DE2342842B2 - Cascade shaft cooler - Google Patents

Description

The invention relates to a cascade shaft cooler according to the preamble of claim 1.

Freshly squeezed food cubes have a high humidity and temperature and are uncomfortable sticky texture. This is unfavorable for transport and storage; as a result, it is common to use the To dry and cool feed cubes.

A shaft cooler for grain and the like having the features of the preamble of claim 1 is known (GB-PS 3 26 871), in which the air guiding roofs are arranged in the direction of the longer shaft element dimension are and the air flow flowing through the duct cooler directly from the duct of the Chute cooler gets into the exhaust duct. As a result, it must either be comparatively lower Air flow rate worked or a noticeable part of the treated material being carried away into the exhaust duct.

The invention is based on the object of providing a cascade shaft cooler of the type mentioned at the beginning to create with which an intensive cooling effect can be achieved and the evenly cooled feed cubes supplies.

The solution to this problem results from the characterizing part of claim 1.
As regards technical progress, the following is stated: Under the air discharge roofs of the cascade shaft cooler according to the invention there is an air flow with practically the same flow velocity everywhere. The flow speed can be selected to be comparatively high, since feed cubes or smaller feed cubes parts, as they are constantly created by the trickling movement of the feed cubes over the casc. As a result of the design of the transition pieces, these parts get back into the cooler shaft at essentially the same height. This means that all feed cubes have approximately the same dwell time in the shaft cooler. A very intensive cooling effect is observed with a low power requirement. The cooling performance and the duration of the cooling process can be influenced by the number of shaft elements. The cascade shaft cooler according to the invention has a favorable air distribution, no dead zones of impaired cooling or zones in which goods to be cooled are deposited, and a high level of operational reliability. As a result of the cleaning effect of the trickling movement of the feed cubes, the air duct roofs are less prone to clogging.

Cascade shaft coolers generally have a favorable space utilization, a low specific one Energy requirements and benefits due to the constant relocation of the feed cubes. These advantages also remain obtained in the cascade shaft cooler according to the invention.

Preferred developments of the invention follow

from the subclaims.

The arrangement of an air volume throttle between the air discharge roof or roofs and sioi has shown the air extraction duct to be particularly advantageous for air distribution If, due to the fan characteristics, the air volume throttle is slightly open and this is higher There are no speed peaks at a distance of 20 to 30 cm inwards to find out more. The amount of air flowing through can thus in this way without disadvantageous Effects on the feed cube treatment are regulated. You can also use the individual shaft elements enforce different amounts of air, for example for gentle initial cooling at the top of the Shaft cooler and maximum cooling down in the shaft cooler. The suction-side air volume restriction proves to be cheaper than an upstream side, especially since no separate guide plates are required.

When the amount of air increases in each duct element have independent and controlled by the feed cubes actuating means, can during the filling and when the duct cooler is emptied, the duct elements are switched on and off in sequence will.

There is no air circulation in the empty part of the shaft, and it is exactly that for cooling the required amount of air enforced in each case

The transition between the transition piece and the shaft element is preferably partially in its upper area closed. This expands the flow cross-section at this transition, and as a result of the deflection of the air flow and reduction in the air speed, a Particularly effective separation of entrained feed cubes and parts of feed cubes.

With the aid of the preferably provided finger flap lock between the air exhaust line and The cube extraction element can remove fine parts of the treated material, which get into the air extraction line are fed into the cube extraction element by means of finger flap ejection. As is well known, wise Food cubes contain a lot of abrasive components such as minerals. If you suck a large amount of abrasive dust is removed with the air flow, deflection points and bends of the air duct are predominantly in sanded through in a very short time. The damaged parts would have to be repaired or replaced after a short time will. Because the dust-like parts only take a fraction of the treatment time compared to the feed cubes from a hygienic point of view, there is nothing against a direct return to the finished fruit cubes object.

By constructing the air duct roofs from several loosely inserted, one-piece panels the proportion of ineffective areas is greatly reduced and the free air passage area is maximized will. This serves to further improve the cooling and drying process and also to avoid it smallest possible deposit sites.

