CN114570289A - Fixed bed catalytic reactor and application thereof in removal of hydrazine nitrate and hydroxylamine nitrate - Google Patents

Abstract

The application discloses a fixed bed catalytic reactor and application of the fixed bed catalytic reactor in removing a small amount of hydrazine nitrate and hydroxylamine nitrate in nitric acid. The fixed bed catalytic reactor comprises a shell, a feed liquid distribution plate and a feed liquid conveying core pipe, wherein the shell is enclosed to form a cavity; the top of the shell is provided with a feed liquid inlet and a product outlet; the feed liquid distribution plate is positioned at the inner lower part of the cavity; the feed liquid conveying core pipe is positioned in the cavity; the upper end of the feed liquid conveying core pipe is communicated with the feed liquid inlet; the lower end of the feed liquid conveying core pipe penetrates through the feed liquid distribution plate and is located above the bottom of the shell. By utilizing the reactor, the preheated feed liquid is decomposed into nitrogen, hydrogen and water by hydrazine nitrate and hydroxylamine nitrate under the action of the supported ruthenium catalyst, so that the treatment of the nuclear power waste liquid can be safely and efficiently carried out.

Description

Fixed bed catalytic reactor and application thereof in removal of hydrazine nitrate and hydroxylamine nitrate

Technical Field

The application relates to a fixed bed catalytic reactor and application thereof in removal of hydrazine nitrate and hydroxylamine nitrate, belonging to the field of nuclear power waste treatment and environmental protection.

Background

Nuclear power is green low-carbon clean energy with high technical maturity, and is an important preferred technical route for solving energy problems for human beings in the future. However, the safety problem of the strongly radioactive waste, namely the spent fuel, is one of the main factors restricting the large-scale popularization and application of nuclear power. The nuclear reactor nuclear fuel has low overall utilization rate, spent fuel containing unconverted uranium is an important nuclear element resource, and at present, a nuclear fuel closed circulation route is adopted to separate, purify and further utilize nuclear elements such as uranium, plutonium and neptunium in the spent fuel. For example, PUREX procedure: dissolving spent fuel rods by nitric acid, extracting tributyl phosphate and n-dodecane organic diluent, and reducing and back-extracting by reducing agents such as hydrazine nitrate and/or hydroxylamine nitrate to realize separation, purification and enrichment of each nuclear element. In the process, a large amount of nitric acid waste liquid containing hydrazine nitrate and hydroxylamine nitrate is generated, according to the principle of minimizing radioactive waste after spent fuel post-treatment, the waste liquid needs to recycle nitric acid in the subsequent process, and the distilled residue is subjected to vitrification solidification and deep burying treatment. Hydrazine nitrate and hydroxylamine nitrate have strong reducibility, are easily oxidized and explosive substances with high energy content, and need to be removed in order to eliminate the explosion risk in the concentration treatment process of the waste liquid. The method for removing hydrazine nitrate and hydroxylamine nitrate mainly comprises the steps of adding an oxidant such as sodium nitrite or introducing dinitrogen tetroxide gas and the like, oxidizing hydrazine nitrate, hydroxylamine nitrate and the like into nitrogen, water, nitrogen oxide and other products for removal, and has the following defects: the consumption of the oxidant is high, the cost is high, the reaction is extremely violent, and certain safety risk exists; when sodium nitrite is used as an oxidant, new solid waste sodium nitrate is easily generated; the nitrogen dioxide utilization is low and there is a risk of leakage. The ruthenium-based catalyst can decompose hydrazine nitrate and hydroxylamine nitrate into nitrogen, ammonia, hydrogen and water, a large amount of gas is released in the reaction, the gas flows disorderly in the reaction liquid, the contact of solid and liquid (the catalyst and the feed liquid) is damaged, and the reaction is very insufficient.

Disclosure of Invention

Aiming at the problems in the waste liquid treatment process, the application discloses a ruthenium-based catalyst-based catalytic reactor for removing hydrazine nitrate and hydroxylamine nitrate in nitric acid, which can efficiently, safely, economically and environmentally realize the recovery treatment of spent fuel.

