NO130124B - - Google Patents

Description

Sole, especially for tiles.

The present invention relates to a floor, especially for tiles, with

essentially planar, circular shaking movement for the non-rotating sole surface(s) which are divided into sections with separate sole organs (sole plates, sole nets, etc.). Such sills are often referred to as swing sills.

The invention, which aims to greatly increase the capacity and efficiency of such solls, will be defined in more detail below. The invention also aims to make the sole easier to process and more durable, to facilitate cleaning and replacement of the sole organs, etc. According to the invention, this is achieved by a sole especially for chips and other non-cubic or non-granular material, comprising a bowl which is non-rotatably suspended in movable devices and whose circumference has the shape of a regular polygon, a motor placed generally centrally in the bowl and equipped with one or more rotatable arms with eccentric weight distribution, adapted to impart to the bowl a large set planar, circular shaking movement, one or more sun surfaces arranged one above the other, each of which extends diagonally downwards from the circumference of the bowl to a central outlet funnel as well as a top cone placed above the engine and guide plates placed under a material pile arranged centrally above the bowl for even distribution of sun material to the peripheral parts of the solar rafts, where the distinctive feature is that the solar surfaces, with the help of largely vertical walls that extend s eg radially from the outlet funnel to the circumference of the bowl, are divided into sections which through openings in the peripheral side wall of the bowl which in and of themselves can be individually pulled out from or pushed in to their respective active positions.

The attached drawings show an example of a floor according to the invention. Fig. 1 shows a side view of a floor according to the invention with the associated supply device for wood chips. Fig. 2 shows a plan of the sole itself with certain parts broken away and the top cone lofted away. Fig. 3 shows a vertical section through the sole along the line III-III in fig. 2.

Fig. h shows a side view of a section wall in the sollet.

Fig. 5 shows a side view and fig. 6 is a plan view of the discharge chute for shavings. Fig. 7 and 8 show two different vertical sections through one of

the hatches for inserting and removing soleplates.

Fig. 5 and 6 are, as fig. 7 and 8, drawn to the same scale, but otherwise different scales have been used in the figures. 1 fig. 1 in the drawing 1 denotes a cyclone separator with an inlet 2 for chips from a chipper and an outlet 3 for the transport air. The separator is carried by a stand h and has an outlet 5 for the chip material which is fed from there centrally downwards onto the ry±e or swing sole. This has the shape of a bowl 6 and is suspended in and carried by easily bendable organs, preferably ropes (wires) 7 which extend between ores 8 on the sole and the stand 9-Four such stands are suitably arranged.

The chip that is fed in falls onto a top cone or cap 10.

Reference should now be made to fig.2 and 3-

In the sole or bowl 6, under the removable top cone 10, an electric motor 11 is attached to a bottom plate 12 and enclosed in a central cylinder 13 which is covered by the cone 10. From the central well, which is formed by the parts 12 and 135, it goes out radially straight walls 1>+ which divide the sun into a number of sections which in the embodiment shown are arranged in a number of eight. The sole has an appropriate ground plan shape of a regular polygon, fig. 2. The transverse walls 1^ are attached to the enveloping bowl-shaped outer wall 6.

Optionally, reinforcements of appropriate design can be inserted, e.g. the angle irons shown in fig. 3 and h.

The transverse walls 1<*>+- are shown in detail also in fig. h. Support strips 15 are attached to these walls, which carry guide plates 16. These are suitably non-perforated and curved downwards at their outer ends. The enclosing frame plate, or bowl 6, is pulled up high above the outer ends of the guide plates 16, so that a ring or embankment of solid material can be built up around the perimeter under varying operating conditions, e.g. depending on uneven introduction or varying composition of the goods. On the cross walls \h there are also arranged inclined channels 17 and 18 respectively where. coarse sieve plates 19 and fine sieve plates 20 have been inserted, respectively. In these walls, upper recesses 21 and lower recesses 22 have also been taken out.

The lower, inner ends of the rough sole plates 19 are arranged around a central delivery funnel 23 for the pins that do not pass through these plates. The fine sole plates 20 are similarly connected with their lower, inner ends to a lower, central feed hopper 2h for the chips that pass through the coarse sole 19, but not through the fine sole plates 20. This chip falls onto a conveyor 25 to be fed to a bin , and on to the boilers.

The material that passes through the finsoll plates 20 falls onto a funnel-shaped bottom 26 and is fed on this downwards to a screw-shaped chute 27 with an outlet 28 to one side. This chute is shown in particular in fig. 5 and 6.

At the upper edges of the base 26 there are arranged hatches 29, a

for each sector. See especially fig. 7 and 8,. The hatches can be removed when their handle 30 is turned out of engagement with a corresponding stop on the sole stem, e.g. on the walls J\ k. When the hatches have been removed, the sill plates 19520 can be inserted into or removed from the channels 17 and 18 respectively, or the sill plates are easily accessible for cleaning and purification. Springs 31 are attached to the hatches 29 by means of clamping means 32 which allow a certain tilting of the spring so that, when the hatch is closed, it presses the strainer plates 19,

20 evenly into place.

