DE3018777A1 - METHOD FOR CRUSHING PRODUCTS AT DEEP TEMPERATURE AND SYSTEM FOR IMPLEMENTING THE METHOD - Google Patents

Description

Method of crushing products at deeper
Temperature and equipment for carrying out the process

The invention relates to a method and a plant for comminuting or grinding of products at low temperature to obtain a powder of this product in cooperation with a very low temperature superplasticizer for crushing or embrittling. In general, liquid nitrogen or liquid or solid carbon dioxide is used as the low-temperature superplasticizer.

There are already numerous cryogenic shredding devices
have been proposed in which - in almost all cases - cryogenic liquid is introduced directly into the comminution housing or grinding housing, and in order to ensure a better energy yield, the gas from the comminution device or the comminution gas has been recirculated into a product passage or a product column for pre-cooling or circulated, and that
either in the direction of flow or against the direction of flow of the products.

In a special embodiment, the product is brought
into an elongated cooling zone with an upstream section for pre-cooling and a downstream section for cooling, these sections being charged with the comminution gas.

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Despite the relatively complex structure of the cooling zone the fact of introducing cooling fluid into the crusher only to bad results, as experience and the different technical embodiments have shown to have.

The present invention is a method for comminuting at cryogenic temperature, in which the product is in brings an elongated cooling zone, which has an upstream section for pre-cooling and a downstream section for cooling, where the cooled products are introduced into a circulating shredder with shredding gas, the excess thereof Part is withdrawn in countercurrent transversely to the pre-cooling zone and where the supply of the cryogenic superplasticizer takes place in the cooling section of this cooling zone and this flows into this cooling section, specifically in cocurrent with the products and towards the shredding device, with the shredding gas partly in countercurrent to these products is recirculated into the pre-cooling section. This method is characterized in that another part of the grinding gas is circulated in cocurrent with the products in the cooling section and that a remaining part is downstream of the cooling section is recirculated into the connecting line of this cooling section in the shredding device.

This special embodiment for the introduction of cryogenic superplasticizers and recirculation of the grinding gas allows, according to experience, to obtain an excellent

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Outstanding thermal yield, because not only the products to be cooled are cooled well, as they are at the same time as the very low-temperature superplasticizer but there is also an excess of this cryogenic release agent in the comminuting device itself and thus serves to compensate for the warming caused by the shredding device, so that the cryogenic superplasticizer does not have to be introduced into the shredder itself at all.

The invention also relates to a plant for cryogenic comminution with a cooling column with an upper pre-cooling section and a lower cooling section, a connecting line towards the cryogenic shredder, where the cooling column downstream from the pre-cooling section in a first introduction line for gas for comminution or comminution gas and downstream from the cooling section with a second introduction line is equipped for grinding gas. This system is characterized by the fact that it is directly downstream of this first introduction line has an introduction device for a cryogenic liquid, e.g. B. a pulverization guide device (ramp) for liquid nitrogen.

This introduction device for cryogenic fluid advantageously has an introducer for a cryogenic fluid into an annular zone between a cylindrical wall of the column and a product funnel.

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Preferably, the cooling section is equipped with a downstream funnel which is opposite a fixed transverse plate on the Conveyor shaft of the products and opens at a small distance from this, with a ring with slide above the plate outside of the funnel is provided. In addition, the second feed line for grinding gas is level with the funnel of the Cooling section arranged.

Further advantages, features and possible applications of the present invention emerge from the following description preferred embodiments in connection with the drawings. Show it:

1 shows an axial section of the cooling column of a preferred cryogenic comminution plant and

FIGS. 2 to 4 are schematic views of three different embodiments of a cryogenic comminution plant.

According to Figure 1, a cooling column 1 has a cylindrical wall with vertical extension, and this column takes one Axial shaft 3, which is driven by a motor 4 of reduced speed (the speed is in the order of magnitude of 20 rpm).

The cooling column 1 has a first section, which is called the pre-cooling section 11, and between the tip

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the column 1 and the height of a first introduction line 12 for grinding gas is limited, and has a cooling section 13 between this first line 12 and a lower end of the column 14. This cooling section is located via a line 15 with a comminuting device or grinding device 16 in connection.

The pre-cooling section 11 is open at its upper end 17 and has a feed hopper 18 for the products to be cooled. The outlet of the introduction line 12 for grinding gas is located opposite a frustoconical baffle 19, which has a uniform and circumferential Division of the comminution gas allowed, of which at least a part according to the arrow F1 upwards through the pre-cooling section at 17 increases towards the atmosphere. In the course of their descent, the products to be cooled beforehand are through on the shaft 3 attached cross bars 20 and 21 swirled.