The method utilizes ruthenium-based catalyst to catalytically decompose hydrazine nitrate and hydroxylamine nitrate in feed liquid into nitrogen, ammonia, hydrogen and water in a fixed bed mode, thereby achieving the purpose of removal, and the reaction equation is as follows:

according to one aspect of the present application, a fixed bed catalytic reactor is provided.

A fixed bed catalytic reactor comprises a shell, a feed liquid distribution plate and a feed liquid conveying core pipe, wherein the shell is enclosed to form a cavity;

the top of the shell is provided with a feed liquid inlet and a product outlet;

the feed liquid distribution plate is positioned at the inner lower part of the cavity;

the feed liquid conveying core pipe is positioned in the cavity;

the upper end of the feed liquid conveying core pipe is communicated with the feed liquid inlet;

the lower end of the feed liquid conveying core pipe penetrates through the feed liquid distribution plate and is located above the bottom of the shell.

The feed liquid enters the bottom of the shell through the feed liquid inlet and the feed liquid conveying core pipe and then passes through the feed liquid distribution plate and can be fully contacted with the catalyst bed layer, the feed liquid passes through the catalyst bed layer from bottom to top, so that gas generated after reaction flows out of the catalyst bed layer quickly, the gas and the feed liquid are not interfered with each other, the feed liquid can be fully contacted with the catalyst, and the reaction is complete.

The feed liquid inlet and the product outlet are positioned at the same side, and an upper feeding and discharging mode is adopted, so that the device is safer and more economical.

Optionally, a sieve plate is arranged above the inside of the shell;

and a spring is arranged on the sieve plate.

Specifically, one end of the spring is in contact with the screen plate and the other end is in contact with the top of the housing.

The spring and the sieve plate can compact the catalyst bed layer together to prevent the catalyst bed from loosening, and the stability of the whole catalyst bed can be realized due to the elasticity of the spring.

Optionally, the housing comprises a reactor end cap and a catalyst packing cartridge;

the reactor end cover is hermetically connected with the catalyst filling cylinder.

Optionally, the end cover of the reactor and the catalyst filling cylinder are hermetically connected by adopting a flange structure, and the sealing element is made of fluororubber.

Optionally, the inner diameter of the end cover of the reactor is 140-160 mm, and the height of the end cover of the reactor is 25-35 mm.

Specifically, the reactor end cap is 304 stainless steel.

Optionally, both feed liquid inlet and product outlet are provided in the reactor end cap.

Optionally, the inner diameter of the catalyst filling cylinder is consistent with the inner diameter of the end cover of the reactor, and the cylinder height is 160-200 mm.

Specifically, the catalyst filling cylinder is made of 304 stainless steel. The inner diameter of the cylinder is 140-160 mm and is consistent with the inner diameter of the end cover.

Optionally, the drift diameter of feed liquid entry is 6 ~ 10 mm.

Specifically, the material of the feed liquid inlet is 304 stainless steel material.

Optionally, the feed liquid conveying core pipe is a hollow pipe, the inner diameter of the hollow pipe is 4-6 mm, the outer diameter of the hollow pipe is 10-12 mm, and the length of the hollow pipe is 200-300 mm.

Optionally, the feed liquid conveying core pipe is positioned at the axial center of the reactor.

Specifically, the material of the feed liquid conveying core pipe is 304 stainless steel.

One end of the feed liquid conveying core pipe is connected with the feed liquid inlet, and the other end of the feed liquid conveying core pipe is arranged at the bottom of the reactor and used for conveying feed liquid.

Optionally, the feed liquid distribution plate is a multilayer sintered net, the thickness is 1-2 mm, and the filtering precision is 40-80 meshes.

Optionally, the wire diameter of the compression spring is 2-4 mm, and the maximum working stroke is not less than 10 mm.

Specifically, the material of the compression spring is 304 stainless steel material. The compression spring is matched with the sieve plate and used for compressing the catalyst bed layer.

Optionally, the drift diameter of the product outlet is 10-12 mm.

Specifically, the material of the product outlet is 304 stainless steel material.

Optionally, the fixed bed catalytic reactor is wholly wrapped with heat preservation cotton; the thickness of the heat preservation layer is 50-80 mm.

