RU2474476C2 - Connection system between continuous grinders arranged in line in grinding plant - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: proposed grinding plant comprises multiple continuous-action grinders. Every grinder has initial material loading filler neck and suspension discharge outlet. Said filler neck and outlet are secured by fixed connector. The latter is connected with loader to communicate grinder discharge outlet with continuous-action grinder filler neck. Plant connector is jointed to appliances intended for preventing leaks of material from connector nearby discharge outlet and filler neck in material transfer from one grinder to next grinder. Said appliances are rotated driven by rotating discharge outlet and filler neck to interact with connector surface in area between connector and, at least, one of filler neck and discharge outlet to shift the material.

EFFECT: better tightness of filler and discharge tubes.

7 cl, 2 dwg

Description

The invention as a whole relates to a grinding plant, intended, in particular, but not only for this, for use in the preparation of ceramic mixtures. Such mixtures are usually obtained by wet grinding of raw materials (silica, feldspar, clay) and the addition of special additives to obtain a homogeneous suspension having the required granulometric properties of suspended powders.

As you know, this type of installation usually contains at least a shredder, which is equipped with a rotating drum, inside which the process of grinding the starting materials by collision, and, in any case, the interaction between the starting materials themselves and a certain number of generally spherical grinding bodies .

Known shredders are divided into continuous shredders and batch shredders, depending on whether the stages of loading the starting material into the drum and unloading the suspension are carried out continuously during the operation of the shredder or whether this occurs in a batch mode, which requires a temporary cessation of the production process and the rotation of the rotating drum.

This invention relates, in particular, to a grinding apparatus comprising continuous choppers.

From the prior art in the field of ceramic production, it is known that the grinding of raw materials is the execution of successive stages from the stage of destruction to the stage of fine grinding. At various stages, the grinding bodies used have different sizes, gradually decreasing from the destruction stage to the grinding stage, therefore, at each stage, such a rotation speed of the drum is used to optimize productivity, work time and energy consumption of the grinder.

In order to achieve the above, a prior art apparatus is known comprising a plurality of continuous shredders arranged in series, wherein the rotary drum of each shredder contains grinding bodies and rotates at a speed that is independent of the speed of the other drums in order to optimally perform one of the above steps grinding process.

A similar installation is described in detail in the Italian patent application RE2003A000013 in the name of the same applicant who is the applicant in this application, a reference has been made to the said application to provide the possibility of obtaining more detailed information.

In particular, each rotating drum of the installation described above is equipped with a loading neck for the material to be processed and a discharge neck for the suspension, while the necks are located on opposite sides of the drum and placed on its axis of rotation, while the necks rotate with the drum as a whole, which facilitates continuous movement downloadable source material and unloading the suspension.

In addition, the discharge neck of the middle (located between the other two) rotating drums is connected to the loading neck of the subsequent drum by means of a tubular connecting element, which is also connected to the loading device for introducing grinding bodies and special additives (for example, dyes) directly inside the next (subsequent) drum.

The disadvantage of such known installations is that the tubular connecting element, unlike the discharge and loading channels, which rotate together with the corresponding rotating drum, must be rigidly connected to the loading device and, accordingly, must remain stationary.

In fact, the free end of the discharge neck is axially inserted into the channel of the tubular connecting element, which, in turn, is placed inside the channel of the free end of the loading neck of the subsequent chopper.

With this configuration, the material moving between the rotating drum and the subsequent rotating drum tends to unplanned exit at the connection section of the first rotating drum and the tubular connecting element and at the connecting section of the tubular connecting element and the subsequent rotating drum.

The very nature of the suspension, which contains particles and abrasive materials, makes it difficult to achieve adequate tightness of the devices.

The purpose of this invention is to overcome the above disadvantage through a simple, rational and inexpensive solution.

This goal is achieved by means of a continuous grinding mill comprising a plurality of continuous choppers arranged in series, while the discharge neck of the chopper and the feed neck of the subsequent chopper are connected by means of a connecting element, while devices are provided to prevent the above-mentioned material from escaping between the connecting element ( 19) and the loading neck and discharge neck during the movement of the material from the previous chopper to the subsequent chopper.

