DE831519C - Discharge device for memory that are used to stack small pieces of ice - Google Patents

Description

Discharge device for storage, which is used for stacking small ice stalls to serve The invention relates to an Äustragvorrichtung for memory that is to be stacked from small pieces of ice.

Such storage systems are installed in locations where for short periods of time large quantities of crushed ice must be available. This is e.g. B. the Case when refrigerated transports, such as ships and refrigerated trucks, during the stop to be filled with ice in a port or at a train station> within a short period of time are. h in large-scale chemical companies when carrying out certain manufacturing processes periodically large amounts of Tiis required for a short time.

Today it is clear that a discharge of stacked ice from a Only then can containers run smoothly while protecting the ice as much as possible leaves. if it takes place from the storage layer on top. Compared to the The invention aims at known discharge devices operating according to this principle to provide an improved device of this type in the sense that it can operate at low Manufacturing costs, mainly thanks to extensive mechanical simplifications, of great efficiency.

For this purpose, l>, i of a discharge device according to the invention coaxial with the vertical axis of the memory of circular cross-section a hollow one Stand with a longitudinal wedge on the outer circumference and also a telescopic tube surrounding this stand arranged, the individual parts of this tube through the wedge of the rod that are led. Furthermore, an excavator is one that can be driven by its own drive mechanism Rotary movement in a horizontal plane can be granted, non-rotatably with the top one Part of the telescopic tube connected; this excavator extracts the contents of it from it Skimmed pieces of ice in atlas top and bottom open telescopic tube, with the individual parts this tube can automatically be pushed into one another to the same extent as the stacked one Ice when discharged by the excavator allows the latter to sink.

The drawing shows an example embodiment of the subject matter of the invention illustrated in a simplified representation, namely Fig. I shows a vertical longitudinal section through the memory and the discharge device, wherein the Excavator is shown in the top tier; Fig. 2 shows the parts in one of the Fig. 1 corresponding section in the position that they after discharge of the Occupy memory contents; Fig. 3 shows a section along the line III-III of Figures 2 and 4 show a detail on a larger scale; Fig. 5 shows a detail of the telescopic tube also on a larger scale.

In the figures, I denotes one for stacking small pieces of ice serving memory of circular cross-section, covered by an insulating layer 2 is protected against exposure to heat. Furthermore, 3 denotes one above the memory I arranged ice making plant. The pieces of ice arising from this system are fed from grooves 4 to a rotating paddle wheel 5, which has a uniform Distribution of the pieces of ice over the storage space causes. Coaxial to the vertical The axis of the memory 1 is a hollow stand 6 with a longitudinal wedge 7 on the outer circumference and furthermore a telescopic tube 8 surrounding this stand 6 is arranged. The items this tube 8 are through the wedge 7 of the stand 6 in the axial direction guided and at the same time prevented from turning. The telescopic tube 8 has in the ol> first Part 81 has an opening 82, and at the lower end it is also open. In the further G denotes a serving for discharging the ice piled up in the store 1 Excavator, the frame of which with the uppermost part 81 of the telescopic tube 8 is a whole forms (see. In particular Fig. 3). This whole is rotatable on a ring wedge IO (Fig. 4) stored, the second half of which is in a sleeve 1 1, which through the mentioned wedge 7 of the stand 6 is also guided in the axial direction. By the wedge 10, the frame 91 and the sleeve 11 are thus with respect to the Movements in the longitudinal direction of the stand 6 are coupled, the wedge 7 for the correct guidance in this direction ensures and at the same time rotational movements of the liner II prevented. The ring wedge 7 allows the uppermost part 81 of the telescopic tube to rotate 8 and thus also of the excavated cream meal 9t relative to the bush 11 without further ado. lit the sleeve II an annular sliding contact carrier 12 is rotatably connected, and the uppermost part 82 of the telescopic tube 8 carries a rotating with the same 13 brush bearer 13.

The sliding contact carrier 12 and thus also the sleeve 1 1 are over Cable drives 14 connected to a counterweight 15, which is located in the cavity of the stand 6 moves up and down in accordance with the vertical movements of the excavator 9. With the Sliding contact carrier 12 is also an electrical cable 16 connected to a not shown electrical power source is connected and according to the vertical movements of the sleeve 11 from the roll 17 or winds on the same. I) The brushes of the brush holder I3 are in a manner not shown with a motor 18, which produces the required movement of the excavator shovels. and further with a motor 19 which, via a cable drive 20, lifts the telescopic tube 8 and associated therewith also the excavator 9 in the respectively required position can cause. electrically connected. The motor 19 is with the help of a stop 21 (Fig. 4) of the cable drive 20 switched off automatically as soon as the excavator 9 in its top floor has been raised.

