DE10029570A1 - Heat exchanger for friable solids has path for friable solids within body over triangular-section tubes - Google Patents

Abstract

The heat exchanger enables a cooling or heating stream to transfer thermal energy to or from the friable solids. It consists of a body with triangular-section tubes in it acting as indirect heat transfer elements. The heat exchanger can also have direct heat transfer installed. In this form, some of the bottom surfaces of the tubes not in contact with the friable solids have gas outlet apertures.

Description

The invention relates to a heat exchanger for free-flowing solids, the suitable both for cooling and for heating the trickle material.

For this, a cooling or heating current is used, the thermal energy of which free-flowing solid is transferred or which extracts heat from it.

Heat exchangers operating according to this basic principle are state of the art extensively described, but here the heat transfer does not take place from or free-flowing solids. The media to be treated are mostly either liquid or gaseous.

Only for drying shredded and thus free-flowing raw lignite tube dryers are known. The raw lignite is inclined in these Pipes, which are bundled in a drum, from one The end wall of the drum is transported to the other. The pipes are made of hot steam flows around. This indicates part of its thermal energy via the pipe walls the raw lignite. Thus an indirect heat transfer is realized, which in concrete case leads to the drying of the raw lignite.

Such tube dryers would basically also be without as a heat exchanger Use drying.  

But they are of their apparatus structure and the necessary peripheral Plant technology cannot be used economically.

It was therefore after a solution for cooling or heating free-flowing To look for solids that can be realized economically and in practice Appropriate acceptance finds.

This was not directly apparent from the prior art.

For this reason, a heat exchanger with special free-flowing solids was used develop, whereby the solid is either extracted or supplied with heat. The heat exchanger should be used with standard workshop equipment and reasonable effort be producible. The assembly effort on site should be kept relatively low. The risk of constipation must be countered by appropriate technical means.

The object is achieved by the features described below Claim 1 has been solved. In the dependent claims are appropriate Embodiments of the invention specified.

For the heat exchanger according to the invention in question for free-flowing Solids were used for indirect heating or cooling, at the same time the realization of a direct heat transfer is proposed.  

For this purpose, a device is presented that consists of a body in the Tubular interior transverse to the direction of flow of the free-flowing solid Heat transfer elements are located.

A heat or coolant flow is underneath due to the heat transfer elements Use a suitable conveyor, such as a blower or Pump, guided and thus an indirect heat transfer realized.

The heat transfer elements are designed so that the trickle material unites builds up the best possible contact with the heat transfer surface. As such, they are smooth inclined surfaces particularly suitable. The angle of inclination should be chosen so that the trickle does not stick, but slides on the surface after impact. According to the invention, tubes with a isosceles or isosceles triangular cross section as Use heat transfer elements.

The triangular tubes are next to each other and offset in several levels in the Corpus arranged, in such a way that one corner of the equilateral Triangle or the corner of the isosceles corner formed by the same sides Triangle is directed against the direction of movement of the free-flowing solid. Since the product guide in the body using gravity from top to bottom is provided below, there are thus two inclined contact surfaces for each triangular tube heat transfer available. These are advantageously in one Angle to each other, which is the natural cone of bulk that the Rieselgut forms equivalent. The third bottom surface of the triangular tube does not come with the product in touch.  

The free-flowing solid intended for heating or cooling is by means of a distributor device placed in the body so that it is from top to bottom trickles over the contact surfaces of the triangular tubes. The total area for the Heat transfer results from the number of triangular tubes per level and the Number of levels and is therefore according to the required Process conditions variable.

The staggered arrangement of the triangular tubes in the different tube levels ensures adequate contact between the Rieselgut and the Contact areas and also good mixing of the free fall located trickle goods by regularly deflecting them.

That is for a high intensity of the heat transfer between Rieselgut and Contact area of importance.

In addition to the features described for indirect heat transfer installable for direct heat transfer. All or some point to this the third lower surfaces of the triangular tubes that are not in contact with trickle material come out openings. A gas flow into the Product space initiated, which flows around the trickling goods and in the direct Contact cools or heats.

The gas flow is either a partial flow of the heating or coolant flow, which is branches off due to the excess pressure via the outlet openings, or one separately fed electricity.  

In the latter case, the triangular tubes provided with outlet openings are one-sided closed and on the other side with a pipe connection and appropriate gas supply options.

The gas flow is in the product space of the body either in direct current with the Rieselgut or countercurrent to this and is accordingly in the lower or upper area derived from the body and in a downstream suitable separator cleaned.

The gas flow for direct heat transfer is in addition to cleaning the Contact or heat transfer surfaces of the triangular tubes can be used by a brief impulse-like pressure increase in the provided with outlet openings Triangular tubes for blowing out the contact surfaces of the triangular tubes underneath leads. For this purpose, it is advisable to use the corresponding triangular tubes with a To connect compressed air line or to equip it, which in the case of a Good heating can be provided with a heater. Regulated solenoid valves in the Compressed air lines trigger a compressed air pulse at certain intervals. The sequence of the compressed air pulses can be staggered according to the pipe level. so that, for example, there is a wave of cleaning in the direction of the flow of bulk material results, which supports the discharge of the trickle material from the body.

The trickle material distribution over the cross section of the body takes place after good entry by means of fixed or adjustable distribution devices, their arrangement and Geometry are to be adapted to the specific requirements in a customary manner.  

The invention is illustrated below using the example of a trickle cooler Drawings explained in more detail.