In a preferred embodiment of the invention, the devices comprise a first spiral-shaped body attached to the free end of the discharge neck of the preceding chopper, so that said first spiral-shaped body is inserted inside the connecting element and together with part of the inner surface of the connecting element forms the first screw device that holds the material inside connecting element.

Additionally, the devices preferably contain a second spiral-shaped body located at the boot neck of the subsequent chopper and attached to it, while the second spiral-shaped body is inserted inside the boot neck of the subsequent chopper and together with such a boot neck forms a second screw device that prevents the material from escaping from the corresponding (distant) end of the connecting element.

Other features and advantages of the invention will become apparent after reading the description of an embodiment below, which is only a non-limiting example, provided with accompanying drawings in which:

Figure 1 presents a schematic drawing of a continuous grinding mill according to the invention,

figure 2 shows in detail the connecting system between the grinders according to the invention.

As shown in the drawings, the grinding apparatus of this invention, generally indicated by the number 1, comprises a plurality of continuous choppers 2 arranged in series.

Each chopper 2 contains a rotating drum 3, which is formed by a cylindrical body 4 with a horizontal axis of rotation, while the housing 4 is closed at one end with a first bottom 5 provided with an axial neck 6, which serves to load the material, and from the opposite end the housing is closed with a bottom 7 provided axial neck 8, which serves to discharge the suspension.

At each end, the rotating drum 3 is supported by a corresponding structure 9 and is driven by a special control system 10 by means of a belt system 11.

A grinding chamber is located inside the rotating drum 3, inside of which both grinding bodies and the starting materials from which the suspension will be composed, that is, essentially water, silica, feldspar, clay, are placed. The grinding bodies are usually made of silicon or aluminum and are subject to wear during operation of the unit when mixed with the suspension during processing.

Figure 1 shows that the previous (located first in the series) first chopper 2 is equipped with a conventional system 18 for loading raw materials, which is known, while the loading neck 6 of the second chopper, as well as any other chopper located further, is connected as discharge neck 8 of the previous chopper, and with a loading tube 20, which is connected to an additional loading device 21.

The loading tube allows you to separately add the grinding body in each grinder 2 continuous operation, and also allow you to separately (independently) enter the materials or water, which makes it possible to constantly adjust the composition of the mixture and ensure its optimal composition.

Each of the grinders 2 continuous operation of the installation 1 for grinding, as it works independently of the others, has an optimal size and is optimized in terms of geometry, size of the grinding bodies and speed of rotation so as to adapt its parameters to the specific grinding stage for which it is intended while the processed suspension continuously flows from the rotating drum 3 to the subsequent rotating drum 3 without interruption of work until the desired particle size distribution is achieved What are the characteristics of suspended powders.

The extraction of the crushed suspension from the chamber for grinding the rotating drum 3 is carried out using conventional devices of a known type, which are not described in further detail below. However, for the purposes of understanding the present invention, it is emphasized that although the extraction devices move the suspension towards the subsequent rotating drum 3, this movement is also carried out and is made effective by rotating the discharge neck 8 and the loading neck 6, which are firmly attached to the respective rotating drums 3.

As mentioned earlier, a fixed tubular connecting element 19 is located between the discharge neck 8 and the loading neck 6, while the connecting element 19 consists mainly of a tube connected to the supporting structure 9 by means of a rigid holder 25.

The parts listed below are rotatably connected to the fixed tubular connecting element 19: on the one hand, the discharge neck 8, on the other hand, the loading neck 6. As described in detail, the free end of the discharge neck 8 is axially inserted into the channel of the tubular connecting element 19, which in turn, introduced into the channel of the free end of the loading neck 6.

Thus, the discharge neck 8 is smaller than the fixed connecting element 19, while the connecting element 19 is smaller than the loading neck 6.

Between the discharge neck 8, the tubular connecting element 19 and the loading neck 6 can be placed suitable devices for creating tightness, while devices for creating tightness can make a significant contribution to preventing leakage of material from the installation 1.