The required rotational movement of the excavator. 9 around the vertical central axis of the memory I is driven by a friction wheel 22, which for the sake of simplicity is only shown in FIG. 3 is produced. By this driven by an electric motor 23 Friction wheel 22, which is always pressed against the inner surface of the memory I, on this If the inner surface rolls in the direction of arrow 4 al), it causes a pivoting movement of the excavator 9 in the direction of arrow B.

The lower part of the vertical stand 6 lies in a shaft 24, which forms a coaxial extension of the storage space. In the one shown in FIG ol> first, position of the excavator 9, the lower end of the telescopic tube 8 protrudes straight still in this shaft 24, in which in the lowest position of the excavator 9 the ineinanclel -schllaclltelte Telescopic tube 8 comes to rest completely, as shown in FIG. 2.

The ice scooped up by the excavator 9 is passed through the opening 82 into the Telescopic tube 8 promoted, from which it is then initially in the shaft 24 and out of this falls via a groove 25 onto a conveyor device 26. The latter leads the event Ice a transport device, not shown, for. B. a cooling rate or a Ship, too.

From the. The preceding should be the mode of action of the one described The discharge device should be clear without further ado. Which is constantly changing during discharge rotating excavator 9 continuously scoops ice from the top of the ice stack and conveys it through the opening 82 in the telescopic tube 8. The excavator 9 then lowers continuously to the extent that the stored ice, when it is discharged, sinks it Excavator allows; as a consequence. that the individual parts of the telescopic tube 8 gradually becoming more and more intertwined until finally Excavator 9 and Telescopic tube 8 after completion of the discharge in ljig. Take up the position shown in FIG. Before sending the storage tank 1 with a new one Ice load is set in motion by the electric motor 19 to excavator g and telescopic tube 8 to bring it back to its topmost position. As soon as this position is reached, causes the stop 21 automatically switches off the motor 19.

In order to keep the discharge device as compact as possible from the store 9 discharged ice into one for the further loading of this ice To bring the required height, it may be useful in the cavity to install a device-like device in the centrally located stand, which the ice falling from the telescopic tube into the shaft below recorded and delegated within the stand of an in the ol) erell part of the storage container Tl anSl) OrtVOrriCl1tUI1g.

PATENT CLAIMS Discharge device for memory that is to be stacked serve of small pieces of ice, characterized in that coaxial to the vertical grow the memory of circular cross-section a hollow post with a longitudinal wedge arranged on the outer circumference and also a telescopic tube surrounding this stand are where the individual parts of this tube are passed through the wedge of the stand, and that an excavator, which a rotary motion by its own drive device can be issued in a horizontal plane, rotatably with the top section of the telescopic tube is connected and the skimmed from it from the memory contents Promotes pieces of ice in the telescopic tube, which is open at the top and bottom, with the individual parts of this body in the Nl atle sell> are constantly pushed into one another, like that accumulated ice when it is discharged by the excavator causes the latter to sink allows.

Claims (1)

2. Discharge device according to claim I, characterized. that The excavator carries an electric motor that pushes one against the inner surface of the store Pressed friction wheel drives, which a Schwenkhewegung of the during its rotation Baggers produces. 3. Discharge device according to claim 1, characterized in that the lower part of the vertical stand in a coaxial extension of the Storage space forming shaft is in the top layer of the excavator the lower end of the telescopic tube just protrudes and into the one in the bottom Position of the excavator the nested telescopic tube comes to rest completely. 4. Discharge device according to claims I and 3, characterized in that that the ice conveyed by the excavator into the telescopic tube falls into the shaft, from from which it then falls on a conveyor. ;. Discharge device according to Claims I and 3, characterized in that that an excavator-like device is arranged in the centrally located stand which detects the ice falling from the telescopic tube into the shaft and inside of the stand of a transport device arranged in the upper part of the storage container spend. 6. Discharge device according to claim I, characterized in that the uppermost part of the telescopic tube with which the excavator is non-rotatably connected, is connected to a counterweight via a cable drive. 7. Discharge device according to claims I and 6, characterized in that that at the upper part of the telescopic tube there is also a power take-off device for an SSlotor. which for lifting the telescopic tube and the excavator in the respective required post is used. 8. output + device according to claims I, 6 and 7, characterized in that that the motor used to lift the telescopic tube and the excavator is automatic is switched off as soon as the excavator has been raised to its uppermost position.