CS203300B1 - Charging device for shaft furnaces - Google Patents

Description

The present invention relates to a charging furnace of shaft furnaces and provides for the charging of a charge on the surface of a charge by means of an adjustable trough whose run-out edge is adjusted approximately in a horizontal plane immediately above the level of the charge.

Planting devices are known, consisting of a rotating hopper mounted above the furnace shaft on a shaft which, at its upper end, is provided with a drive located outside the gas-tight furnace housing. A fixed trough or chute is attached to the lower part of the rotary hopper with these devices, where the charge is deposited in the annulus only when the hopper is rotated. Therefore, devices with an adjustable chute or trough have been developed, where the leading edge of the trough moves on a circle centered on the center of the horizontal hinge pins when tilting. A disadvantage of this solution is the considerable height of the building, and the correct function is conditioned by the level of the charging which allows the leading edge of the trough to be set to the extreme position to the axis of the furnace. When placing a charge on the perimeter of the shaft, the run-off edge of the trough is at a considerable height above the level of the charging, which is technologically disadvantageous. In another known solution, the adjustable trough rotates on a vertical pin in a horizontal plane. A drawback of this solution is the risk of clogging of the trough at a location where the charge flow direction and speed vary considerably. The rotating trough is connected to an eccentrically situated opening in the rotary hopper, so that the peripheral placement of the charge is uneven.

These drawbacks are overcome by the shaft furnace charging apparatus according to the invention, consisting of a rotatable and angularly adjustable distribution chute, over which a split vertical feed hopper is arranged whose inlet member has a tapering clear cross section in the flow direction and which is connected to the outlet of at least one container. It is an object of the invention that at least one pair of annular links is alternately connected to the inlet member of the feed hopper with an alternating and tapering clear cross section alternating in the feed flow direction. The essence of the invention furthermore is that the heights of the individual pairs of annular elements of the feed hopper decrease in the feed flow direction. It is also an object of the invention that the axis of the feed hopper is coincident with the axis of symmetry of the annular links, the order of which is equal to the number of container outlets.

The advantage of the charging furnace of the shaft furnaces according to the invention is to regulate the charge flows in the vertical feed hopper without increasing the risk of vault formation and stopping the charge flow, as in other known designs. The flow control of the charge is achieved predominantly on annular cells with a narrowed cross-section. Therefore, these elements are lined with wear plates or protective ribs which are fixed in the charge flow spreader such that the distance between the ribs decreases in the direction of the charge flow, so that a stationary material layer is retained in the space between the ribs. An advantage of the planting device is further that the rate of flow control of the charge can be permanently differentiated depending on the position of the material flow impact point on the inner walls of the vertical feed hopper. It is also an advantage of the invention that the rate of flow control of the charge is the same as the material flow from any container outlet.

In the exemplary embodiment, the shaft furnace planting apparatus of the invention is shown in the drawings in vertical section, wherein the direction of rotation and tilting of the distributor channel is indicated by arrows.

Schematic bottom of the tank is disposed above the input člán- ¹ Kem two vertical feed hopper, while the outlet 7 ', 7 "of the two trays are led into the inside cross-section of the input article 2, which tapers in the flow direction of the charge. Two further pairs of ring members 3, 4 are connected to the input cell 2; 5 and 6 vertical feed hoppers of heights vi and vz. A rotating distributor chute 1 is arranged around the axis 8 of the vertical feed hopper, the planter and the furnace shaft.

After opening one of the outlets 7 ', 7', the loose material is poured in the indicated stream through the inlet member 2 into the other annular members 3, 4; 5 and 6 of the vertical feed hopper, wherein the oblique flow of the feed is directed approximately in the vertical direction and symmetrical to the axis 8 of the vertical feed hopper, so that the feed falls into the distribution chute 1 during its rotation at approximately the same location. The walls and bottom of the distributor channel 1 are protected against wear by wear plates and protective ribs which retain part of the material layer.

The degree of rectification of the material flow is different upon impact on the annular links 3 and 4 of the first pair and on the annular links 5 and 6 of the second pair, because at the same change in clear cross section, the heights vi and z differ in the pairs of links 3, 4 and 5, 6.

In other embodiments, the individual annular members of the vertical feed hopper are formed, for example, by horizontal rows of wear plates or protective ribs that are mounted on the casing of the vertical feed hopper; . The widening and tapering of the cross-section of the annular members is continuous or sudden, whereby a stationary material layer is formed at the sudden tapering points to prevent wear of the adjacent section of the inner wall of the vertical feed hopper.

The axis of the vertical feed hopper is an axis of symmetry for its annular members, the order of which is equal to the number of reservoir outlets. Therefore, the shape of these annular links is such that, in the case of two outlets above the vertical feed hopper, the annular links merge with themselves when rotated 180 ° about an axis so that the axis is a second order symmetry axis.

With a higher number of outlets, the axis of rotation is the axis of symmetry of the higher order. For example, with three discharges, the annular links merge three times with each other during rotation - after each rotation of 120 [deg.] And so on. Each axis of symmetry of the even order is simultaneously the axis of symmetry of the second order. Thus, the order of the symmetry axis is a number that indicates how many times the annular elements described will merge with themselves during the 360 ° rotation. At the same time, this number is equal to the number of outlets for the tanks.

If the annular elements of the vertical feed hopper have an axis of symmetry of the same order as the number of outlets, then the degree of rectification of the material stream when pouring the charge from any outlet. The same technological effect is achieved if the described symmetry is maintained only for the inner walls of the annular links which are in contact with the material stream.

The charging plant of the shaft furnace according to the invention can be installed on shaft, especially blast furnaces, where the device charges the largest amount of charge per unit of time, the number of containers above the planting device being free. The typesetting equipment of the shaft furnaces according to the invention can also be used for setting granulometrically very inhomogeneous bulk material into containers or other devices. In these cases, a rotatable and angularly adjustable distribution trough need not be placed below the vertical feed hopper.

Claims (3)

A shaft furnace plant comprising a rotatable and angularly adjustable distribution trough above which a vertical feed hopper is arranged whose inlet member has a tapering clear cross section in the direction of flow and which is connected to an outlet of at least one container, characterized in that at least one pair of annular links (3, 4; 5, 6) is connected to the inlet member (2J of the vertical feed hopper), alternating in the flow direction of the batch, with an expanding and tapering clear cross-section. vynalezu 2. Planting device according to claim 1, characterized in that the heights (vi, vz) of the individual pairs of annular links (3, 4; 5, 6) of the vertical natural hopper are reduced in the feed flow direction. 3. Planting device according to claim 1, characterized in that the axis (8j of the vertical feed hopper) coincides with the axis of symmetry of the annular links (3, 4; 5, 6), the order of which is equal to the number of cartridges (7 ', 7').