NO822235L - VERTICAL EQUIPMENT SHOOT. - Google Patents

Abstract

1. Bucket for vertical elevator comprising a rear wall (1) designed to be attached to the endless driving member of the elevator, a front face (2, 9), forming the bottom of the bucket by joining up with the rear face (1) and two side faces, wherein the profile of any common cross section of the bucket perpendicular to its rear face is such that a portion (2) of said face forming the bottom of the bucket is constituted by a circular arc, the center of which is located on a straight line (3) forming an angle (A) of 15 to 25 degrees with the rear face (1), characterized in that said portion (2) is the main portion of said front face (2, 9) and in that said circular arc is of angular length (B + C) at least equal to 50 degrees, of which 25 degrees at the most arc situated between said straight line (3) and said rear face (1) and of which 25 degrees at least are situated on the other side of said straight line (3).

Description

The present invention relates to a feed vane

for a vertical elevator.

It is known that the capacity of a bucket elevator of

depends on a number of factors, such as the number of blades per meter elevator, the speed of the elevator and the shape of the bucket. It is also known that it is not possible to increase the number of shovels per meters above a certain limit because for a given horizontal projection of the opening of the bucket, the latter will be too shallow and not filled in a suitable way. You know like-

is led that it is not sufficiently homothetic to change the dimensions of a given vane in order to have a scale effect.

The behavior of buckets is in reality different according to the scope and the capacity will be affected even for minor modifications.

The present invention is the result of long investigations into the shape and especially the profile of the blades in order to try to control the dimensional parameters of the blade in order to unite a large number of blades per meter elevator with good filling of the buckets and this at high speed, and on

a simple way as a function of the desired dimensions of the buckets without affecting the capacity of the elevator. The profile of the buckets according to the invention constitutes an optimum that gives elevators with such buckets a very high capacity compared

network with normal elevators.

The invention thus aims to provide

a bucket for vertical elevators consisting of a rear wall to be connected to the endless draft device of the elevator, of a front surface which forms the bottom of the bucket and which is connected to the rear surface and of two side-

surfaces. According to the invention, the mentioned surface which forms

ner the bottom of the blade, when the blade is viewed in profile, have a part consisting of a circular arc centered in a straight line forming an angle of 15 - 25° with the rear surface and an angle length at least equal to 50° where at most 25° is placed between the said line and the said rear surface and where at least 25°

is located on the other side of the said straight line.

Furthermore, the opening plane of the bucket is inclined in front of

hold the back wall at an angle between 75

and 80°, the distance that separates two parallel lines from this opening and passes the two endpoints of the aforementioned circular part corresponds to approx. 5/6 less than the depth of the bucket. It is advantageous for the circular part to be extended with an upper part which is mostly straight and which is inclined by approx. 10° in relation to the projection line of the upper part of the circular part on the opening plane and in the direction of the outside of the vane.

Furthermore, the lower end of the aforementioned is circular

part either connected to the rear wall with a connecting part of small radius or connected to the rear wall with a lower straight part parallel to the plane of the opening and ending with

a connecting piece to the rear wall with a small radius.

One of the advantages of the invention consists in a simple method for determining the shape of a vane and in particular the profile of the bottom which consists in drawing up two parallel lines at a distance of 5/6 of the depth which form a given angle with a straight reference line parallel with the rear surface of the vane, draw up a line of intersection with the two parallel lines inclined to the reference line at a given angle, and let an arc of a circle with a central angle approximately equal to 50° and which is centered on the said line of intersection, pass through the intersections of the center line of the segment of the intersection line that lies within the parallels to the said parallels.

The invention will be better understood from the following description which is not limiting and which makes it possible to

see further benefits and distinctive features.

In the attached drawings are

fig. 1 a sketch of a profile of a vane according to the invention;

fig. 2 shows possible developments of the shovel according to the invention by an expansion of the capacity.

