FI58758B - ANORDINATION FOR UPDATING OF SUS GRUS ELLER LIKNANDE KORNFORMIGT MATERIAL - Google Patents

Abstract

1. Apparatus for heating sand, gravel or similar granular material, comprising arcuately profiled channels (22) arranged in a receptacle (1) containing the material to be heated for feeding a heating gas into the material, and further arcuately profiled channels (22) for discharging the heating gas from the material, characterized in that the arcuately profiled channels (22) which serve to feed the gas into the material as well as the arcuately profiled channels (22) which serve to evacuate the gas from the material are grouped in alternately laterally adjacent batteries (2, 3) each comprising several vertically superposed arcuately profiled channels and forming vertical partition walls between which the material to be heated is arranged in relatively thin layers (5).

Description

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Patent · och raglatarttyralian 1 Antokin utl ^ d och utl.ikdfun publkund (32) (33) (31) Fyy ^ «* y utuolkuu» —Boglrd prloritut (71) Oy Partek Ab, 21Ö00 Parainen, Suozni-Finland (FI) ( 72) Kai Juhani Lainio, Turenki, Antti Juhani Koivupalo, Pargas,

This invention relates to a device for heating sand, gravel or the like granular material. This invention relates to a device for heating sand, gravel or the like granular material. , which includes vaulted gutters located in the tank of the substance to be heated for supplying and removing heating gas to the substance.

A device for heating aggregates used in the manufacture of concrete is already known, which has a hot air blower connected to the lower part of the silo and overlapping inverted V-shaped vaulted gutters in the silo, through which the and in the latter case, short spacer supports between them. The parallel vaulted gutters are staggered so that their ends facing the center of the silo are zigzag-shaped, while of the crossed vaulted gutters, every other gutter terminates near the intersection. The disadvantage of these devices is that the vaults make it difficult for the substance to drain and the even distribution of the heating gas in the substance is not efficient enough.

Grain dryers are also known which, as described above, have V-shaped vaulted troughs arranged one on top of the other so that every other vaulted trough is connected to the blow-in channel and every other to the outlet channel. Due to the overlap of the vaulting troughs, the mixing in the dryer is strong, so the grain consumes the heat of vaporization as it dries and the dust formation is strong. This is a disadvantage when the material to be dried is sand or gravel and the aim is only heating.

It is therefore an object of the present invention to provide an apparatus for heating sand, gravel or similar granular material of the above-mentioned type, in which the heating is limited to a well-defined volume range, even in a considerably larger storage or intermediate silo. efficient so that heating can be carried out continuously if desired.

The device according to the invention is characterized in that the vaulting troughs for supplying heating gas on the one hand and the vaulting troughs for removing heating gas on the other hand are assembled into parallel radially partitioned radiators with several overlapping vaulting troughs between them.

Due to these thinner mattresses, heating can be accomplished by blowing a heating gas, such as hot air or flue gas, through them for a period of time such that the desired average mattress temperature is reached before the mattress temperature on the exhaust side has significantly risen from its initial temperature. This has the advantage that on the one hand the moisture possibly contained in the heated material, such as rock humidity of the concrete station can not get the effluent gas as loss of carrying out höyrystyslämpöään, because the material of the mattress in the blow side layer vaporizing the moisture condenses out of the blow side of the cold layers and, secondly, the blowing of leaving the heating gas borne dust binds to the blow side of the damp times 3 58758 rox. Therefore, dust extraction devices are not needed despite the high flow rate of the heating gas.

In the device according to the invention, the flow of the substance to be heated is such that no mixing takes place, and the flow of the heating gas is such that the front surface area is very large over its entire flow length and the length of the flow paths is short. Due to this and the small volume of the heating zone, the operating speed of the device is high and the need for thermal insulation between the outdoor space and the heating system is almost non-existent, due to the fact that the heating zone is more or less completely heated within the silo.

According to a preferred embodiment of the device according to the invention, the other end of each vaulted gutter coil for supplying the heating gas is connected to a heating gas distribution chamber, which in turn is connected to the heating gas supply line. Also, the other end of each vault trough radiator is connected either to a collector chamber, which in turn is connected to an exhaust flue, or each trough radiator is connected to its own exhaust duct, which in turn is connected to its own exhaust flue, which is provided with a throttle to control the heating gas flow.

