nothing prevents the use of this equipment for further crushing materials (products for Lag annealing, etc.) .}.

The aggregates are stone, obtained from the crushing of suitable rocks, which are used, in the context of civil constructions, as aggregates for: • draining layers, crawl spaces, fillings;

• non-binding base layers, in road pavements;

• cement conglomerates;

• bituminous conglomerates etc ..

The finer parts are also used for the production of mortars, plasters and micronized.

For each of the aforementioned uses, they must meet suitability requirements concerning both the origin and nature of the rocks they belong to and the physical-mechanical characteristics of the individual elements. Crushing has very ancient origins. It was born from the time when man began to devote himself to the work of the land, from which he draws the major sources of his livelihood. In fact, the first mills belong to the prehistoric era; they consisted of a huge stone disk that was used for grinding the seeds.

Only later were other crushing machines developed, used in the mining field. The primitive metallurgies for the treatment of minerals used heavy stones, dragged on a circular track, by means of a carousel set in motion by human and / or animal force.

At present, crushing can be obtained by mechanical disintegrating action caused by: crushing of the stone between two jaws and / or resistant elements having a similar function: violent impact of the stone element thrown against a resistant wall; crushing of the aggregate caused by resistant elements (bars, heavy blades) set in motion together with the aggregate itself.

Given the size of the input elements in the feeder, to obtain the various sizes, from the largest (crushed stone) to the smallest (sand), it is necessary to proceed in successive stages.

It is possible to distinguish in:

- primary crushing,

- secondary crushing, which reduces what comes from the primary;

- Terni crushing, which reduces that coming from the secondary to a maximum size of about 30 mm (sand and filler etc ...).

The mills can, consequently, be classified with direct reference to the type of crushing practiced in:

- PRIMARY MILLS;

- SECONDARY MILLS;

- TERTIARY MILLS.

Then, depending on the system adopted for the disintegration of the material, we have:

- Simple toggle jaw mills; with double toggle: - Rotary mills;

- Impact mills;

- Hammer mills; bar; with cylinders; paddles etc ...

The main characteristic parameters of a mill are:

■ the size of the feeding mouth;

■ the reduction ratio obtained with the various adjustments;

■ net hourly production;

■ the necessary power (linked to the number of revolutions of the supply rotor and the efficiency of the system)

The subject of this report is a particular class of mills for crushing inert and non-inert material: TERZIARI, QUARTAR AND SECONDARY HAMMERS MUs. QUARTARIO IS THE TERM COINED TO DEFINE THE CRUSHING OPERATIONS WORKING ON PRODUCTS WITH UNITS LESS THAN A FEW MILLIMETERS IN DIAMETER (MAX 10MM SIZE INCREASE).

At present, the classic hammer mills are capable of processing maximum sizes that can be cataloged as tertiary. No hammer mill is able, today, to produce and program quartary grinding. The classic hammer mills are formed by a rotor equipped with hammers with the function of projecting the material fed against you armored walls of the external hull, causing its disintegration; a crushing chamber; the rotor hammers (number two or more), rotating the rotor at high speed.

The effectiveness of the operation depends on the paths undergone by the aggregate to be crushed. The first impact against the moving hammers, with a low percentage of crushed material, is followed by the projection of the crushing residues against the armor and other moving material; the most resistant elements are tightened between hammers and armor. The penetration of the aggregates, due to impact against the hammer face, is generally rejected by the hammer head due to the lack of synchronization between the incoming material and the hammers.

The hammer mills lend themselves well to the production of sand, gypsum grinding, limestone used as flux in the steel industry etc ... Their classic field of use is the terminal state of secondary and tertiary crushing.

CURRENTLY, HAMMER MILLS STILL HAVE SIGNIFICANT PROBLEMS. The main problems of the current condition of hammer mills lie in obsolete operating techniques. Since the equipment must guarantee the crushing of very hard material, it has always been thought to stiffen the external casing without ever conceptually intervening on the operating principle.The strong wear of the hammers and armored walls (due to the presence of tangential effects desired); the low production rate (resulting from a high recycling rate); a high, and sometimes excessive, formation of dust: the bad versatility of the final processing product; a non-homogeneous and unsuitable particle size due to the scarce presence of very thin parts with an excess of dust; crushing that is not able, and not controllable, to work on pieces of less than three millimeters in diameter (programmed production of fillers) are the main drawbacks of existing equipment and technologies, In addition to technical / production problems, there are problems related to safety in the workplace and environmental impact problems: the enormous quantity of poivere released during operation affects the ergonomics of the workplace and the health of workers. Despite the countless efforts made in the past, and the countless patent applications bear witness to this, it is not yet possible to define a consolidated strategy and technology in the industrial field capable of overcoming the aforementioned drawbacks.