The cooling section 13 has a feed or loading device 25 for cryogenic superplasticizers that come from a There is guide device 26 (ramp) which is supplied with liquid nitrogen through a line 27 and a ring of Has injection nozzles 2 8, which are directed downwards. This circular guide device 26 is in the space between the wall of the column 2 and a funnel 30

arranged, in which a circulation screw 31 is also arranged for the products climbed on the shaft 3 and the

a circulation of the products according to the arrows f allowed.

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301877?

Downstream of the feed device 25 for the cryogenic fluid are successively on the shaft 3 vortex arms or rods 32 and 33, then a chimney 34, which with the wall the column 2 is positively connected by a transverse arm or cross bar 35, and is arranged in the interior of this chimney 34 a screw 36 attached to the shaft 3 moves. Incidentally, this screw extends down to below them Fireplace 34.

At the lower end of the cooling section 13 is opposite a second feed line 40 for grinding gas a funnel 41 arranged, the lower end 42 opposite a circular Transverse plate 43 is arranged and provided at a small distance therefrom, the plate 43 on the shaft 3 with greater radial extent than the end portion 42 of the funnel

41 is attached. On the periphery of this plate 43 and above the same a retaining ring 45 is arranged for the product, which axially upwards at least to the level of the end of the end part

42 of the funnel 41 extends. This ring 45 is broken by a window 46, in which in a more or less large distance a slide 47 can be located, which is positively connected to a radial actuated by a hand crank 49 Shank 48 is connected.

At the level of the window 46 or below this, a deflector 60 or a baffle plate 60 is arranged, which leads to the end 61 of the Column 1 is inclined towards where the connecting line 15 is located.

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The cooling column is operated in the manner described below:

It will be seen below that the comminution gas is introduced into the column 1 in part through the first line 12 and in part through the second line 40. A considerable part of at least the gas coming from the line 12 escapes upwards in the direction of the arrow F ₁ in countercurrent to the products, and another part of the gas coming from the line 12 is directed according to the arrows P »in cocurrent with the to be cooled Products in the cooling section.

The comminuting gas coming from line 40 is overall that which, according to arrow F, leads to the connection line and is directed from there into the shredding device 16.

In continuous operation, the product takes up essentially all of the space left free in the column and flows off under the force of gravity; it is continuously introduced through the feed hopper 18 and slowly swirled through the arms or rods 20 and 21 while at the same time it is pre-cooled by the comminution gas flowing _{in the direction of arrow F 1.} At the level of the funnel 30, the product is at least partially recirculated onto itself as a result of the screw 31, according to the arrows (f), before it enters the cooling section, where it is subjected to a vigorous cooling of the fluid coming from the pulverizers 28 is coming.

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The cryogenic superplasticizer thus accompanies the product as it passes through the cooling zone, and it is found that the Product also here, but rather also in the pre-cooling section recirculated on itself according to the arrows (f) due to the action of the screw 36.

A more or less large removal takes place at the level of the plate 43 through a more or less large opening of the Slide 47, and the selected amount of product, which corresponds to the amount supplied, is then in a fully cooled State directed to the shredding device 16, in which the cooling fluid is introduced in excess at the same time will.

The cooling column which has been described in connection with FIG. 1 can be a cryogenic comminution device of different types can be assigned or connected to this, and in connection with FIGS. 2 to 4 three preferred embodiments explained.

Figure 2 shows the cooling column 1, very schematically in the the pre-cooling section 3, the cooling section 13, the detector or the baffle plate 19, the funnel 3O and the device 25 for supplying cryogenic fluid and the distributor plate 43 are shown at the lower end. This cooling column 1 is through the connecting channel 15 connected to a comminution device 16 or a grinding device 16 (of which the wheels or

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moving pieces). Furthermore, the excess grinding gas withdrawn through a filter 51, and the crushed particles are collected in the funnel 58.

In this embodiment, the comminution gas is not directed in its entirety to the filter 51 but is partially diverted into a circulation or recirculation channel 52 with a throttle valve 53, in order to form a first line 12 on the one hand (which opens downstream from the pre-cooling section 3) and on the other hand to form the second conduit 40 (which opens downstream from the cooling section 13). As a result, part of the comminution gas flows partly through the first line 12 in countercurrent to the products according to arrow F ₁ and flows in the other part only with the same direction of flow as the products according to arrow F 1, and another, larger part of this gas is passed directly through the second line 40 led to the connection channel 15.

As a result of the throttle slide 5 3, the amount of grinding gas can be which is recirculated in the channel 52 must be kept in equilibrium so that the entry of air can be avoided, or conversely, a loss of too large an amount of reduction gas at the upper inlet of the channel of the cooling column 1 does not occur can.