Optionally, the thickness of the insulating layer is not less than 50 mm.

Specifically, the heat-insulating cotton is made of aluminum silicate.

Optionally, the sieve plate may be a sieve plate or a screen mesh, and the material is 304 stainless steel.

Optionally, the fixed bed catalytic reactor comprises a reactor end cap and a catalyst packing cartridge;

the reactor end cover is hermetically connected with the catalyst filling cylinder;

the upper part of the catalyst filling cylinder is provided with a sieve plate, and the lower part of the catalyst filling cylinder is provided with a feed liquid distribution plate;

the reactor end cover is provided with a feed liquid inlet, the feed liquid inlet is connected with a feed liquid conveying core pipe, and the feed liquid conveying core pipe penetrates through the sieve plate and the feed liquid distribution plate until the bottom of the catalyst filling cylinder is approached.

As a specific embodiment, the fixed bed catalytic reactor comprises:

the device comprises a feed liquid inlet (1), a reactor end cover (2), a compression spring (3), a feed liquid conveying core pipe (4), a catalyst filling cylinder (5), a feed liquid distribution plate (6), heat-insulating cotton (7), a stainless steel sieve plate (8) and a product outlet (9);

the top of the reactor end cover (2) is provided with a feed liquid inlet (1) and a product outlet (9), and the catalyst filling cylinder (5) is used for filling the catalyst and is connected with the reactor end cover (2) in a sealing way through a flange. The catalyst bed layer is pressed by a stainless steel sieve plate (8) through a pressing spring (3). The feed liquid inlet (1) is used for inputting feed liquid, the feed liquid is conveyed to the bottom of the catalyst filling cylinder (5) through the feed liquid conveying core pipe (4) on the axis of the reaction zone, the feed liquid is uniformly distributed to the bottom of the catalyst bed layer from bottom to top through the feed liquid distribution plate (6), the feed liquid is contacted with the catalyst to carry out catalytic reaction, and a product is discharged from the product outlet (9) after passing through the stainless steel sieve plate (8). The outside of the reactor is wholly wrapped with heat insulation cotton (7).

According to a second aspect of the present application, a method for removing hydrazine nitrate and hydroxylamine nitrate from nitric acid is provided.

A method for removing hydrazine nitrate and hydroxylamine nitrate in nitric acid adopts the fixed bed catalytic reactor.

Optionally, a feed liquid containing hydrazine nitrate, hydroxylamine nitrate and nitric acid is conveyed to the bottom of the shell through a feed liquid inlet and a feed liquid conveying core pipe, the feed liquid is uniformly distributed by a feed liquid distribution plate and then applied to a catalyst bed layer from bottom to top, the feed liquid is contacted with a catalyst to perform catalytic reaction, and a product is discharged through a product outlet.

Optionally, in the feed liquid, the concentration of nitric acid is 0.5-2.0 mol/L; the concentration of the hydrazine nitrate is 0.1-0.5 mol/L; the concentration of hydroxylamine nitrate is 0.1-0.5 mol/L.

Optionally, the concentration of nitric acid in the feed liquid is 1.0 mol/L; the concentration of the hydrazine nitrate is 0.1 mol/L; the concentration of hydroxylamine nitrate was 0.3 mol/L.

The feed liquid treated by the method is a solution for treating nuclear power waste, and inevitably contains a very small amount of nuclear elements. As used herein, the feed solution contains 0.06g/L of hexavalent uranium.

Optionally, the catalyst is loaded into a catalyst loading cartridge; the catalyst is a supported ruthenium-based catalyst, the granularity is 4-8 meshes, porous activated carbon is used as a carrier, and the ruthenium loading is 1-5 wt%.

In the present application, the supported ruthenium-based catalyst can be selected from the prior art.

Alternatively, the operating conditions of the fixed-bed catalytic reactor are: the preheating temperature of the feed liquid is 60-95 ℃; the flow rate of the feed liquid is 0.02-4.0L/min.

Optionally, the preheating temperature is independently selected from any value of 60 ℃, 65 ℃, 70 ℃, 75 ℃, 80 ℃, 85 ℃, 90 ℃, 95 ℃, or a range value between any two.