The shaft 33 for the motor 11, fig. 3?is arranged in the center of the sun. An arm 3'+ is attached to this shaft, where a suitably variable number of weights can be attached. This arm carries an angle iron or U-iron 36 at its outer end

at its one flange engages a circular U-beam 37 which is attached to the bottom 12 and which is to catch the weights and prevent them from being flung out if they were to come loose.

Electric current to the motor 11 is fed through a cable in the rudder

38, fig. 2.

The device described works as follows:

The solid material or chipping material that comes from the choppers falls from the outlet 5 onto the cone 10 and from there onto the guide plates 16.

The weights 36 will set the motor shaft 33 slightly at an angle in relation to the vertical, so that the entire sole in the rest position is slightly at an angle. When the motor rotates, the rotating arm 3^" with the weights 35 will thus give the sole a shaking movement which essentially takes place in the sole plane and also has a tilting movement. The sole thus tilts but it does not rotate. The amplitude is determined by the size of the weights 35 and can be varied by changing these.

Due to the shaking movement, the tile material that falls centrally on the cone 10 is fed outwards onto the guide plates 16 and falls down around the circumference, the perimeter, for the sole on the coarse sole plates 19 - Pins that do not pass through these plates are moved due to

of the shaking movement downwards and inwards on the plates and falls into the funnel 23 to be fed away from the sole.

The tile passes through the coarse sole plates 19 and is guided by the shaking movement downwards and inwards to the hopper 2h- on the conveyor 25 for further removal.

The finest material passes through the fine sole plates 20 down onto the bottom 26, is shaken on this down the chute 2'7 and is fed away from the sole through the outlet 28.

In that the arm 3<*>+ med. the weights 35 sweep through the openings 21, it prevents sticks, which are already loose material, from gathering in piles on the rough plates 19. The sweeping movement of the arm directly breaks up any piles of sticks on the rough sole plates 19 and throws sticks into adjacent sectors, so that a more even distribution is achieved . The air draft that occurs due to the arm with the weights further contributes to preventing the stick's troublesome starting of the coarse sole plates, such as with known tile soles.

The openings 22 allow, in the event of an uneven supply, a short-term accumulation of ready-soled chips on the lower part of the fine-soll plates 20 around the funnel 2h.

Because several solar sections are built together in a circular arrangement into a compact unit with common operation and common input, very high efficiency is achieved and at the same time great simplicity. In addition, inspection, cleaning and replacement of solar panels becomes very simple and the solar has a great ability to avoid operational disruptions due to uneven supply of solar material, varying nature of this, etc., and that solar material collected on a nearby solar surface is transferred to another solar surface.

Although during operation the sun essentially keeps its center of gravity on a vertical, stationary line, the load on the load-bearing elements is essentially static.

Torsion rods or one or more elastic poles can be used to carry the sole together with or instead of the ropes 7.

Certain changes can be made to the devices shown and described, thus the motor does not have to be electric, but can be e.g. an internal combustion engine, hydraulic or pneumatic engine.

The motor does not have to be permanently connected to the solar, but can drive the solar via an eccentric device. It is not necessary, whether the motor is separated from or permanently connected to the sole, that the eccentric weight distribution which causes the shaking movement is achieved by the motor shaft itself or through attached weights or the like. has an eccentric weight distribution, i.e. an asymmetrical weight distribution in relation to its geometric axis. Instead, the shaft can be completely symmetrical and form a non-rotating stator, around which rotates a driven rotor with asymmetrical weight distribution.

In some cases, it may be appropriate to control the movement of the sole in a vertical direction with springs or the like. elastic elements, especially if the ropes 7 are replaced by or supplemented with torsion bars etc.

The arm 3<*>+ does not need to be weight-loaded. It can be replaced with a double arm which is balanced on the shaft 35 and only serves to sweep over the sole plates for distribution of the sole goods.

Claims (3)

1. Sole, especially for chips and other non-cubic or non-granular material, comprising a bowl (6) which is non-rotatably suspended in movable devices and whose circumference has the shape of a regular polygon, a motor (11) placed large placed centrally in the bowl (6) and equipped with one or more rotatable arms (3*0; with eccentric weight distribution, arranged to impart to the bowl (6) a largely planar, circular shaking movement, one or more superimposed sole surfaces, which each extends obliquely downwards from the circumference of the bowl (6) to a central outlet funnel (23, 2'+) as well as a top cone (10) placed above the engine and guide plates placed under a material pile (5) arranged centrally above the bowl for even distribution of solar goods for the peripheral parts of the solar fleets, characterized in that the solar rafts, by means of largely vertical walls (1^-) which extend radially from the outlet funnel (2.3, 2 <*> +) to the circumference of the bowl (6), are divided into sections (19, 20) which through openings (29) in the peripheral side wall for the bowl (6) which, as is known per se, can be individually pulled out from or pushed in to their respective active positions. 2. Soll as stated in claim 1, characterized in that the walls (1'+) are designed with openings (21, 22) which allow the movement of sun goods between mutually adjacent sun sections (19, 20) which form part of the same sun surface. 3. Soll as specified in requirements 1 and 2, characterized in that the weight arms (3I4-) are designed to sweep over the underlying soleplates (19), as they pass through the openings (21) located at the same level in the vertical walls (Ih)