SU1759460A1 - Grinding members - Google Patents

Abstract

The invention relates to devices for grinding and grinding liquid materials with pasty inclusions in the chemical industry. SUMMARY OF THE INVENTION: Grinding elements include concentrically adjacent movable 1 and stationary 2 shells with screw cuts 3 and 4 on their outer 5 and internal 6 surfaces, while the screw cuts are made with different screw pitch. 1 hp f-ly, 3 ill.

Description

The invention relates to devices for grinding and grinding liquid materials with dough-like inclusions in the chemical industry, namely, to the production of viscose, where it can be used in installations to dissolve cellulose xanthate.

Grinding elements are known that include movable and fixed shells adjacently placed with cuts on their outer and inner surfaces (1).

The disadvantage of this technical solution is the low strength of the grinding elements.

The closest in technical essence and the achieved result are the grinding elements, including adjacent concentric placed mobile and fixed shells with screw cuts on their outer and inner surfaces (2).

The disadvantage of such grinding elements is the low strength of the shells due to

the coincidence in the projection of the external and internal screw cuts, creating a thin and, therefore, weak spot in the shell, that if a foreign body, such as a welding flash, hits between the mobile and fixed shell of a larger size than the gap between them, it leads to jamming and breaking shells on the weak point, i.e. from the end of the smallest cross-section of the interchannel partition.

The aim of the invention is to increase the strength.

The goal is achieved by the fact that, in known grinding elements including adjacent concentrically placed movable and fixed shells with screw cuts on their outer and inner surfaces, according to the invention, the screw cuts on the outer and inner surfaces of each shell have different screw pitch, projections the elevation angles of which are crossed within the height of the shell with the formation along its

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the perimeter of the all-closed power frame sawtooth form.

In addition, the width of the channels of the screw threads on the shells is made tapering in the course of their ascent, and the depth of the channels decreases in the same direction.

Making helical cuts on the shell on its outer and inner surfaces with different helical steps, the projections of the elevation angles of which are crossed within the shell height, form intersecting interchannel cylindrical sections, which increase the strength of the shell, and therefore grinding elements.

Formation around the perimeter of the shell of an all-closed power frame from interchannel cylindrical sections of its external and internal surfaces allows to increase the strength of the shell, and hence the grinding elements.

The implementation of an all-closed power frame in the form of a sawtooth form is an element that implements the mechanism of operation of the grinding elements, i.e. a mechanism whose official purpose is grinding.

Execution on sides of channels of screw cuts of variable shape, i.e. tapering along the ascent of the helical lines of the channels provides an increase in the cross-section of the interchannel cylindrical sections at their peaks, which increases the strength of the frame shell and, therefore, the grinding elements as a whole.

Figure 1 shows the grinding elements in the working position without drive and related parts; Fig, 2 - scan the outer surface of the shell; on fig.Z - scan the inner surface of the shell.

The grinding elements include adjacent concentric ones with a gap, and movable 1 and fixed 2 shells with screw cuts 3 and 4, respectively, on their outer 5 and inner 6 surfaces. The screw cuts 3 and 4 are made in the same direction. In this case, the direction of rotation of the moving shells 1 is opposite to the direction of lifting the screw cuts 3 and 4. On each side 1 (2) the screw cuts 3 and 4 on its outer 5 and inner 6 surfaces are made with different helical steps, the projections of the angles a {a @ which crossed within the height H of the shell 1 (2). On the moving shells 1 angle a screw cuts 3 on

the outer surfaces 5 are 48 °, and the angle / 5 of the lifting of the screw threads 4 on the inner surfaces 6 of these shells is 60 °. The height of the moving shells 1 is mm.

On the fixed shells 2, the angle a of the screw cuts 3 on the external surfaces 5 is 47 ° 23, and the angle ft of the screw cuts 4 on the internal surfaces 6 of these shells is 33 ° 20. Height of fixed shells

2 is mm.

Every two adjacent screw cuts 3 or 4 form interchannel cylindrical sections 7 and 8, respectively, on the outer 5 and inside 8 surfaces.

shells 1 and 2. Interchannel cylindrical sections 7 and 8 overlap each other and thus create along the perimeter of each shell 1 (2) a whole-closed power frame of a saw-like shape.