Optionally, the flow rate of the feed liquid is independently selected from any of 0.02L/min, 0.03L/min, 0.04L/min, 0.05L/min, 0.06L/min, 0.07L/min, 0.08L/min, 0.1L/min, 0.15L/min, 0.2L/min, 0.5L/min, 1L/min, 1.5L/min, 2L/min, 2.5L/min, 3L/min, 3.5L/min, 4L/min, or a range between any two thereof.

Optionally, a feed liquid containing hydrazine nitrate, hydroxylamine nitrate and nitric acid is conveyed to the bottom of the catalyst filling cylinder through a feed liquid inlet and a feed liquid conveying core pipe, is uniformly distributed by a feed liquid distribution plate from bottom to top and is applied to the bottom of a catalyst bed layer in the catalyst filling cylinder, the feed liquid is contacted with the catalyst to perform catalytic reaction, and a product is discharged through a product outlet.

As a specific embodiment, the method comprises:

introducing feed liquid preheated to above 60-95 ℃, wherein the feed liquid comprises 0.5-2.0 mol/L nitric acid, 0.1-0.5 mol/L hydrazine nitrate and 0.1-0.5 mol/L hydroxylamine nitrate. The flow rate of the feed liquid is 0.02-4.0L/min, the catalytic reaction is started to continuously treat the feed liquid, and effluent liquid of a product outlet is taken to detect the content of hydrazine nitrate and hydroxylamine nitrate.

A catalyst filling cylinder 5 is taken, a feed liquid distribution plate 6 and a feed liquid conveying core pipe 4 are sequentially installed, a ruthenium-based catalyst with the granularity of 4-8 meshes is filled, and a stainless steel sieve plate 8, a compression spring 3 and a reactor end cover 2 are installed. The feed liquid input pipe and the product transmission pipe are respectively connected with the feed liquid inlet 1 and the product outlet 9 in a sealing way by utilizing the clamping sleeves.

The beneficial effect that this application can produce includes:

1) the fixed bed catalytic reactor provided by the application is cleaner and more environment-friendly in a mode of treating hydrazine nitrate and hydroxylamine nitrate based on the catalytic decomposition of a ruthenium-based catalyst compared with a traditional mode of adding an oxidant, and has no potential safety hazard.

2) According to the fixed bed catalytic reactor provided by the application, the working mode of the reactor is that a certain amount of catalyst is put in once to carry out removal, and the economic efficiency of the fixed bed catalytic reactor is superior to that of a mode of continuously adding an oxidant.

3) The fixed bed catalytic reactor provided by the application adopts a fixed bed continuous working mode, is simple to operate, is flexible and convenient, and can be efficiently connected with a subsequent treatment process.

Drawings

FIG. 1 is a sectional view of a fixed bed catalytic reactor.

Wherein, 1-feed liquid inlet 2-reactor end cover 3-compression spring

4-material liquid conveying core pipe 5-catalyst filling cylinder 6-material liquid distribution plate

7-heat preservation cotton 8-stainless steel sieve plate 9-product outlet

Detailed Description

The present application will be described in detail with reference to examples, but the present application is not limited to these examples.

Unless otherwise specified, the raw materials in the examples of the present application were purchased commercially, and if not specified, the test methods were performed by conventional methods, and the equipment settings were set according to the manufacturer's recommendations.

The catalyst is a supported ruthenium-based catalyst, the granularity is 4-8 meshes, porous activated carbon is used as a carrier, the ruthenium loading capacity is 5 wt%, and the preparation method is an impregnation method.

The analysis method in the examples of the present application is as follows:

and (3) testing and analyzing the contents of the solution hydrazine nitrate and hydroxylamine nitrate after the reaction by using a potentiometric titration method.

As shown in fig. 1. The reactor is designed in a fixed bed mode and comprises a feed liquid inlet, a reactor end cover, a compression spring, a feed liquid conveying core pipe, a catalyst filling cylinder, a feed liquid distribution plate, heat preservation cotton, a stainless steel sieve plate and a product outlet.