We now pass to characterize the operating principle of traditional hammer mills.

To ensure the crushing of the aggregates, the hammers (generally two in number, and / or multiples to obtain the balancing of the equipment) integral with the motion of the main rotor must be equipped with a high peripheral speed (to obtain high force of first impact). This speed is directly proportional to the number of revolutions of the rotor.

In the secondary mills, in order to be able to treat the crushed stone up to a minimum size of about thirty mm in diameter, a peripheral speed of the hammers of not less than 40 ÷ 50 m / sec is required, while in the tertiary ones, for sizes less than thirty mm mm in diameter, it is necessary to reach at least double speeds of about 70 ÷ 80 m / sec. However, the modulus of this speed assumes such high values as not to allow an easy and complete passage of the material coming from the loading hopper. High speeds create an interference phenomenon. The material is rejected by the hammer and channeled between the maximum perimeter circumference of the hammer and the armor wall, until it is subjected to the crushing phenomenon. In addition, a high percentage of aggregates, not hitting the face of the hammer, bypasses the first reduction in particle size.

The extreme precision required to allow a frontal impact on the face of the hammer and avoid the onset of tangential stresses, which also causes wear of the hammer and unscheduled reduction of the inert size, requires an excessively small entry time (obviously adjustable through a speed input).

Necessity and impossibility of high speeds, high efforts involved, particle size that does not meet the design requirements are the cause of malfunctioning of the existing equipment. The following paragraphs will deal in detail with the application and the proposed invention.

PURPOSE TO BE ACHIEVED WITH THIS INVENTION

Object of the present invention are tertiary, quartary and secondary hammer mills in the construction and agricultural sectors. Such hammer mills are capable of producing commercially advantageous micronized materials. Operation that, today, no mill is able to perform.

The operating principle at additional impact speed undergoes, with the present invention, some expedients and modifications which allow it to obviate the classic drawbacks of these apparatuses and to expand the field of application. Classic drawbacks are: excessive wear of the hammers and the inadequate (and not predetermined) grain size of the final product, excessive tooling times, excessive wear of the elements involved.

Throughout this paragraph, reference will continuously be made to a primary rotor (indicating with this term the rotor that receives drive power by means of a pulley and V-belt from the power supply system) and a secondary rotor (indicating the rotor that receives motion through the pulley and belt toothed by the primary rotor). In the next paragraph, the components of the equipment for which industrial protection is requested will be dealt with in detail.

Following the realization of a physical prototype of the equipment, and the implementation of some tests carried out on a sample (exhaustive of the type of material to be treated in the industrial field) of aggregates, it is possible to highlight a series of advantages obtainable through the principle of operation. It should be emphasized that the classical advantages obtainable by means of the previous equipment working at an additional speed of impact are added the advantages deriving from the measures required for industrial protection.

In the remainder of this paragraph, in order to emphasize the advantages of the aforementioned invention, we will separately discuss the advantages deriving from a classical apparatus with additional impact speed, compared to traditional hammer mills with single effect, and the advantages deriving from an apparatus as per proposed invention, compared to an additional impact speed mill.

Schematically, the advantages of a hammer mill with additional impact speed compared to traditional equipment are:

- Double production per hour compared to traditional mills with new hammers;

- Very low recycling:

- Granulometry (material fineness module) programmable according to the impact speed;

- Excellent versatility of the final product.

- Increased duration of wear parts:

- Reduced dust emission (significant percentage of abatement compared to a traditional hammer mill).

The proposed invention proposes to add considerable advantages compared to an equipment with an additional impact speed, in particular it is possible to identify:

A. Facilitation of inlet flows by means of wear plates with variable positioning;

B. Introduction of wear-resistant steel tube to position inserts by centrifugal fixing;

C. Insertion of wear-resistant steel tube inserts through centrifugal fixing (with dovetail attachment):

D. Compensation of wear on accelerating inserts by means of adjustable eccentrics

E. Hammer wear reduction through adjustable eccentricity adjustment:

F. Increase of machining forces and powers:

G. Increased service life of hammers and accelerating inserts:

H. Increase in maintenance and reductions in re-tooling times (reduction in the number of components and simplification of maintenance operations);

I. Increase of the safety factor,

J. Lower effect of environmental impact due to granulometric programming and reduced power of use.

In detail:

A The presence of plates (invitation plates) with variable and adjustable positioning favors optimal feeding to the secondary rotor (feeding at full load); secondary rotor equipped with accelerating inserts and integral with the motion of the main rotor by means of a toothed belt;