According to a preferred embodiment of the device according to the invention, the vault gutters are loosely arranged in fixed pairs of conductors with openings leading from the distribution chamber to the gutter radiators for supplying heating gas and openings from the gutter radiators for removing gas to the collecting chamber or exhaust ducts.

The vault gutters preferably consist of two or more overlapping vault cassettes, which in turn consist of a plurality of overlapping vault gutters. Thus, these wear-prone parts can be easily replaced by removing the worn cartridge from the wire pairs and replacing the new cartridge.

^ 58758 In order to equalize the flow of heating gas and the drainage of the substance to be heated, each trough coil for supplying the heating gas may be provided with its own throttle flap to control the flow of heating gas, or baffles or obstacles to the flow of the substance can be adapted to equalize the flow rate of the substance to be heated in different mattresses.

The invention is described in more detail below with reference to an embodiment of the device according to the invention shown in the accompanying drawings.

In the drawing, Fig. 1 shows a vertical section of a rock silo in which a heating device according to the invention is placed, and Fig. 2 shows the same in a vertical section perpendicular to Fig. 1.

Figure 3 shows the device according to Figures 1 and 2 in horizontal section along the line III-III in Figure 1.

Fig. 4 shows a single vault cassette in a side view and Fig. 5 in an end view, in which Fig. 5 shows the upper and lower cassettes belonging to the same vault gutter in dotted lines.

Fig. 6 shows a part of the heating gas distribution chamber with the installation guides and inflow openings of the vaulted gutter batteries therein, and Fig. 7 shows a section along the line VII-VII in Fig. 6.

Figures 8 and 9 show a modified embodiment of the device according to the invention in a manner similar to Figures 1 and 2.

The heating device according to the invention shown in Figures 1-3 comprises a plurality of vault cassettes 2, 3 arranged inside a aggregate silo 1 or a similar tank, which are arranged at small intervals in parallel between pairs of conductors 4 supporting them at both ends. Between the vaulted gutter coils 2, 3, vertical mattresses 5 of heated material are formed, which can flow freely downwards towards the silo discharge hatch 6. The guides 4 are attached to one side of the vaulted gutter coils 2, 3 by An inlet pipe 14 connected to the heating gas source is connected to the blowing duct 7 for conducting the heating gas through the blowing duct 7 and the associated vault gutter coils 2 to the aggregate to be heated. On the opposite side, the guides 4 are attached to the outlet ducts 11, which have an outlet opening 10 at the inlet ducts 3 which are not connected to the blow-in duct 7 by the inlet openings 8.

Thus, heating gas, for example hot air or a mixture of flue gas and air, is led through a pipe 14 and an inlet duct 7 and connected vaulted gutters 2 to the aggregate mattresses 5. Heating gas flows through the aggregate mattresses 5 in each in its own outlet flue 12, and each outlet flue 12 has a flow control flap 13. The control flap 13 allows the flow of heating gas through the different mattress layers 5 to be adjusted using a continuously operating heating device so that the heating gas flow corresponds to the average aggregate flow rate in different aggregates.

If, on the other hand, the heating of the aggregate is carried out as a batch process and in particular in a separate vessel smaller than the actual silo corresponding to the size of the aggregate charge to be heated, the control flap 13 is not required while the aggregate is in place in the mattresses 5.

Figures 4 and 5 show on a larger scale a vault cassette 2, 3 used in a heating device according to the invention. Such a cassette consists of vaulted troughs 22 attached to vertically supported vertical supports 21, which are formed by inverted V-shaped troughs. The vaulting troughs 22 can be attached to the supports 21, for example by welding. In the embodiment shown in Figures 4 and 5, one cassette comprises four overlapping vault gutters 22, and in the embodiment shown in Figures 1 and 2, one vault gutter battery 2, .3 comprises three overlapping vault cassettes.

6 58758

Figures 7 and 8 show the heating gas supply duct 7. It is supported in a suitable manner, not shown, on the structures of the silo 1. Attached to the supply duct 7 are U-shaped guides 4 for vaulted gutter coils 2, 3. Every second conductor 4 has an opening 8 through which the heating gas can flow under the vaulting troughs 22 of the vault gutter coils 2. The outlet ducts 11, which are likewise supported on the silo structures, are fixed at respective points by guides 4 for vaulted gutter coils 2, 3, and in the wall of the outlet ducts there is a corresponding opening 10 at every other guide 4, but the openings 10 are offset from the blowing channel openings 8.

