RU2636647C1 - Device for thermochemical hetero-phase processing of disperse materials with vibration liquefaction - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: device for thermochemical hetero-phase processing of disperse materials with vibration liquefaction containing a heat-insulating housing and a vibratory drive, material loading and unloading units, heaters evenly located at the side walls of the housing, circulating fans fixed to the bottom wall of the housing; inside the housing there is a rack with a series of mesh shelves containing thresholds of overspilling, wherein the rack is mounted on the stands of the vibratory drive with a clearance from the side walls of the housing.

EFFECT: increased uniformity of thermochemical transformations of carbon materials during activation, reproducibility of product properties, isokinetic of material transformations during processing.

7 cl, 2 dwg

Description

FIELD OF TECHNOLOGY

The present invention relates to the field of mechanical engineering, oil, gas, coal chemistry, metallurgy and a number of other industries, since vibration fluidization can intensify chemical heterophase processes, diffusion transfer, heat and mass transfer, mechanical mixing processes, effectively reduce energy costs for the implementation of a number of thermochemical processes in industry , including the processes of activation of carbon materials, including for the production of carbon molecular sieve sorbents, activated carbons and other dispersed materials.

BACKGROUND

Known aerodynamic grain dryer disclosed in RU 2018074 C1, publ. 08/15/1994. This grain dryer contains a thermally insulated housing with loading and unloading nozzles, heaters, a vibration damper and an aspiration system. The housing is fixed and equipped with a platform mounted in the housing with the possibility of vibration and having inclined, cascading shelves for moving grain, above and below which heaters with reflectors are installed, while the inclined shelves are installed with gaps one relative to the other, and in the joint zone equipped with s-shaped agitators.

The disadvantage of this device is the low heat efficiency, high metal consumption, low specific productivity per unit area occupied by the equipment, the lack of reverse flow direction of the gas reagent, the inability to process the material in reverse mode and the stopped flow of material, with temperature programming, as well as a significant temperature difference in the furnace and in the material.

The closest analogue of the claimed invention is a device for continuous drying of bulk materials in a vibratory circulation layer, disclosed in RU 2215958 C1, publ. 11/10/2003. The device disclosed in the analogue comprises a heat-insulating casing, a screw transporting chute mounted on a vibro drive, heaters installed between the turns of a screw transporting chute, the bottom of which has perforation in the form of evenly spaced conical openings for pouring inert material, and parallel to the heaters from the inside and outside pass coils with radial holes facing the heaters.

The disadvantage of this device is also the low efficiency of heat use, high metal consumption, the inability to process the material in non-isothermal mode, with a programmable rise or decrease in temperature, the absence of a reversal of the direction of flow of the gas reagent, a significant temperature difference in the furnace and in the material.

SUMMARY OF THE INVENTION

The objective of the claimed invention is to develop a device for thermochemical heterophasic processing of dispersed materials with vibration fluidization, providing a material with high uniformity, including low-temperature activation of carbon materials, operating in flow isothermal or batch mode with predetermined changes in temperature, direction and speed of purge loading of the reagent, direction and material moving speeds.

The technical result of the claimed invention is to increase the uniformity of thermochemical transformations of materials, including carbon activation upon receipt of activated carbon.

The specified technical result is achieved due to the fact that the device for thermochemical heterophasic processing of dispersed materials with vibration fluidization contains a sealed thermally insulated housing and a vibrodrive, material loading and unloading units, heaters evenly located at the side walls of the housing, circulation fans on the lower wall of the housing, and inside the housing a whatnot is located with a series of mesh shelves containing thresholds for material overloading, while the whatnot is supported by a vibrator drive frame and is not in contact asaetsya with the housing walls.

The circulation fans are made in the form of a central hub (wheel), on which the blades are fixed evenly around the circumference, while the circulation fans are made with the possibility of creating a reversible gas flow, and the fan blades are located at 45 ° to the plane of the wheel.

The vibrodrive is made integral and contains the upper and middle frame, and the base, and springs are fixed between the upper and middle frame, and jacks are installed between the base and the middle frame.

On the upper frame of the vibrodrive, rack-mounted racks with mesh shelves are fixed.

The base of the vibrodrive is fixed, isolated from the heat insulating body.

The vibrodrive is configured to change the frequency and phase of the oscillations.

Overflow thresholds are made with the possibility of full or partial opening.

BRIEF DESCRIPTION OF THE DRAWINGS

The attached diagrams show the design of the proposed device:

FIG. 1 is a side view of the device.

FIG. 2 is a cross-sectional view of the device.

1 - Thermal insulating body; 2 - site loading material; 3 - node unloading material; 4 - the upper frame of the vibrodrive; 5 - the middle frame of the vibrodrive; 6 - the base of the vibrator; 7 - a jack; 8 - spring; 9 - rack vibrodrive; 10 - mesh shelf.

DETAILED DESCRIPTION OF THE INVENTION

A device for thermochemical heterophasic processing of dispersed materials with vibration fluidization contains a heat insulating casing (1) and a vibratory drive, loading units (2) and unloading (3) of the material, heaters evenly located at the side walls of the casing, circulation fans mounted on the lower wall of the casing, inside of the building (1) there is a shelf with a number of mesh shelves (10) containing the overflow thresholds, while the shelf is mounted on the racks (9) of the vibrodrive with the formation of a gap between the shelves and the side walls of the housing (1 )

Circulating fans are made with the possibility of creating a reverse flow of a gas reagent.