In the figures, line 1 shows the rear wall of a vane in the figure's plane. At this wall, the vane is connected to the movable and endless element (not shown, but which may exist

of one or two chains, a drive belt or similar) by means of

bolts or similar fastening devices. Front spine 2

which forms the bottom of the bucket and which is connected to the back wall 1 has a circular profile where the center 0 is placed on a straight line 3 which forms an angle A with the direction of the back wall

gen 1. This angle can lie between 15 and 25° and is preferably close to 20°. The angular length of the circular profile 2 corresponds to at least 50° and in most vanes with small dimensions it does not exceed 50°. This angle consists of the sum of the angles B and C (in the figure these are equal), the angle B is at most 25° and, in most practical cases, it lies between 22 and 25°, the angle C corresponds to at least 25° and in practice can it reaches up to 40° for blades with large dimen-

is .

It is known to incline the opening plane 4 in the bucket

1 relative to the horizontal. This inclined position is defined by the angle D which forms this plane 4 with the rear wall 1 of the bucket. For the described blade, the angle D is between 75 and 80° so that when the rear surface of the blade is in a vertical position, the inclined position in relation to the horizontal plane for plane 4 will be 10 - 15°, which essentially corresponds to that angle which is the natural inclination of the product being carried.

As defined above, the circular profile is limited

2 of two points 5 and 6. It is necessary that the distance a separating the two straight lines 7 and 8, which are parallel to each other and to the direction of the opening plane 4, roughly corresponds to 5/6 of the depth of the bucket. The point 6 forms the bottom of the bucket (ie the point which is furthest down when the rear surface 1 is vertical) and these 5/6 are the lower 5/6 of the total depth. The last sixth part b of this depth is defined by the upper part 9 in' the forward surface of the vane which extends the circular part 2. This part 9 has a generally linear profile. The direction is such that it forms an angle E of approx. 10° with the orthogonal projection line 10 of the point 5 on the opening plane 4 located outside the opening of the vane. It is noted that the connection between this part 9 and part 2 takes place under an angle G which cannot be exceeded

180° (the angle G is the angle between part 9 and the tangent at point 5 with part 2).

Finally, fig. 1 that the part 2 from the point 6 connects to the rear surface 1 by means of a part with a small radius 11, where this radius is determined by the depth of the vane a + b when this is produced by punching. In the figures, the side walls of the vanes have not been shown, which may be flat either completely from the opening or have an upper part with a configuration similar to the part 9 in relation to the plane of the opening and these side walls preferably converge towards the bottom of the vane.

The shovel according to the invention is thus completely defined. One of the first advantages lies in the simplicity of the profile which allows an easy execution and manufacture" especially when punching. The shape in the front surface and the bottom defined by the pieces 9 and 2 ensures a good filling when penetrating the product mass at the bottom of the elevator and a good retention of the product when the elevator goes up. It has been found that. the bucket according to the invention during filling behaves like a cutting tool, the product is "cut" by the edge 9 and "flows" along the piece 2 without breaking as a continuous chip. This device makes it possible to avoid the product being pushed back from the bottom of the bucket, which prevents filling and to completely remove vibrations that occur due to impact of the product in the bucket. This leads to better operation of the elevator and less wear. When emptying, the bucket rotates around an upper part of the elevator, and the part 9 forms a holding element for the product to counteract the tendency of the bucket to drop prematurely. The height and the angle of this part is in this connection important parameters and the values mentioned above are an optimal compromise to ensure this holding function and the penetration function in the product mass at the bottom of the elevator.

The shape of the shovel according to the invention as it is defined has as its most important consequence a determination method for the optimal profile in a shovel which is to be used in particular in an installation with given characteristics.

One of these characteristics lies in the desired performance of the elevator which, for a given speed, is determined by the projection of the opening of the vanes on a horizontal plane and the number of vanes per length unit of the elevator. It can be seen that the desired performance directly determines the depth of the bucket. From this simple given size, the invention allows the optimum blade to be quickly determined for the stated requirement.

It is sufficient to pull up, when you know

a + b, and thus a and b, the two straight lines 7 and 8 which form a known angle D with the vertical. You then draw up the straight line 3 which forms the angle A with the vertical. This line 3 intersects the straight lines 7 and 8 which determine a segment h-where the center line is found. This center line intersects each of the straight lines 7 and 8 at points 5

and 6. It is thus sufficient to draw the circular arc that passes through the points 5 and 6 with a central angle of 50° and placed on the straight line 3 to obtain the part 2 which

one side extends with part 11 and on the other with part 9. When one draws up the vertical 11 and the plane 4, the profile of the blade is given.

