SK6044Y1 - Machinery screw - Google Patents

Abstract

The screw includes a front part (1), which is equipped with an axial located tip (2). The tip (2) is directly plain-bearing in the front part or through an axial supporting element (3).

Description

K 6044 -1

Technical field

The technical solution relates to the design of the screw node in machinery, in particular compaction machines, such as briquetting or pelleting presses for processing loose plastic and other materials of organic and / or inorganic origin. The technical solution from the construction site belongs to the field of mechanical engineering. From the point of view of application, the technical solution belongs to the field of processing and transformation of loose materials of organic and / or inorganic origin, briquetting or pelleting, application of rubber industry and plastics industry.

BACKGROUND OF THE INVENTION

Compaction technologies - briquetting, compacting and pelleting are based on high pressure material pressing with appropriate temperature, humidity and fraction size of the compacted material.

For example, a screw pelleting press described in German Patent DE 19619612 is known in the art. Further, a pellet and granule manufacturing apparatus is known in the Slovak patent SK 285 431.

For undemanding constructions the worms are monolithic or solid. This tip serves to guide the flow of already highly compacted biomass. The compaction process results in a briquette with a hole.

Pressing with screw briquetting presses of, for example, Pini & Kay manufacturers and the aforementioned patents, results in extremely high screw wear, where after 70 hours of pressing, high wear and breakdown of the screw end thread occurs. This drawback has been partially solved by the construction of a briquetting or pelletizing press with high screw resistance according to the Slovak patent SK 287 723, where the screws are of a folded construction. This means that the worms are two-part and multi-part with a threaded back, the central part of the worm that is replaceable and has a length of 1 to 2½ of thread. The front of the screw is also replaceable and has a length of 1 to 2½ of thread, with a taper at the end of the screw.

Conventional and conventional designs utilize the tip as part of a screw that is fixed to or otherwise bound to it. The tip rotates with the screw and therefore its thermal and abrasion stresses are very pronounced, which is reflected in the reduction of its service life and of the entire working screw. Due to the spike in the material being processed and the material being processed to move out of the nozzle only, carbonization of the material in the region of the hole occurs as a result of high friction. The material to be processed is very compact and imposes great resistance on the tool, which is overcome at the expense of reduced equipment performance.

Due to persistent problems with the tip of the screw, there has been room for the development of such a construction that would eliminate its drawbacks. As a result of this effort, the worm construction node in machinery such as compaction machines in particular for biomass, extrusion and plasticizing machines in the present utility model is described.

The essence of the technical solution

These drawbacks are overcome by the construction of a screw of machinery, such as compaction machines, in particular for biomass, but also of other machinery, in which the screw is an actuator such as in extrusion and plasticizing machines according to the present invention. The construction basically consists of a screw which is integral or multi-part and the essence of the construction is that the front part of the screw is provided with an axially mounted tip, which is supported therein in a radial plane directly or through a sliding axial support member. If the insertion tip is mounted on the face of the front of the screw, then the face of the front of the screw comprises a first sliding surface and the back of the axially mounted tip comprises a second sliding surface. In this case, the assembly does not include an intermediate - sliding axial support member and therefore the sliding surface material must be specially designed.

A more advantageous solution is provided if the front part of the screw is provided with an axially mounted tip which is supported therein in a radial plane by a sliding axial support member which is a spacer in the assembly. Then, there are several implementation possibilities of the sliding axial support member. In one case, it may be a sliding bearing, a sliding member with differently shaped surfaces, which is fixedly attached or wedged to the face of the front of the screw by one side in a variety of ways. For example, the sliding axial support member may have a radial shoulder in the form of a groove that fits into a complementary radial shoulder at the front of the screw. The alignment of the sliding axial support member with the front of the screw and the tip is ensured by both the sliding axial support member and the front of the screw and the tip having a central hole through which a fixed pin or screw passes. The rigid pin can only be loosely screwed on or screwed on. The sliding member with different shaped surfaces is made of a material with good sliding properties. A second realization option of the sliding axial support member is an axial roller bearing or a ball bearing.

For the purpose of this technical solution, the scope of protection includes all shape solutions of the screw, tip and other machine components. Also for the purposes of this technical solution, the scope of protection includes all constructional methods of design of the tip, axial support member and other structural parts of the machine.

The advantages of such a screw in the machinery, in particular in the biomass compaction machines according to the technical solution, are obvious from its external effects. The design eliminates wear of the front parts of the worms, where after a longer period of operation these worn parts of the worms in the length of 1 to 2½ of thread can be replaced. The tip is in the process stage, which can be called calibration-compaction. This makes the already processed material very compact and imposes great resistance on the tool. The tip only defines the shape of the space and the material only flows around it, i. j. it will not spin in the material. This reduces the process resistance, leading to increased system efficiency. In this case, wear of the screw tip and, in terms of thermo-mechanical stress, also eliminate the service life of the first screw threads, which are thermally conductive to the tip, which affects their operation.