For heating use electric or gas heaters.

The vibrodrive is made integral, containing the upper (4), middle (5) frame and base (6), and springs (7) are fixed between the upper (4) and middle (5) frames, and between the base (6) and the middle frame (5) ) jacks installed (8).

On the upper (4) frame of the vibrodrive, racks (9) of the shelves with mesh shelves (10) are fixed.

The base (6) is made stationary, isolated from the heat insulating body (1).

The vibrator is not connected to the furnace body (1), it is located on a separate base. Racks (9) are attached to the vibrator and passed through the holes in the bottom of the heat-insulating housing (1). Mesh shelves (10) are located inside the housing (1) on the uprights (9).

Vibration to the mesh shelves (10) is transmitted through the racks (9) mounted on the frame of the vibrodrive.

The vibrodrive is configured to change the frequency and phase of the oscillations.

Overflow thresholds are made with the possibility of full or partial opening.

The operation of the claimed device in semi-periodic mode is as follows. The vibrator turns on in the mode of periodically changing the frequency and phase of the oscillations. Material, for example coal, is fed through the loading unit (2) with the vibrator turned on to all mesh shelves (10) of the whatnot. Mesh shelves (10) are filled with open sill thresholds. But at the same time, the filling threshold is closed on the lowest net shelf (10). After filling the bottom shelf with a layer of material of a given thickness, the overburden threshold on the shelf (10) located on top of it is closed. Thus, fill all the shelves (10), starting from the bottom to the top. After filling with a layer of material the uppermost mesh shelf (10), the material loading is stopped and the circulation fan is turned on, then the heaters. After reaching the set temperature in the material layer, a gas reagent (air, water vapor, etc.) is fed into the furnace, which provides the necessary thermochemical transformations of the material. The temperature in the device changes according to a predetermined program that provides the necessary material transformations, up to 550 ° C. During activation, the vibro-boiling layer of the material moves on the mesh shelves (10). The direction of movement of the material periodically changes according to a given program due to a change in the phase of vibrations of the vibrator. In addition, due to a change in the direction and speed of rotation of the fans in the vibro-boiling layer of the material, the direction and flow rate of the reagent change according to a given program. The homogeneity of the material transformations is ensured by changing the frequency and phase of vibration of the shelves that are separate from the heat-insulating casing, changing the direction of movement of the material layer, as well as the frequency and amplitude of oscillations of the material particles in the vibration-fluidized layer on all shelves. After reaching the specified degree of conversion of the material, the reagent is shut off and the fan is turned off. Then, alternately, from the top up on the mesh shelves (10), the overflow thresholds are opened and the activated material in a vibro-fluidized state through the discharge unit (3) is removed from the device.

When operating in isothermal flow mode, the material transfer thresholds are lowered to a predetermined height, and the productivity and processing time are determined by the height of the thresholds, the feed rate of solid material and gaseous reagent. In this mode, the material is fed through the loading unit (2) to the upper mesh shelf (10). Then, in the vibrated state, the material flows through the lowered thresholds sequentially from the upper shelf to the lower one and enters the unloading unit (3).

The uniformity of material transformations in this mode is also ensured by changing the frequency and phase of vibration of the shelves separate from the heat-insulating casing, changing the direction of movement of the material layer, as well as the frequency and amplitude of the oscillations of the material particles in the vibration-fluidized layer on all shelves.

Thus, the present invention provides a device for increasing the uniformity of thermochemical transformations of a material, in particular the activation of carbon materials upon receipt of sorbents, by the height of the layer on each shelf, as well as by the height of the reactor on all shelves, by increasing the intensity of heat and mass transfer processes when changing the direction of supply of the gaseous reagent and the use of separate mesh shelves mounted on a vibration exciter with a gap from the side walls of the heat-insulating housing, h It allows the change of the frequency and phase of oscillations, and to realize with this possibility of turbulence in the reagent layer of the material at the surface of each particle during processing of the material on shelves shelves.

Claims (7)

1. A device for thermochemical heterophasic processing of dispersed materials with vibration fluidization, comprising a heat insulating casing and a vibrodrive, material loading and unloading units, heaters uniformly located at the side walls of the casing, circulation fans mounted on the lower wall of the casing, a shelf with a number of mesh shelves is located inside the casing containing thresholds for overfilling, while the whatnot is installed on the racks of the vibrodrive with a gap from the side walls of the housing. 2. The device according to p. 1, characterized in that the circulation fans are configured to create a reverse flow of a gas reagent. 3. The device according to p. 1, characterized in that the vibrodrive is made integral, containing the upper, middle frames and base, and springs are fixed between the upper and middle frame, and jacks are installed between the middle frame and the base. 4. The device according to p. 3, characterized in that on the upper frame of the vibrodrive rack racks are fixed with mesh shelves. 5. The device according to claim 1, characterized in that the vibrodrive is made separate from the heat insulating body. 6. The device according to p. 1, characterized in that the vibrator is configured to change the frequency and phase of the oscillations. 7. The device according to p. 1, characterized in that the thresholds for refilling of the vibrated fluid in the mesh shelves are made with the possibility of full or partial opening.

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