In addition, the width of the screw-cut channels 3 and 4 on all of the shells 1 and 2 along the rise of their screw lines is made tapering. The depth of the channels screw thread 3 and 4 on the moving

shells 1 are made decreasing in this direction. 9 - end on the loading side of the processed product, 10 end on the discharge side. The screw cuts 3 and 4 are divided by an inter-channel partition 11 and in FIG. 1 both combined in section are shown conventionally.

Work grinding elements as follows.

The operation of the strength mechanism will be considered on the example of movable shells 1, which work under more complex conditions and have thinner local cross sections. The operation of the strength mechanism of fixed shells 2 is similar.

During the rotation of the moving shells 1, they, capturing the processed product with screw cuts 3 and 4 from the end 9, move it through the channels of these cuts in the direction of discharge to the end 10. Exodus

from the height H of the shell 1 (2) and the selected angles of elevation of the helix lines of the outer 3 and inner 4 screw cuts form interchannel cylindrical sections 7 and 8, respectively, on the outer 5

and the inner side 6 of the shell 1 (2), which in plan overlap each other within the working height H of the latter, i.e. have intersecting projections.

This means that the interchannel cylindrical sections 7 and 8, which overlap each other, form along the perimeter of the shell 1 (2) of a single-piece power frame of a saw-like shape. The design of this power frame resembles an endless

a saw-tooth chain of strongly inclined and bound letters A of the alphabet of the Russian alphabet. Moreover, by virtue of the variable cross section of the screw thread channels 3 and 4, both in width, and in moving shells 1, and in depth, each individual power L-shaped element has thicker sections at its apex. In considering the strength mechanism of power L-shaped elements, the average inter-channel body of the partition 11 is not taken into account, since its presence goes to the margin of the overall strength of the shell 1 (2) and is the basis on which the power frame under consideration is superimposed on both its sides.

In the case of screw-threading 3 (4) of a foreign solid body, such as a welding flash, in one of the channels, which is larger than the gap A between the shells 1 and 2 and seized, a force arises between them that acts on the leg of the L-shaped force. an element that is displaced from to rotate it relative to the top of the force L-shaped element. But since the other leg of the subsequent L-shaped element is connected with the previous one, in our case with the loaded one, this loaded leg of the L-shaped element appears as if supported by the subsequent one. As a result, the force flow closes at the top of a triangle consisting of legs of L-shaped power elements and creating a strong frame of the shell 1 (2), which increases its overall strength. The foreign body, being wedged between the shells 1 and 2, either deforms itself to such an extent that it is able to exit the screw thread channel 3 (4), or deforms the inter-channel partition 11, remaining in the channel and the device with shells 1 and 2 continues to work, or wedge shells 1 and 2, and hence the device as a whole, without breaking the sheath 1 (2), which is a fairly acceptable case in an emergency.

Thus, each individual L-shaped power frame element, supported by the subsequent same element, increases the strength of the shell 1

(2) as a whole, which ensures its integrity when foreign bodies enter the processed product.

The use of the proposed technical solution in comparison with the prototype

allowed you to bring the following benefits.

Increasing the strength of the shell and, consequently, the device for grinding in general, where such grinding elements are used.

The possibility of forming functional elements of the shell by the method of precise casting, which expands the technological methods of manufacturing grinding elements.

The appearance of a variable channel shape on the sides of the grinding elements allows an increase in the degree of mechanical force on the processed product, which improves the quality of the processing of the latter.

Claims (2)

1. Grinding elements containing concentrically placed moving and fixed shells with screw cuts on their external and internal surfaces, characterized in that, in order to increase the strength, screw cuts on the external and internal surfaces Each shell has a different helical pitch, the projections of the elevation angles of which are crossed within the shell height with the formation of L along its perimeter of the whole-closed power frame of a saw-like shape. 2. Grinding elements according to claim 1, that is, with the fact that the width of the screw-cutting channels on the shells is made tapering along their rise, and the depth channels are decreasing in the same direction. B  L 777777 S 1QI 681 Figz