BRIEF DESCRIPTION OF THE DRAWINGS

The screw of a compacting machine, in particular for biomass according to the invention, will be explained in more detail in the accompanying drawings, in which FIG. 1 is a cross-sectional view of an overall compaction machine assembly. In FIG.

a side view of the entire screw is shown. In FIG. 3 is a cross-sectional side view of the entire screw. In FIG. 4 shows a worm with a tip and a sliding axial support member. In FIG. 5, two sliding axial support members are shown schematically. In FIG. 6, two prongs are shown schematically. In FIG. 7 shows a further possible construction of the front part of the screw in an axonometric view. In FIG. 8 is a perspective view of a complete pointed screw.

EXAMPLES

It is to be understood that individual embodiments of the invention are presented for illustration and not as limitations of the invention. Those skilled in the art will find or be able to ascertain using no more than routine experimentation many equivalents to specific embodiments of the utility model. Such equivalents will also fall within the scope of the following protection claims. For the skilled person skilled in the art, the dimensioning of such a device and the appropriate selection of its materials and construction arrangements cannot be a problem, therefore these features have not been solved in detail.

Example 1

In this example of a particular embodiment of the subject matter of the invention, a first optimum constructional design of a screw of a compacting machine, in particular for biomass, shown in FIG. 1, which is a cross-sectional view of an overall compaction machine assembly including a removable tip screw. The front part 1 of the two-part screw is provided with an axially mounted removable tip 2 which is slidably mounted therein in a radial plane through the sliding axial support member 3, which is a spacer in the screw assembly, as shown in FIG. 2 and 3. The sliding axial support member 3 is in this case a sliding member with differently shaped surfaces, which is fixed by one side to the face of the front part 1 of the screw by a radial shoulder 4 in the shape of a groove that fits into the complementary radial shoulder at the front part 1, as shown in FIG. 4 and 5. The alignment of the sliding axial support member with the front of the screw 1 is provided with the tip 2, in that both the sliding axial support member 3 and the front of the screw 1 and the tip 2 have a central bore 5 through which the fixed pin 6 passes. 6 is only loosely engaged, but in an alternative embodiment of the solution it is screwed on the front part 1 of the screw, in which case it is essentially a screw. The tip 2 is a cone with graduated conicity as shown in FIG. 6. The slide with different shaped surfaces is made of a material with good sliding properties, for example of bronze.

Example 2

In this example of a specific embodiment of the subject matter of the invention, a first derived construction solution of a compaction machine screw, in particular for biomass, shown in FIG. 7 and 8. The construction is already sufficiently described in Example 1. The difference in construction lies in the different attachment of the sliding axial support member 3 to the front part 1 of the screw, as shown in the figure.

Example 3

In this example of a specific embodiment of the subject matter of the invention, a second derived constructional solution of a screw of a compacting machine, in particular for biomass, is described. The construction is already sufficiently described in Example 1. The difference in construction lies in the different implementation of the sliding axial support member 3, namely the axial roller bearing or an alternative spherical shoulder.

Example 4

In this example of a specific embodiment of the subject matter of the invention, a third derived constructional solution of a compaction machine screw, in particular for biomass, is described. The construction is already substantially described in Example 1. The difference in construction lies in the different placement of the tip 2 with respect to the face of the front part 1 of the screw. The assembly in this case does not include an intermediate sliding axial support member 3, and therefore the face of the front part 1 of the screw comprises a first sliding surface and the back of the axially mounted tip 2 comprises a second sliding surface. In this case, the sliding surface material must be specially designed.

Industrial usability

The machine screw finds utility in briquetting or pelleting of bulk materials of organic and / or inorganic origin, in the rubber industry, the plastics industry or also in the energy industry.

Claims (9)

PROTECTION REQUIREMENTS A machine screw, characterized in that the front part (1) of the screw is provided with an axially mounted tip (2), which is mounted therein sliding directly or via a sliding axial support member in the thirteenth week. A machine screw according to at least one of claims 1 and 2, characterized in that the sliding axial support member (3) is a sliding member with shaped surfaces. from Machine screw according to at least one of claims 1, characterized in that the sliding axial support member (3) is an axially rolling bearing. Machine screw according to at least one of claims 1, characterized in that the sliding axial support member (3) is a spherical bearing. Machine screw according to at least one of claims 1, characterized in that the sliding axial support member (3) is a sliding bearing. 2 2 2 (3). A machine screw according to claim 1, characterized in that the face of the front part (1) of the screw comprises a first sliding surface and the back of the axially mounted tip (2) comprises a second sliding surface. Third m 4th m 5th m 6th m Machine screw according to at least one of Claims 1,3 to 6, characterized in that the sliding axial support member (3) has a radial shoulder (4) and a central bore (5). Machine screw according to at least one of Claims 1,3 to 6, characterized in that the face of the front part (1) of the screw has a complementary radial shoulder and a central bore (5). Machine screw according to at least one of Claims 1 to 8, characterized by m 8th m 9th m s in that the fixed pin (6) or screw passes through the insertion point (2) and the face of the front part (1) of the screw in the axial axial center.