Fig. 1 shows a possible arrangement of triangular tubes in the radiator body. One way of designing a trickle cooler is shown in FIGS . 2 to 6. 3 Fig. 2 shows the main view, FIG. A right side view,

Fig. 4 shows the side view from the left, Fig. 5 is a view from above and Fig. 6, such a from below.

The reference symbols used in the drawings have the following meaning: 1 body
2 triangular tube
3 deflector plate
4 Rieselgut
5 connection flange
6 upper cone
7 inspection opening
8 distributor plate
9 fan
10 baffle
11 guide plate
12 lower cone
13 outlet opening

According to FIG. 1, ten triangular tubes 2 with an equilateral cross section are arranged in the body 1 of the trickle cooler for each tube row. A distance ratio between two tubes of a row of tubes and the distance between two rows in an extension of the contact surfaces loaded with trickle material is chosen to be 1. Other conditions are conceivable and depend on the flow behavior of the product.

This applies equally to the specific cross-sectional shape of the triangular tubes 2 to be selected. In this regard, reference is also made to the explanations in the description of the invention. Tubes other than triangular shaped can also be used.

In addition, there are different pipe geometries in the individual pipe rows conceivable.

Due to the staggered arrangement of the triangular tubes 2 in the individual tube rows, inevitably mutually arising free spaces between the last tube and the body wall are each narrowed by a deflector plate 3 such that the same cross-sectional geometry as in the rest of the radiator body also results there.

The trickle cooler according to FIGS . 2 to 6 has a rectangular cross section. On the housing side, it essentially consists of the body 1 with adjoining upper and lower cones 6 and 12 . The upper cone 6 is provided with an inspection opening 7 and ends in a rectangular connection flange 5 , which serves as a product inlet. Within the upper cone 6 distributor plates 8 are fixedly mounted to the distribution of material in the triangular tubes. 2

In the chosen example, the cooling air first flows through the Dreickrohre 2 in the lower pipe layers, and then arranged in the upper region of the body 1 triangular pipes. 2 For this purpose, a fan 9 is arranged in the lower half on the outer wall of the body 1 . This presses the cooling air into the triangular tubes 2 located in the lower half of the body. On the exit side of the cooling air is directed by means of a deflection plate 10 into the triangular tubes 2 of the overlying pipe levels. It escapes into the atmosphere above the fan 9 via a guide plate 11 .

The trickle material 4 trickled through the body 1 is collected in the lower cone 12 and discharged via an outlet opening 13 .

Claims (12)

1. Heat exchanger for free-flowing solids with tubular heat transfer elements, characterized in that the trickle material to be cooled or heated ( 4 ) is guided in free fall within a body ( 1 ) via triangular tubes ( 2 ) through which coolant or heating medium flows, with an equilateral or isosceles cross-section and that the triangular tubes ( 2 ) are arranged horizontally or inclined next to each other and in several planes offset from each other in the body ( 1 ), in such a way that a corner of the equilateral triangle or the corner formed by the same sides of the isosceles triangle is directed against the direction of movement of the flow material ( 4 ), and that optionally all or some triangular tubes ( 2 ) have outlet openings through which a gas flow for direct heat transfer and / or cleaning of the contact surfaces can be introduced into the product space, the outlet openings each in the third sub surfaces, the triangular tubes ( 2 ) that do not come into contact with trickle material ( 4 ). 2. Heat exchanger for free-flowing solids according to claim 1, characterized in that the triangular tubes ( 2 ) of all tube rows have the same geometry. 3. Heat exchanger for free-flowing solids according to claim 1, characterized in that the triangular tubes ( 2 ) have different geometries in any arrangement. 4. Heat exchanger for free-flowing solids according to claim 1, characterized in that the contact surfaces of the triangular tubes ( 2 ) acted upon by the flow material ( 4 ) is selected such that the flow material ( 4 ) does not adhere but slides on the surface after impact, and that the angle of inclination advantageously corresponds to the natural cone of bulk which the trickle material ( 4 ) forms. 5. heat exchanger for free-flowing solids according to claim 1, characterized in that also differently than triangular shaped tubes are usable. 6. Heat exchanger for free-flowing solids according to claim 1, characterized in that the heating or cooling medium guided through the triangular tubes ( 2 ) is liquid or gaseous. 7. Heat exchanger for free-flowing solids according to claim 1, characterized in that the trickle ( 4 ) does not follow the laws of free fall, but is guided. 8. Heat exchanger for free-flowing solids according to claim 1, characterized in that the spacing ratios of the triangular tubes ( 2 ) with each other and in the individual tube rows and their position in the body ( 1 ) are adapted to the trickling behavior of the product, the due to the offset arrangement of the triangular tubes ( 2 ) in the individual rows of pipes, inevitably reciprocal free spaces between the last triangular pipe ( 2 ) and the body wall are each narrowed by deflector plates ( 3 ) so that the same spacing ratios as in the rest of the radiator body also result there. 9. heat exchanger for free-flowing solids according to claim 1, characterized in that the gas flow for direct heat transfer either a partial flow of the heating or coolant flow for the indirect Heat transfer or a separately fed electricity. 10. Heat exchanger for free-flowing solids according to claim 1, characterized in that the gas flow for the direct heat transfer in the product space of the body ( 1 ) is performed either in cocurrent with the trickle ( 4 ) or in countercurrent to it. 11. Heat exchanger for free-flowing solids according to claims 1 and 10, characterized in that the gas flow for direct heat transfer in addition to cleaning the contact surfaces of the triangular tubes ( 2 ) is used for this purpose a compressed air line in a conventional manner. 12. Heat exchanger for free-flowing solids according to claims 1 and 10 or 11, characterized in that a separate compressed air line for cleaning is available.