The heating gas is led through a pipe 14 to the supply duct 7, from where it flows through the openings 8 under the vaults of the vault gutter coils 2. As shown in Fig. 5, cavities 9 are formed under the vaulted gutters, through which the heating medium can flow almost unhindered over the entire length of the vaulted gutters and thus distribute and flow through the large head surface into the aggregate mattress 5 and through the cavities 9 and through their cavities 9 to the exhaust ducts 11.

The heating device according to the invention can be used either as a continuous or batch heater. The continuous heater is placed inside the silo close to the bottom. The heating device is then blown with the amount of heating energy required to heat the amount of material to be unloaded from the silo in portions at a time in connection with each unloading. In the case of a heater, the net volume of the heating vessel corresponds to the largest cartridge size to be heated at one time.

When using a continuous heating device, there is a disadvantage that the substance to be heated can flow unevenly in the gaps formed by the vaulted gutters 2, 3, i.e. in the mattresses 5, as a result of which the substance to be heated may overheat at slow flow rates, which in turn increases the heating gas exhaust temperature. .

7,5758 This uneven run-off can be prevented, for example, by attaching wear-resistant motor vibrators 19 on the upper vault paths of the outermost vault gutter coils 3, which promote a smooth run-off of the substance to be heated. Alternatively or in addition, as shown in Fig. 9, beams 17 can be placed on the upper cassettes of the vault gutter coils 2, 3 or below the lowest cassettes in the region of the fastest flow, which can be experimentally easily moved to their right places. The rails 17 are preferably freely fitted on pins 18 located in the uppermost cassettes with a relatively dense distribution.

Furthermore, as shown in Figs. 8 and 9, the flow of heating gas can be limited by baffle plates 16, the function of which is to prevent the flow of heating gas through the mattress 5 either over the entire discharge length, i.e. over the entire height fully stationary passive stock or only below average flow. In Figures 1-3 and 8 and 9, reference numeral 20 denotes a stationary passive storage in the area between the outer jacket of the silo 1 and the heating device according to the invention, which acts as a thermal insulator between the environment and the heater.

From the point of view of the efficiency of heat transfer, it is advantageous that the heating device according to the invention is supplied with sufficiently hot heating gas. For example, when heating a cold aggregate to a temperature of 70-90 ° C at a concrete plant in an element factory, the temperature of the heating gas can be 200-500 ° C, whereby the heating time and thus also the start time of the cold heating system is only a few minutes.

The recirculation of the heating gas in the heating device according to the invention can take place either in a closed or open system. In a closed system, the gases from the exhaust flue 12 are led back to the heat generator and further to the pipe 14. If the flue gases of the heat generator are mixed with the heating gas, only the amount of gas corresponding to the flue gases has to be removed from the closed circuit. In an open system, on the other hand, the heating gases are directed completely out of the flue.

Claims (10)

Apparatus for heating sand, gravel or similar granular material, comprising in a container for the material to be heated arranged vaulting channels for introducing heating gas into the material and vaulting channels for discharging the heating gas from the material, characterized in that one on the other hand, the vault formation gutters (3) intended for initiation of the heating gas and, on the other hand, the vault formation gutters (3) intended for discharge of the heating gas are arranged alternately next to one another, which arise relatively thin material pads (5). 2. Device according to claim 1, characterized in that one end of each battery (2) of vault formation grooves for initiating the heating gas is connected to a heating gas distribution chamber (7), which in turn is connected to an inlet line (14) for heating the gas. Device according to Claim 1 or 2, characterized in that one end of each battery (3) of vault-forming channels (3) of vault-forming channels is connected to a collection chamber, which in turn stays in communication with a chimney duct. Device according to Claim 1 or 2, characterized in that one end of each battery (3) of vault-forming gutter for draining the heating gas is connected to each of its outlet duct (11), which in turn is connected to each of its chimney duct (12). ), which is provided with a damper (13) for controlling the flow of the heating gas. Device according to any one of the preceding claims, characterized in that the batteries (2, 3) of the vaulting grooves are removably inserted in rigid guide pairs (4), which are provided from the distribution chamber (7) to the batteries (2) intended for opening the heating gas. ) of openings (8) of vaulting gutters and from the batteries (3) of vaulting gutters intended for conducting the heating gas to the collecting chamber or outlet ducts (11) conducting openings.