You can then adapt the first retracted bucket in such a way that you precisely adjust the capacity of the bucket to the desired one as shown in fig. 2. In this figure, the described elements can be found with the same references.

You can thus increase the capacity in the bucket without changing the height (a + b) by moving point 6 outwards (to 6a). The part 2 thus extends by a flat part 2a parallel to the opening plane 4 which is itself connected to the rear wall la by a connection part 1a which is similar to the part 11. This scoop with a larger opening has the same technical characteristics as the scoop in fig. 1, but is better suited to certain types of products such as sticky materials.

You can also increase the height (depth) of the bucket

(c + d) by extending profile 2 beyond point 5 (to point 5a). The center angle of the part 2b of the extension of the profile 2 is such that, added to the angle C of 25°, it forms an angle F which can reach 40°. The 5/6 of the depth of the bucket

is thus shown with the distance c, the vane extends beyond the point 5a in a part 9a which has the same geometrical characteristics as the part 9 described above.

The opening of the vane is thus located in 4a, where the rear surface is surface 1 extended upwards or surface la. You can see from this diagram that within broad limits the original shape of the shovel can be varied without modifying the operational characteristics. To these possibilities one can finally add the completely homothetic variations of the shovel. With these methods, the shovel can be adapted to the product and the installation while preserving the essential features.

The invention has interesting applications in loading and unloading.

It is not limited by the description given, but, on the contrary, a number of variations can be imagined without this going beyond the scope of the invention.

Claims (8)

1. Bucket for vertical elevator consisting of a rear wall (1) which can be connected to the endless traction device of the elevator, with a front surface (2-9) which forms the bottom of the bucket and which is connected to the rear surface (1) and of two side surfaces, characterized in that when the blade is seen in profile, the aforementioned surface which forms the bottom of the blade has a part (2) which consists of a circular arc with the center on a straight line (3) which forms an angle (A) of 15 - 25° with the rear surface (1) and an angle length (B + C) which at least corresponds to 50°, where a maximum of 25° (B) is located between the straight line (3) and the mentioned rear surface (1) and where at least 25° (C) is located on the other side of the said straight • line (3). 2. Bucket according to claim 1, characterized in that the plane of the opening on the bucket (4) is inclined in relation to the rear wall with an angle (D) between 75 and 80°, the distance (a) separating the two parallel lines (7 , 8) with this opening (4) and which passes through the end points (5, 6) in the aforementioned circular part (2) corresponds to approx. 5/6 of the depth in the bucket. 3. Shovel according to claim 2, characterized in that the circular part (2) extends with an upper part (9) which is approximately straight and which is inclined in approx. 10° (E) in relation to the projection line (10) of the upper end (5) in the circular part (2) in the plane of the opening (4) and in the direction outwards in relation to the vane. 4. Shovel according to claim 3, characterized in that the said upper part (9) together with the tangent in the said circular part (2) in the connection point (5) forms an angle (G) which at least corresponds to 180°. 5. Shovel according to any one of the preceding claims, characterized in that the lower end (6) in the circular part is connected to the rear wall (1) with a connection with a small radius (11). 6. Shovel according to any one of claims 1-4, characterized in that the lower end (6) of the circular part (2) is connected to the rear wall (1) with a lower part (2a) which is mostly straight and parallel to the plane of the opening (4) and which ends with a connection part with a small radius (lia) to the back wall (1.) . 7. Bucket according to claim 1, characterized in that the angle (A) which the straight line (3) in the center of the circular arc (2) forms with the rear wall (1) of the bucket corresponds to 20°. 8. Method for determining the profile (2) on the bottom of a shovel according to any of the preceding claims with a certain depth (a + b), characterized by drawing up two parallel lines (7, 8) at a distance at 5/6 (a) of the depth where there is a given angle ' ( D) with a straight reference line (1) parallel to the rear surface of the bucket (1), draw up an intersection line (3) with the straight parallel lines ( 7, 8) which is inclined in relation to the straight reference line (1) at another given angle (A), and by making a circular arc (2) with a central angle (B + C) which roughly corresponds to 50° and which is centered on the said line of intersection (3) passing through the points of intersection (5, 6) of the center line of the inner segment of the line of intersection (3) with the parallels (7, 8) with the said parallels.