In a further development of the invention, a device is provided with which the air throughput can be changed periodically. Such a device can common to all shaft elements and thus the Air exhaust duct or a single duct element, for example through installation in the area of the Transition piece are assigned. For example, a flap can be arranged in the middle by means of a The shaft in the transition piece can be set in rotation. The drive can be operated at low speed by means of a Gear motor take place, which is advantageously arranged outside on the transition piece 20 with each Circulation of the flap, the air passage is closed and opened twice as a result of this large fluctuations in the amount of air, respectively. Air velocities through the layer of feed cubes to be cooled These air pulsations can intensify and intensify the cooling process. An analog rotating The flap can be provided at the upper end in the air exhaust duct. If such a facility corresponds to the Is assigned cube extraction element, a separation process can be carried out at the same time with a corresponding layer height will. It is even conceivable to install the fan (not shown) in the »pump area», i.e. in that normally undesirable area in which the amount of air is between zero and some value periodically fluctuates to operate. For this, however, is A very strong dimensioning of the fan wheel is a prerequisite.

The invention is explained in more detail below with reference to the drawing using an exemplary embodiment explained. It shows

F i g. 1 the cascade shaft cooler in a front view,

F i g. 2 the cascade shaft cooler in a side view,

Fig. 3 the cascade shaft cooler in plan view,

4 shows a hanging pendulum of a cube deduction element the cascade shaft cooler on a larger scale,

Fig. 5 a single manhole element in a larger Scale in section,

F i g. 6 shows a section along VI-VI in FIG. 5, Fig. 7 actuating means for an air volume throttle, F i g. 8 shows the actuating means of the air quantity throttle on a larger scale in the viewing direction of FIG. 6, F i g. 9 a cube deduction element in section, FIG. 10 a cube deduction element combined with a sieve,

F i g. 11 a single guide plate for the ventilation roof, and

FIG. 12 shows a section along XII-XII in FIG. 11. The cascade shaft cooler is made of individual elements Shaft elements 1, a shaft upper part 2, and a cube extractor element 3 constructed, as in the Fig. 1, 2 and 3 is shown. The shaft upper part 2 has an inlet nozzle 4 and is four Side walls 5 completed. Openings 6 are provided on two side parts 5. In the top are Level flaps 7, which are held in a certain position with a counterweight 8, are arranged. The level flaps 7 are via an electrical limit switch 9 via a not shown Control system with vibration generators 10 of the cube extraction element 3 connected.

A single shaft element 1 is shown in FIGS. 5 and 6 shown on a larger scale. The shaft element 1 has two pairs of horizontal air duct roofs.

A central air supply roof 11, which in vertical section has the shape of an isosceles triangle open at the bottom, is connected to the ambient air via openings 12 in side walls 14 and 15. Two half air supply roofs 13 and 13 'in the form of sloping surfaces iewejs ngrallpl 7ij one according to ⁿ

Triangle side of the central air supply roof 11 are through wall interruptions 16 and 16 'all over the place The area of the narrow side wall is free for fresh air and at the same height as the central air inlet roof 1! arranged.

Above the air supply roofs 11, 13 and 13 'are two air discharge roofs 17 and 18 arranged symmetrically, which also have the shape in vertical section have an isosceles triangle open at the bottom. The respective air discharge roof 17 or 18 is above the gap between the central air supply roof 11 and the half air supply roof 13 or 13 'arranged. The side wall 14 is closed with respect to the air discharge roofs 17 and 18. In contrast, the opposite side wall 15 each an opening 19 and 19 ', which through a transition piece 20 with a downward sloping surface 20 ', an air volume throttle 21 and an air exhaust line 22 are connected. All air duct roofs are by an upper angle 25 and two lower angles 26 or in the case of the half air supply roofs 13 and 13 'formed a lower angle, in which air-permeable panels 27 roof tile-like are inserted.

A connection of all air discharge roofs 17, 18 or transition pieces 20 with a common air discharge line 22 is favorable because the air currents of different moisture content are mixed and so a condensation of water in the air exhaust pipe, which is with in the air exhaust pipe existing food cube components such as sugar and protein become sticky and tend to stick Could connect masses, is counteracted. Between the air extraction line 22 and the cube extraction element 3 a finger flap lock is arranged.

An air volume throttle 21 is advantageously assigned to each duct element 1. The air volume throttle 21 is controlled by a flap 30, as shown in FIGS. 7 and 8 is shown. The flap 30 is over a shaft 31 with a counterweight 32 displaceable with respect to the shaft 31 in a rest position held, which at the same time corresponds to the closed position of the air volume throttle 21. On shaft 31 is further a lever 33 firmly wedged, which on the opposite side with a sliding bush 34 on an actuating rod 35 is slidably mounted. The actuating rod 35 points on both sides of the sliding bush 34 locking disks 36, which determine the end positions of the air volume throttle 21, so that their total Closure or opening can be prevented. The air volume throttle 21 can act as the actual air volume control device can be used. Depending on the position of the counterweight 32, even the degree of opening the air volume throttle 21 as a function of the above the flap 30 or above the respective duct element 1 can be influenced. The shaft cooler is for the largest and smallest feed cubes optimally applicable.

