DE1177574B - Device for sorting lumpy lime or the like. - Google Patents

Description

Device for sorting lumpy lime or the like. In the industry of stones and earth, the aim is to achieve a sales product that is as uniform as possible. Likewise, it is valuable in the smelting works, the ore in terms of uniformity to be sorted as precisely as possible. However, the companies lack a facility which purely mechanically examines the evenness of the respective goods. So far sorting according to quality classes was even possible, it was done purely empirically according to values based on long experience and determined on samples. In general one had to be content with it, especially in the lime industry, instead of a Gilte-class sorting perform, the shipping unit z. B. a wagon load a z. B. by a To add the average sample taken from the tube sample divider.

The invention aims to remedy this deficiency and a device to create exactly the entire respective good that comes from an oven, or which, like ore, is unloaded from a ship on its way to the bunkering to test and lead to a suitable type of bunker in a bunker group.

According to the invention, the sample discharge ends in one of the whole sorting through a dosing device passed through sample divider in a device for continuous measurement of the unit weight or the like, during the raid discharge of the same sample divider into a transport device opens, which is reversible to one of several sort containers. Included is said measuring device transducer of a controller, the actuator Dosing device is. The controller is the command generator of a device for reversing the transport device.

The device for measuring the unit weight can be a hammer mill and the sample divider can be a tube sample divider.

The embodiment of the transport device connected downstream of the tube sample divider - and thus also of the reversing device - depends on the particular case of need. So z. B. the reversing device can be a movable horizontal conveyor on the stage of a bunker group with a fixed feed point; or the reversing device can be a reversing chute which is optionally directed to fixed conveyors that are separate from each bunker. Regardless of which transport and reversing devices are used, it is essential in any case that the time between the testing and the arrival of the goods at the reversing station is taken into account by a time slider that gives the reversing device the command at the right time.

Simply by connecting a known fine flow tube sample divider to the beater mill, it is also possible , in a purely mechanical manner, to carry out an ongoing control and / or z. B. carry out daily sorting checks, and the entire process can also be recorded using a writing instrument.

In the drawing, the invention is explained using an exemplary embodiment. It shows schematically a device for sorting, for example, of lime, the coming from a lime kiln into a group of bunkers.

A conveyor belt 1 coming from a lime kiln battery opens into an equalizing container 2. The discharge device 3 of the container 2 is a metering charging device for a coarse flow tube sample divider 4. The known tube sample divider, which works according to the law of probability, takes a real average of the lumpy lime that falls through it, and about 1/2oo of the amount charged to the sample discharge 5, while all of the remaining lime reaches the overflow discharge 6. The sample discharge 5 opens into a device for the continuous instantaneous measurement of the unit weight, namely a hammer mill 7. The lime crushed therein reaches the receptacle 8, for example a bucket elevator 9, from whose discharge 10 the crushed lime falls into a charging device 11 , which is in A fine flow tube sample divider 12 is supplied with a uniform flow. In the same z. B. 1 / iooo of the lime falling into the tube sample divider to the sample discharge 13, under which a day sample transport container 14 is located. 15 is the overflow discharge of the fine flow tube sample divider, which z. B. is fed to a tube mill in order to bring it there to the grinding fineness of the sales product. According to the numerical ratio given, this tributary is only about 1/200 compared to the amount coming from belt 1.

The device consisting of the beater mill 7, the elevator 9 and the fine flow tube sample divider is known. It does not necessarily belong to the device according to the invention, which essentially only comprises the devices 2, 4 and 7 and the following details: 16 is a controller, the controlled variable X of which is the electrical drive power of the beater mill 7 . The manipulated variable Y emanating from the controller leads to the charging device 3. The same manipulated variable Y 'or a pulse which is given when the manipulated variable changes from one area of its value to an adjacent area reaches the drive device 17 of a reversing chute 18. The same is charged by a conveyor belt 19 onto which the overflow discharge 6 of the tube sample divider 4 opens. The Umsteuerschurre 18 has in the example, three outlets, the middle of which leads into the central variety hopper 20 of a hopper group and the two outer to each one fixedly arranged conveyor belt 21 or 22. The conveyor belt 21 serves to feed the hopper 23 and the conveyor belt 22 for feeding the bunker 24. In the bunkers there are normal burnt lime (bunker 20), harder burnt lime (bunker 23) and soft burnt lime (bunker 24).

