DE754532C - Schraemkette - Google Patents

Description

Inclined chain The invention relates to inclined chains with cutting edges Made of suitable high-quality cutting construction material for processing rock, lignite etc. Such cutting chains are usually made with many teeth, or cutting picks each with a cutting edge of approximately the same length, each pick at a different angle into the Chain link inserted, provided, to make a large number of grooves in the overall frame cut out. So far, the individual grooves have usually been even on the entire scrap distributed; at most it happened that the outer edges of the inclined joint increased through there Use of the cutting picks to be divided into smaller and closer together grooves. The Schram profile was always hollow, already through. the attachment of the picks conditional in the chain links.

There is also a version with multiple picks in each link group known, which in laterally equal head spacings in the chain links of the group are used. The generated scratch has grooves of the same width, measured in radians on the Schram profile. The middle pick is set stronger upwards; than would correspond to an arched overall scratch profile, and is therefore stronger than the ones left, -n- burdened.

The invention is in contrast to this. She refers to that Increase the cutting performance of the cutting chain. She exhausted all possibilities of the Increase in performance of the cutting chain as such. Your main idea is the individual Evenly load cutting edges, so that all cutting edges are still just under load permissible dimensions together achieve a higher cutting performance. than before, where only one or a few cutting edges were so, heavily loaded. There are different ways which lead to this goal; they can be walked each individually, they can but also went together. will. These different paths are now discussed below listed one after the other.

First of all: The individual teeth of the cutting chain are now in accordance with the invention arranged in such different lateral head spacing that the in the feed direction frontal cutting. Teeth, d. H. those that cut with an entering angle of about go ° Teeth, are arranged in a smaller mutual lateral head distance than the teeth working with a smaller setting angle, e.g. B. the outer cutting. Teeth. The individual teeth with different setting angles are in: such as the chip cross-section equation corresponding lateral head spacing arranged.

The drawing shows. an embodiment; it shows schematically the Schram profile p generated. of N teeth a (N means the number of teeth in a group that are inserted in different ways). After cutting a full group of teeth, the Schram profile is forward by f . moved to q: q is only drawn on the right half-page. f is the chip thickness in the middle of the Schram., is the chip thickness on the sides of the Schram. x is the respective width of the individual grooves. For the cutting point cutting at point c, x = b, ie equal to the smallest groove width; likewise, x is approximately equal to b at point d: in both cases the setting angle x (according to DIN 768) is equal or approximately equal to 50 °. In all other places -r grows; the more oblique the cut, ie the smaller the setting angle x, the larger x is. When the Schrampro: fil is drawn, the maximum value is at the outer position of the Schram.

L 'is the direction of advance. The direction of the cut is directed towards the viewer. The chip thickness - at the Schramaußen-; ending is determined by the equation = f - sin x .

The invention and with it the example cited are based on the observation that the central cutting edges break more often than the outer ones. This observation led to the following consideration: Some of the Schrämpicks sit on the front; partly at an angle, ie with a smaller setting angle x, in: the chain links. So far they have been so distributed. that all picks have cut out grooves of the same width, that is, that x was constant. The chips cut by the individual picks, however, were of different sizes, because namely. the chips were of the same thickness. The chips in the middle of the scratch were f thick, those on the outside of the scratch were f # x thick. The difference is greater, the more obliquely the picks were inserted. The middle, forehead working picks were therefore the most heavily loaded.

According to the invention, the middle picks are now relieved and the outer picks are more loaded, as far as possible in such a way that all the picks are equally heavily loaded. This can be achieved in practice. that each pick cuts out a chip of the same cross-section, so that the total joint is divided into grooves of unequal width. whose projection in the feed direction, however, results in grooves of the same width. The total tread width is then equal to s - v. The effective groove width is according to the chip cross-section law for all chips of the same cross-section.

The invention also consists in this. that in a constituent group with a well-known uniform side division measured in radians on the Schram profile x (here x = constant) several teeth for each of the frontal grooves to be cut one after the other at expediently equal intervals from the beginning of the group to the end of the group are used.

This is also a means of getting rid of the more heavily loaded central cutting edges to relieve. Furthermore, the invention also consists in that in a link group with a well-known uniform side division measured in radians on the Schram profile x (here also. x = constant) all teeth cutting with a large setting angle, d. b. the teeth cutting in the forward direction and the neighboring ones Teeth with more resistant cutting edges than the rest. z. B. with stronger and bigger ones Carbide plates are provided.

This is also possible. the more heavily loaded middle tailors as powerful as the external cutters. Do you work with pecking? with inserted hard metal pins, so you can for the Middle cutter a more powerful carbide type, a metal-ceramic type or diamond take as cutting material.

The following can be achieved through each of the specified embodiments Notable advantages: All pecks: are equally stressed. The permissible Performance is significantly higher than before because the most heavily burdened Middle cutter are relieved. You can achieve a higher cutting speed, larger feed and longer service life of the cutting edges.

Claims (1)

PATENT CLAIMS: 1. Cutting chain to increase the performance of cutting in the rock with cutting edges arranged on it or to be built in, made of useful high-quality cutting, building material, the teeth of which are used in such a way that they create a hollow, rounded overall cutting profile, - characterized in that the inner in the feed direction: g frontal teeth with go ° and about gd ° 'cutting angle (x) are arranged at a smaller mutual lateral head distance than the outer tame working with a smaller setting angle (x), so that by dividing the Schram profile into grooves of unequal width, each tooth has one in the other groove Cuts out the chip with approximately the same cross-section. z. Schrämkette consisting of chain links with teeth combined into groups, the teeth of a group cutting out the full profile and they are distributed in the group in such a way that they cut out this profile in individual grooves of equal width measured in radians on the profile: (x = constant) , characterized in that in it for the grooves to be cut with go ° or approximately 9o9 'setting angle, several teeth for cutting out the same groove are arranged one behind the other at suitably equal intervals within a link group, namely from the beginning of the group to the end of the group. 3. Schrämkette with cutting, characterized in that in a link group for the same groove width measured in radians on the Schramprofile (x = constant) all teeth cutting with go ° and approximately ga 'setting angle are provided with resisting cutting than the other teeth. To distinguish the subject matter of the invention from the state of the art, the following documents have been considered in the grant procedure: British patent specifications No. 19,453 v. J. 1913, 229807.