The cube extraction element 3 is via four hanging pendulums 40 on a base 39 via a square support 41 screwed on with flanges 42. Around the supports 41 ' four rubber blocks 43 are arranged, which in turn are held with a sleeve 44 and with the Hanging pendulum 40 are connected. On the cube extraction element 3 is an analog support 41 'via flanges 42' The support 41 'is in turn mounted on the suspension pendulum 40 via rubber blocks 43' with a bushing 44 '.

As a result of this suspension pendulum, which is known per se, the cube extractor element 3 can have a damped oscillating movement especially in a preferred direction (A). Although small movements in the transverse direction to it are possible, the transverse movements are dampened more. The cube extractor 3 is larger Scale in FIG. 9 shown. For reasons of transport, the cube deduction element 3 is directly connected to the Base 39 connected. The cube extraction element 3 has two flat inclined floors 50 with lateral shoulders 51 on. A roof 52 is arranged above the floor 50, which allows the feed cubes to exit directly into the Floor 50 prevented.

The mode of operation of the Schachtkühier according to the invention is illustrated in FIG. i to 6 following:

The freshly squeezed feed cubes are done with excess water content and in a hot state the inlet nozzle 4 is filled. The cubes trickle over the cascade-like air duct roofs 17, 18 and 11, 13 and 13 'down. The first cubes get to the cube extractor element 3 and form the opposite Air supply roofs 11, 13 and 13 'of the lowermost shaft element 1 have a natural angle of repose. With the filling of the first cubes must be ensured at the same time for a sufficient air flow, because Otherwise the cubes adhere mainly to the air ducting roofs, which represent obstacles for the cubes would. While the cooling and excess water drainage is progressing, the cube extraction element 3 remains switched off. If the level of the feed cubes exceeds the level flaps 7, these are due to the weight of the Cube pressed down against the restoring force of counterweights 8. The turning movement of the level flaps 7 is transmitted to a limit switch 9 at the same time. The limit switch 9 switches in the End position of vibration generator 10, with which the discharge of the finished treated by the shaking movement Rolling the dice begins. The level flaps 7 ensure that the shaft cooler does not run empty unnecessarily. So is ensures uniformity during the entire operating period. In an industrially carried out Laboratory test, an anemometer was used to determine an even distribution of air, and above all the discharged feed cubes had a surprisingly uniform temperature at all four corners, which is proof of a good operation of the shaft cooler according to the invention. Although the The air speed was chosen so high that small cubes could be carried away on the surface, only fine dust particles could be found in the air vent line 22.

The shaft upper part 2 has openings 6, the one allow a particularly gentle pre-cooling zone. In this way, the cooling process goes evenly over the whole cube cross-section in front of you, as well as the release of the excess water, which is often feared Shock cooling does not occur.

Experience has shown that in the treatment of feed cubes in shaft coolers a certain There is a favorable measure of the cube layer thickness (c), which is approximately 250 to 300 mm (c) if the size is increased significantly beyond this level, the quality of the cubes deteriorates. It is now it has been found that between the layer thickness of the cube in the cooler and the horizontal length dimension (B) there is also an optimal ratio of this layer, for the following reasons:

- the maximum possible volume utilization of the entire shaft cooler should be achieved. This results in a few small air duct roofs and a large duct element base area;

- The air speed should be selected as high as possible in order to achieve a more intensive treatment process to reach. This results in a large number of large air duct roofs;

- the air distribution should be uniform. This results in a short horizontal length dimension (B) the cube layer;

- The material sinking in the shaft should be uniform without expensive auxiliary equipment. From this it follows a small manhole element base area.

The contradicting requirements resulted in an optimal ratio of layer thickness (c) to layer length (B) from about 1: 4 to 1: 5. The horizontal dimension (B) of the layer and the length In order to remain economical, the air duct roofs should not be significantly below 1.0 ni, but around No loss of quality, do not exceed 1.5 m. A length of 1.2 m appears to be ideal.

From the side of lowering the material and utilizing space, two pairs of an air supply roof have each other with an air discharge roof turned out to be particularly advantageous, which together with the optimal length of 1.2 m is currently the most advantageous embodiment.