B The replacement of a cylinder with bolted inserts for conveying the feed material (see classic equipment with additional impact speed) through the use of a wear-resistant steel tube integral with the secondary rotor shaft, by means of fixing bushings outside the mill casing, and equipped with grooves for dovetail coupling of the inserts, is one of the main advantages of the above invention. The locking of the inserts takes place through the sole action of centrifugal force. The considerable reduction in weight, due to the replacement of the cylinder and of the relative locking systems of inserts with the tube equipped with grooves for dovetail coupling, the positioning of the inserts, by means of a dovetail attachment, with centrifugal fixing allow a considerable reduction of the vibrations involved with consequent reduction of noise pollution and increase of the ergonomics of the workplace, allow considerable advantages in maintenance (reduction of the number of components), assembly of spare parts (elimination of fixing times). The introduction of the wear tube, on which to fix the inserts, has a further advantage: it protects the shaft of the secondary rotor from wear. The tube, in fact, mounted with a clearance of a few millimeters on the secondary rotor, has a protective function for the aforementioned organ.

C To avoid high wear, both of the inserts on the secondary rotor and of the hammers integral with the main rotor, which require frequent maintenance interventions (retooling and / or replacement of inserts / hammers and / or inversion of the main rotor motion), the introduction of the eccentric inserts wear compensation allows the gradual setting of the operating point in relation to the optimal kinematics,

D By adjusting (externally) the angle of incidence and the light between accelerating inserts and eccentric inserts to compensate for wear, it is possible to calibrate the incidence of internal efforts. The position of the eccentrics can be adjusted to ensure the best direction of the aggregates to the face of the hammer; the position of the registers can be adjusted in order to obtain an almost normal impact between the aggregates and the surface of the hammers, reducing the wear of these (minimization of tangential stresses and wear work).

E The contemplation of tool compensation allows the extension of the useful life of the accelerating inserts (the wear of the inserts is adjusted by adjusting the modulus and direction of the eccentricity in order to guarantee constant light between registers and accelerating inserts) and of the hammers (the phasing of the equipment, defined in the project field, it allows to obtain almost normal impact between hammers and aggregates and to avoid excessive presence of tangential stresses due to excessive wear of the hammers).

F The adjustment of the angle of incidence of the aggregate on the hammer surface, through the insertion of wear compensation eccentrics, allows an increase in the forces involved and the possibility of working even in pieces of a few millimeter diameter units (quartary ).

G The possibility of extending the useful life of the elements subjected to wear, combined with the reversibility of the motion (capable of exploiting double impact surfaces) requires a reduced number of interventions. The adjustment by means of eccentrics allows the accelerating inserts to be used in conditions of wear up to 2 cm. Such a configuration would be unacceptable in devices without regulation.

H The adoption of dovetail accelerating inserts integral with the motion of the secondary rotor and fixed (by dovetail coupling) to it by the automatic effect of the action of the centrifugal force alone, allows a quick replacement of the same. The procedure does not require subsequent machine stop operations to tighten and retighten the accelerating inserts (this is necessary if the inserts are constrained by bolts and / or other devices),

I The reduction of maintenance interventions is the fundamental prerequisite for raising the safety level. In addition, the technical solutions hypothesized in this configuration require fewer components, compared to traditional configurations with an additional impact speed, whose intervention procedures that were safer (elimination of any containment cylinders and / or tightening systems);

J The calibration of the granulometry of the aggregates and the registration of the inserts, in order to reduce the sliding effects, allow to obtain the finished product in shorter times, with less production and emissions of dust and a characteristic index of environmental impact that is decidedly better (lower consumption energy, less recycling etc ...).

DESCRIPTION OF THE INVENTION IN REALIZATIONAL AND FUNCTIONAL FORM

In this paragraph, the invention will be described in embodiment with reference to the attached drawings (FIGURE 1 - FRONT VIEW; FIGURES 2 - 3-4 - 5 - 6, DIAGRAM AND PHASES OF MOTION), which refer to the operating principle of which industrial protection is requested.

The tertiary, quartary and secondary hammer mill for inert material and further breakable materials, reversible and non, fully impact and inclined throw, at additional impact speed, with accelerating wear inserts fixed by dovetail attachment and synchronized to the main hammers , with adjustable eccentric for wear compensation, it consists mainly of the following parts:

- Bearing structure, covered with plates in wear-resistant material, - Loading hopper, complete with load feeder;

- Entry plates for conveying the incoming material towards the launch area, devices and support for the shafts of the moving parts (pulleys and toothed belt for motion to the secondary rotor);

- Main rotor. This rotor is made up of the following parts:

o the anti-wear protections (flywheel covers);

o the two hammers integral with the motion of the rotor itself;

- Secondary rotor. This rotor, placed above the primary rotor, is equipped with a relative peripheral with tapered inserts (the tapering facilitates the entry of the material) in the same number as that of the hammers.