The lump of lime coming from a lime kiln on the belt 1 is temporarily stored in the compensating tank 2, since the regulator-controlled flow rate in the tube sample divider 4 is temporarily greater or smaller than the amount delivered by the belt 1 . If the quantities deviate for a longer period of time, the controller 16 receives a command via the level indicator of the container 2 to temporarily switch off the flow completely and thus put the system out of operation - or a command to increase or decrease the controlled variable X. X is therefore a controlled controlled variable. Correspondingly, a line for the reference variable W leads from the container 2 to the controller 16. With a change in X, Y changes proportionally; because as long as the unit weight of the lime does not change, the controller has to keep the quotient LIQ constant. But if the newly entering lime has a different burning quality, the Q changes with a constant L. The measured LIQ is divided into three sub-areas in the practically occurring measuring range. At the transition from one to another sub-area, the control line Y 'receives a command pulse which , if L7Q is small, adjusts the reversing chute 18 so that the lime is introduced into the bunker 24. Specifically heavy lime, which has a larger LIQ, is introduced into the bunker 23 by a corresponding switchover of the device 18.

The measurement of the value LIQ takes place practically at the same time as the belt 19 is being fed from the discharge 6. The reversing chute 18 may, however, only become effective in response to a reversing pulse when the tested lime is in it, ie. H. according to the transport time that the good spends on belt 19. This time shift of the corn mando can, for. B. be done by a Zeilrelaisgruppe.

Individual pieces of lime that deviate from the average burning state of the incoming quantity cannot be recognized by the device according to the invention, especially since a damping element of the controller ensures that the chute 18 is switched over at appropriate time intervals. The discharge of an individual furnace of a furnace battery, which deviates from the average burning state, is also hardly recognized if all the furnaces of the battery only feed a single belt 1 at the same time. The device according to the invention then measures the resulting burning quality of the discharge from the furnace battery.

It is therefore desirable to assign each furnace either its own belt 1 with its own downstream sorting device according to the invention or to connect the conveyor belt 1, which is the only one for all furnaces of the battery, with intermediate bunkering and periodic loading at time intervals with the discharge of one of the furnaces. In the latter case, a single device according to the invention is sufficient. The continuous operation of the device according to the invention makes it possible to manage with very brief intermediate storage.

Claims (2)

1. A device for automatic sorting of pieces of lime, cement, brass or the like, d a - characterized by that the Probenaustrag (5) to be sorted of the total through a metering device (3) guided Well incurred sample splitter (4).. opens into a device (7) for the continuous measurement of the unit weight or the like of the goods, while the overflow discharge (6) of the same sample divider opens into a transport device (19/21/2, 2) which is placed on one of several type containers (20 / 23/24) is reversible that the said measuring device (7) is the transducer of a controller (16) , the actuator of which is the metering device (3), and that the controller (16) is the command transmitter of a device (18) for reversing the transport device. 2. Device according to claim 1, characterized in that the sample divider is a known tube sample divider. 3. Device according to claim 1 or 2, characterized in that the device for measuring the unit weight is a hammer mill (7) . 4. Device according to claim 1, characterized in that the device for reversing the transport is a movable horizontal conveyor on the stage of a bunker group with a fixed feed point. 5. Device according to claim 1, characterized in that the device for reversing the transport has a reversing chute (18) which can optionally be directed to a fixed conveyor, each of the sort bunkers (20/23/24). 6. Device according to claim 1, characterized in that a time slider is arranged between the unit weight measuring device (7) and the reversing device (18) , which takes into account the dwell time of the goods on the transport device (19). 7. Device according to claim 3, characterized in that the beater mill (7) is arranged downstream of a fine flow tube sample divider (12) in a manner known per se. Documents considered: German Auslegeschrift No. 1053 901; Taggart "Handbook of Final Dressing", 1953, Sec. 19, pp. 64/67; Kirchberg, "Preparation of Mining Raw Materials", Vol. 1 (1953), Fig. 182.