The lowering of the feed cubes is not only due to the shape of the shaft elements and the air duct roofs determined, but also by the dice deduction element. Especially with cascade coolers swinging cube deduction elements have been tried and tested very well. The illustrated embodiment of a shaft cooler has a cube extraction element, which is particularly advantageous for the even lowering of the feed cubes 3 with a main oscillation direction transverse to the air guiding roofs 11, 13, 13 ', 17, 18 and in Direction of the longer shaft element dimension (A).

Between the air supply roofs 11 and 13 as well as 11 and 13 'of the shaft elements 1 is in each case one vertical wall 23 arranged. This, together with the preferred direction of oscillation of the cube extraction element 3 an absolutely even cube lowering over the longer shaft element dimensions, achieved in particular in the lowermost shaft element 1, which is the uniform quality of the cooled

ίο and dried feed cubes is used.

In the same direction, cube dosing flaps 53 known per se act along the narrow sides of the Shaft element, which together with a roof 52 form a metering gap 49 and the cube also over the both narrow sides (B) into the bottom 50. The cube dosing flaps 53 can be adjusted by means of a wheel 54.

The arrangement of two symmetrically opposite vibration generators 10 on the is advantageous shorter dimensions of the cube extraction element 3, which are known to influence each other in such a way that tumbling movements are turned off and only horizontal vibrations across the connecting pipe 55 in the direction of Long side (A) arise. A sieve 56 is expediently arranged between the roof 52 and the floor 50.

The roof 52 is connected to the vibrating floor 50 and received from the vibration generator 10 same swinging motion. This means that the cubes can be discharged despite the cube dosing flap not vibrating 53 guaranteed. Since the dice are discharged onto the sieve 56 via the narrow side (B), everyone receives Cube the longest possible path to the outlet 58. Fine parts can pass through a separate channel 57 be delivered. With this design, the the finished cube can be freed from the amount of dust that is not desired by the customer. The screening itself is of very good quality because it is carried out over the longer route

For this purpose 4 sheets of drawings

Claims (11)

Patent claims: 1. Cascade chute cooler for feed cubes with a chute upper part, several stacked box elements and a cube extractor element, with air-permeable air duct roofs that are open at the bottom and which run parallel to one another are arranged in the duct elements, which are provided as pairs of an air supply roof with an air discharge roof connected to an air extraction line , characterized in that the air duct roofs (11, 13, 13 ', 17, 18) are arranged in the direction of the shorter shaft element dimension (B) and that the air discharge roofs (17, 18) with an air outlet line (22) through a separator-like transition piece (20 ) are connected with downwardly facing Sjhrägfläche (20 '). 2. Cascade shaft cooler according to claim 1, in which between the air outlet line (22) and the air discharge roofs (17, 18) of a shaft element (1) an air flow throttle (21) is arranged, characterized in that the air flow throttle (21) with a through the feed cube actuatable flap (30) is connected 3. Cascade shaft cooler according to claim 2, characterized in that between the air flow throttle (21) and the flap (30) an actuating rod (35) with locking discs (36) for Determination of the extreme positions of the air volume throttle (21) is arranged. 4. Cascade shaft cooler according to one of claims 1 to 3, characterized in that the upper cross-sectional area between the transition piece (20) and the shaft element (1) partially is closed and an extension piece (20 ') which is continued downwards into the interior of the shaft has downward sloping surface. 5. cascade shaft cooler according to one of ■ claims 1 to 4, characterized in that between the air extraction line (22) of the lowermost box element (1) and the cube extraction element (3) a finger flap lock (28) is arranged. 6. Cascade shaft cooler according to one of claims 1 to 5, characterized in that the Air duct roofs (11, 13, 13 ', 17, 18) each made up of several loosely inserted in angles (25, 26), one-piece, air-permeable plates (27) are constructed. 7. Cascade shaft cooler according to one of claims 1 to 6, characterized in that the Shaft elements (1) each with two pairs of horizontal air duct roofs (11, 13, 13 ', 17, 18) exhibit. 8. Cascade shaft cooler according to one of claims 1 to 7, characterized in that the Air discharge roofs (17, 18) of each duct element (1) above the air supply roofs (11, 13, 13 ') are arranged. 9. Cascade shaft cooler according to one of claims 1 to 8, characterized in that between the air supply roofs (11, 13, 13 ') of the individual shaft elements (1) a vertical Wall (23) is arranged. 10. Cascade shaft cooler according to one of claims 1 to 9, characterized in that one Device is provided with which the air flow rate can be changed periodically 11. Cascade shaft cooler according to claim 10, characterized in that in one or all Transition pieces (20) a flap with a centrally arranged shaft is arranged