The two rotors are connected and forced to perform the same number of revolutions in the unit of time (phased), by means of special transmission pulleys and toothed belt;

- Wear-resistant steel tube, integral with the motion of the secondary rotor towards which it acts as a protective wear-resistant shell and locked to the outside of the casing by bushings, equipped with grooves for dovetail fastening of the accelerating inserts;

- Accelerating inserts integral with the secondary rotor by means of a tube with dovetail fixing by effect of the centrifugal force alone;

- Transmission parts for rotary movements (pulleys and toothed and trapezoidal belts);

- Wear compensation eccentrics in wear-resistant steel;

- The armor and all those other mechanical parts currently present in each mill that are not referred to here. Keep in mind that, not having crushed, the approach registers of the armored walls fundamental for traditional mills, no longer have a reason to exist; these walls will be fixed, at a distance of about 50 mm from the hammer, both for the secondary mill and for the tertiary and quartary sectors. - The carcass of the mill contains all of the above.

Listed in a schematic and synthetic way the elements making up the equipment under examination, let's now pass to the description of the OPERATING PRINCIPLE

For the sake of simplicity in the description below, reference will be made only to the tertiary mill, as the secondary and possibly quartary mills are of similar construction and adopt all the principles of tertiary mills.

The feeding of the mill takes place by gravitational fall in the upper part, open, through a loading hopper with a normal feeder (not object of this patent), the material, from the feeding arrives to the accelerating inserts integral with the secondary rotor. The height of fall and the inclination of the guide plates is calculated bearing in mind that in the time between one stop and the next the inert material, in fall, must cover a path equal to the depth of the inserts in the radial direction. to avoid energy waste and allow full operation.

The lead plates direct the aggregate within the maximum peripheral of accelerating inserts.

The task of the accelerating inserts is to considerably increase the inlet speed of the aggregate in the crushing chamber, avoiding the repulsion of the material due to the high rotation speeds involved. Once intercepted by the accelerating inserts, the aggregate is forced to follow a circular trajectory (defined by the diameter of the inserts themselves) which, due to the high speeds and centrifugal force, is positioned along the external periphery and then launched along the facade. of the hammer. The main characteristic of this second rotor and of the inserts is to receive the aggregate from above, to invite it along a circular trajectory and throw it against the face of the hammers of the mill, not vertically, but in a direction almost perpendicular to the face of the hammer ( avoiding the onset of tangential stresses that perform wear and tear). The aggregate is thus accelerated and acquires a speed equal to the peripheral speed of the inserts.

At this point the two accelerating insert wear compensation registers come into play. The wear compensation adjusters (manually adjustable through the clamping system) deflect and direct the aggregate coming from the accelerating inserts against the hammers which rotate in the opposite direction with respect to the inserts with which they are integral. The deviation allows the collision in almost normal conditions between the hammer and the inert.

For the correct functioning of the crushing principle, a synchronization operation must be performed between the movement of the accelerating inserts and the rotation of the hammers. Said phasing operation takes place by setting the position of the hammers with respect to the accelerating inserts by defining the phase of the toothed pulleys. Through the phasing of the system, and above all the compensation of the wear of the accelerating inserts, the impact is guaranteed under almost normal conditions. An initial impact / conveyance against the accelerating inserts and secondary against the hammers, is followed by a final and definitive impact against the armor plates of the structure.

Reference marks for the positioning of the compensation registers will be created in order to allow an appropriate setting of the system and an adequate compensation of the wear of the accelerating inserts.

Regarding the percentages of re of the inert material, on this type of technology it can be said that we have a very low quantity of recycled materials.

The reversibility of the system (clockwise and counterclockwise of feeding), capable of exploiting the double feeding direction and the double impact surface, is guaranteed by the symmetry of the equipment.

By specifying in detail the physical characteristics of the equipment for which an industrial application patent is requested, we can, in this context, specify that the prototyped equipment is capable of processing micronized materials (and therefore defined quartan sizes) reaching a peripheral speed of over 110m / sec. The motion transmissions between the main and secondary axes occur through pulleys and toothed transmission belt capable of supporting the enormous loads involved and limiting the acoustic impact of the device. The eccentrics are bolted, with a hole in the form of a slot for registration, to the frame of the structure through two adjustable bolts equipped with a locking system. The whole structure is made of highly wear-resistant material.