In particular, as shown in FIG. 2, the first spiral-shaped body 23 is attached to the free end of the discharge neck 8 and to its outer surface, as a result of which the first screw device according to the invention is formed.

Thus, the first spiral-shaped body 23 rotates with the rotation of the chopper 2 continuous action, which is associated with the discharge neck 8.

In addition, the second spiral-shaped body 24 is attached inside the loading neck 6 of the subsequent chopper, as a result of which a second screw device according to the invention is formed.

Similarly to the first spiral-shaped body 23, the second spiral-shaped body 24 rotates with the rotation of the grinder 2 continuous action, which is connected to the loading neck 6.

During operation of the installation 1, the rotating drums 3 rotate independently of each other and engage in the rotation, respectively, the discharge neck 8 and the loading neck 6, while the tubular connecting element 19 remains stationary.

The first spiral-shaped body 23, which is connected to the discharge neck 8, rotates inside the first part of the connecting element 19.

The first spiral-shaped body 23 interacts with the inner surface of the connecting element 19 during the movement of the material and forms the first screw device that performs the function of holding the material inside the connecting element 19, and also prevents the unplanned exit of material from the corresponding (near) end of the tubular connecting element 19.

In addition, the second spiral-shaped body 24, which is connected to the loading neck 6, rotates inside the loading neck 6 and, interacting with the outer surface of the connecting element 19, forms a second screw device, which makes a significant contribution to preventing the exit of material from the corresponding (distant) end of the tubular the connecting element 19.

The features of this invention also provide advantages due to the fact that other material enters the connecting element through the loading tube 19.

In this invention, without going beyond its scope, as indicated by the above formula, modifications and improvements dictated by possible requirements for it or special cases can be made.

Claims (7)

1. Installation (1) for grinding, containing many grinders (2) continuous operation, each of which is equipped with a loading neck (6) for the source material and a discharge neck (8) for the suspension, while the loading neck (6) and the discharge neck ( 8) are arranged in series by means of a fixed connecting element (19), while the connecting element (19) is connected to the loading device (20, 21) and connects the discharge neck (8) of the grinder to the loading neck (6) of the continuous grinder at the same time, in the installation with the connecting element (19), devices are connected to prevent the exit of material from the connecting element (19) at the discharge neck (8) and at the loading neck (6) during the movement of material from the previous grinder to the subsequent grinder, while these devices are rotated due to the corresponding rotation of the discharge neck (8) or the loading neck (6) and interact with the surfaces of the connecting element (19) in the area between the connecting element (19) and at least one of said necks (8,6) for advancing material. 2. Installation (1) according to claim 1, characterized in that the devices for preventing the exit of material contain at least a first spiral-shaped body (23) connected to the free end of the discharge neck (8) of the previous chopper, while the first spiral-shaped body (23) is placed in the connecting element (19) and together with the connecting element (19) forms the first screw device, which, when moving the material, holds it inside the connecting element (19). 3. Installation (1) according to claim 1 or 2, characterized in that the devices for preventing the exit of material contain a second spiral-shaped body (24) connected to the free end of the loading neck (6) of the subsequent grinder, while the second spiral-shaped body (24) placed inside the loading neck (6) of the subsequent chopper and together with the loading neck (6) forms a second screw device that prevents the exit of material at the far end of the connecting element (19). 4. Installation (1) according to claim 2, characterized in that the first spiral-shaped body (23) is attached on the outside of the discharge neck (8) so that it can rotate when the chopper (2) is continuously operated, to which the discharge neck is connected (8). 5. Installation (1) according to claim 3, characterized in that the second spiral-shaped body (24) is attached on the inside of the loading neck (6) so that it can rotate when the grinder (2) is continuously operated, to which the loading neck is connected (6). 6. Installation (1) according to claim 1, characterized in that the loading device comprises a device (21) for loading material and a loading tube (20) that connects the loading device (21) with a connecting element (19). 7. Installation (1) according to claim 1, characterized in that the devices for creating tightness are placed between the discharge neck (8) and the connecting element (19) and between the connecting element (19) and the loading neck (6).

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