In another embodiment shown in FIG the main structural elements of the column 1 are denoted by the same reference numerals as in Figure 2, and the crushing

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gas is fed directly into the hopper of the shredder 16 taken through the second line 40 for grinding gas. The line 40 is here also with a throttle slide 53 provided as the first line 12, which opens downstream from the pre-cooling section 3, and it is connected to a housing 55, which completely surrounds the filter 51 at a distance.

In this embodiment, the entirety of the grinding gas thus partially recirculated through the second line 40 without filtration, on the other hand after filtration at 51 recirculated through the first conduit 12; Here, too, the throttle slide 53 allows the amounts of the comminuting gas to be regulated using the first and second lines 12 and 40.

In the embodiment shown in Figure 4, the The whole of the comminuting gas is taken from the end of the housing 55 of the filter 51 and, on the one hand, by a circulating device 56 routed to the first line 12 and, on the other hand, routed to the second line 40; the first line 12 comprises a quantity throttle valve 57, which thus restricts the amount of the grinding gas which is released to the atmosphere towards escapes, limit allowed.

The invention relates to the comminution of products into pieces at cryogenic temperatures, e.g. B. of food, such as B. nutmegs, or of industrial products such. B. Plastics that become brittle at low temperatures or can be crushed.

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Claims (11)

Dr. Hans-HeinriA Willrath t D. 6M0 mlVJU May Dr. Dieter Weber S / B Postfach 6145 198O Dipl.-Phys. Klaus Seifet ΪΚ55Ϊ * PATENTANWÄLTE it'TWILLPATENT 1 ClCX: 4 - 1 series 2.418 L'Air Liquide, Societe Anonyme pour I1Etude et 1'Exploitation Des Procedes Georges Claude, 75, Quai d'Orsay, 75321 Paris Cedex 07 / France Process for crushing of products at low temperature and equipment to carry out the process priority; May 18, 1979 in France, registration no. 79 12,728 claims 1. Process for comminuting products at very low temperatures to obtain a powder from this product with a low-temperature superplasticizer for Embrittlement or comminution, in which the product is brought into an elongated or extended cooling zone, an upstream pre-cooling section and a 0300A8 / 0799 Postal check: Frankfurt / Main 67 63-602 Bank: Dresdner Bank AG ₁ Wiesbaden, account no. 276 807 has downstream cooling section, in which one furthermore the cooled products in a comminuting device with Circulation of the grinding gas introduces, an excess part of which in countercurrent through this Pre-cooling zone is withdrawn, and in the case of the cryogenic fluid in the cooling section of this cooling zone is supplied and flows in this cooling section, in the same direction as the points and to the Crushing device, the crushing gas or the gas for crushing partly in the pre-cooling section is recirculated in countercurrent to the products, characterized in that another part of the comminution gas in the same Direction of how the products are circulated in the cooling section and that a remaining part is downstream of the cooling section is circulated or recirculated in the connection line of this cooling section to the shredding device. 2. The method according to claim 1, characterized in that part of the downstream of the pre-cooling section is recirculated Crushing gas is passed through the cooling section to the crushing device. 3. Plant for comminution at cryogenic temperatures with a cooling column with an upper pre-cooling section and a lower cooling section, a connection line to the lowest temperature Zerklexnerungsgerät out, wherein the cooling column downstream of the pre-cooling section with a first Introduction line is equipped for grinding gas 030048/0799 and downstream of the cooling section with a second inlet conduit is equipped for grinding gas, characterized in that downstream of the first line an introduction device for a cryogenic flux, e.g. a pulverization guide device (25) for liquid nitrogen. 4. Plant according to claim 3, characterized in that a screw for ascending the products on a conveyor shaft for the products is attached at the level of a funnel. 5. Plant according to claim 3, characterized in that the cooling section is provided with a downstream funnel, which is arranged opposite a distributor transverse plate and at a distance therefrom, which frictionally engages with the product conveying shaft is connected, and that a ring with slide is arranged above the plate and outside the funnel is. 6. Plant according to one of claims 3 to 5, characterized in that that the second introduction line for the comminuting gas is level with the funnel of the cooling section is arranged. 7. Plant according to claim 3, characterized in that the first introduction line for the grinding gas directly is connected to the hopper of the shredder. 030048/0799 8. Plant according to claim 3, characterized in that the first introduction line for the grinding gas with a Housing is connected, which surrounds at a distance from a filter of the funnel of the shredding device. 9. Plant according to claim 3, characterized in that the second introduction line for grinding gas with the first Introduction line for the grinding gas is connected. 10. Plant according to claim 3, characterized in that the second introduction line for the grinding gas directly
is connected to the hopper of the shredder. 11. Plant according to claim 3, characterized in that the introduction device for the cryogenic fluid
an introduction device for the cryogenic fluid in an annular zone between a cylindrical wall of the columns and a product funnel. 030048/0799