The above dimensions refer to tertiary / quartary mills and undergo slight changes in the case of secondary mills. Industrial application characteristic of this structure are the plants for the production of cements, mortars, sands, fillers, micronized etc ..., or all those applications where the intervention of a material crushing equipment is required.

Claims (1)

CLAIMS AS PER INDUSTRIAL PATENT APPLICATION: 1. Tertiary, quartary and secondary hammer mill, for crushing inert material and further crushable material, reversible or not, completely impact and inclined throw, at additional impact speed, consisting of a loading hopper and the carcass that contains a main rotor; invitation plates with variable inclination depending on the characteristics and quantity of the aggregate; wear protection (flywheel covers); a main rotor; the number two hammers; the armored walls; a secondary rotor (integral with pulleys and toothed belt to the motion of the main rotor), characterized by the fact that said secondary rotor mounts a wear-resistant steel tube equipped with tapered inserts (integral with the motion of the secondary rotor by means of dovetail attachments with centrifugal tightening ) in the same number as that of the hammers; inserts to direct and accelerate the incoming material; a wear-resistant steel tube to protect the secondary rotor shaft equipped with grooves for inserting inserts by means of a dovetail attachment; a symmetrical system of accelerating insert wear compensation, by means of adjustable eccentrics for wear compensation. II Tertiary, quartary and secondary hammer mill, for crushing inert material and further crushable material, reversible or not, completely impact and inclined throw, at additional impact speed, characterized by the fact that the aggregate, coming from a hopper of load, is directed onto the accelerating inserts (integral with the secondary rotor by means of an anti-wear tube, locked to the outside of the casing by means of bushes and provided with grooves for interlocking dovetail inserts by centrifugal force action) conveyed along the length of the inserts and projected by effect of the centrifugal force along the maximum peripheral curve, is directed, due to an impact with the compensation register, at an additional speed with respect to the effect of the driving component alone on the face of the hammer suitably phased. III Tertiary, quartary and secondary hammer mill, for the crushing of inert material and further crushable material, reversible or not, completely impact and inclined throw, at additional impact speed, characterized by the fact that the position of the wear compensation eccentrics can be adjusted in eccentricity in order to compensate for the wear of the accelerating inserts and guarantee an optimal operating point. IV. Tertiary, quartary and secondary hammer mill, for the crushing of inert material and further crushable material, reversible or not, fully impact and inclined throw, with additional impact speed, characterized by the fact that the secondary rotor is provided with an anti-wear protection by means of a wear-resistant steel tube with grooves for dovetail coupling of the accelerating inserts. V. Tertiary, quartary and secondary hammer mill, for the crushing of inert material and further reversible and non-breakable material, fully impact and inclined throw, with additional impact speed, characterized by the fact that the fixing between the secondary rotor and accelerating inserts takes place on a wear-resistant steel tube, integral with the motion of the aforementioned rotor, by means of dovetail fixing due to the effect of soy centrifugal force. YOU. Tertiary, quartary and secondary hammer mill, for the crushing of inert material and further material to crush them, reversible or not, completely with impact and inclined throw, at additional impact speed, characterized by the fact that it is possible to exploit a wear of over 20 mm of the accelerating inserts without altering the optimal operating conditions. VII. Tertiary, quartary and secondary hammer mill, for the crushing of inert material and further crushable material, reversible or not, fully impact and inclined throw, with additional impact speed, characterized by the fact that it is VIII. Tertiary, fourth and secondary hammer mill, for the crushing of inert material and further crushable material, reversible or not, completely impact and inclined throw, with additional impact speed, characterized by the fact that thanks to the wear adjustment system the throw of the material is almost perpendicular to the face of the hammers, reducing their wear and increasing the operating time of the hammers. IX. Tertiary, quartary and secondary hammer mill for the without intervention of additional external driving force, crushing effects and additional crushing powers compared to a single-acting system. X, Tertiary, quartary and secondary hammer mill, for the crushing of inert material and further reversible and non-breakable material, completely impact and inclined throw, with additional impact speed, capable of reaching speeds such as to allow the processing of micronized materials and materials defined as quartaries in a commercially advantageous way. XI. Tertiary, quartary and secondary hammer mill, for crushing inert material and further crushable material, reversible or not, fully impact and inclined throw, with additional impact speed, characterized by the fact that the maintenance times and the number of elements at stake are, due to the wear compensation and tightening devices by means of centrifugal force alone, considerably reduced and in greater safety.