As shown in figure 1, a feed liquid inlet 1 and a product outlet 9 are arranged at the top of a reactor end cover 2, a catalyst filling cylinder 5 is used for filling a catalyst and is connected with the reactor end cover 2 in a sealing way through a flange, and the sealing piece is made of fluororubber. The catalyst bed layer is pressed by a stainless steel sieve plate 8 through a pressing spring 3. The feed liquid inlet 1 is used for feeding feed liquid, the feed liquid is conveyed to the bottom of the catalyst filling cylinder 5 through the feed liquid conveying core pipe 4 on the axis of the reaction zone, the feed liquid is uniformly distributed to the bottom of the catalyst bed layer from bottom to top through the feed liquid distribution plate 6, the feed liquid is contacted with the catalyst to perform catalytic reaction, and a product is discharged from the product outlet 9 after passing through the stainless steel sieve plate 8. The outside of the reactor is wholly wrapped with heat insulation cotton 7.

In the examples, the parameters of the components comprised by the fixed-bed catalytic reactor are specified below:

the drift diameter of the feed liquid inlet is 6 mm;

the inner diameter of the end cover of the reactor is 150mm, and the height of the end cover of the reactor is 30 mm;

the wire diameter of the compression spring is 3mm, and the maximum working stroke is not less than 10 mm;

the feed liquid conveying core pipe is a hollow pipe, the inner diameter of the hollow pipe is 6mm, the outer diameter of the hollow pipe is 10mm, and the length of the hollow pipe is 260 mm;

the inner diameter of the catalyst filling cylinder is consistent with the inner diameter of the end cover of the reactor, and the cylinder height is 180 mm;

the feed liquid distribution plate is a multilayer sintered net, the thickness is 2mm, and the filtering precision is 80 meshes;

the drift diameter of the product outlet is 10 mm.

The materials of the parts are all 304 stainless steel.

The heat preservation cotton is made of aluminum silicate and has the thickness of 60 mm.

Example 1

Weighing 700g of catalyst, placing the catalyst in a catalyst filling cylinder (5), covering a stainless steel sieve plate (8) above a feed liquid distribution plate (6), compacting the catalyst by using a compression spring, covering an end cover of a reactor, and screwing. Preheating feed liquid containing 0.3mol/L hydroxylamine nitrate, 0.1mol/L hydrazine nitrate, 1.0mol/L nitric acid and 0.06g/L hexavalent uranium to 60 ℃, pumping the feed liquid into a reactor for reaction through a feed liquid port (1) at the flow rate of 50mL/min, allowing the reacted solution to flow out of a product outlet (9), and measuring the content of the hydrazine nitrate in the reacted solution to be 0.0002mol/L and the content of the hydroxylamine nitrate to be 0.000005 mol/L.

Example 2

Weighing 700g of catalyst, placing the catalyst in a catalyst filling cylinder (5), covering a stainless steel sieve plate (8) above a feed liquid distribution plate (6), compacting the catalyst by using a compression spring, covering an end cover of a reactor, and screwing. Preheating feed liquid containing 0.3mol/L hydroxylamine nitrate, 0.1mol/L hydrazine nitrate, 1.0mol/L nitric acid and 0.06g/L hexavalent uranium to 80 ℃, pumping the feed liquid into a reactor for reaction through a feed liquid port (1) at a flow rate of 50mL/min, allowing the reacted solution to flow out of a product outlet (9), and measuring the content of the hydrazine nitrate and the hydroxylamine nitrate in the reacted solution to be 0.00001mol/L and 0.000008mol/L respectively.

Example 3

Weighing 700g of catalyst, placing the catalyst in a catalyst filling cylinder (5), covering a stainless steel sieve plate (8) above a feed liquid distribution plate (6), compacting the catalyst by using a compression spring, covering an end cover of a reactor, and screwing. Preheating feed liquid containing 0.3mol/L hydroxylamine nitrate, 0.1mol/L hydrazine nitrate, 1.0mol/L nitric acid and 0.06g/L hexavalent uranium to 60 ℃, pumping the feed liquid into a reactor for reaction through a feed liquid port (1) at a flow rate of 70mL/min, allowing the reacted solution to flow out of a product outlet (9), and measuring the content of the hydrazine nitrate in the reacted solution to be 0.0004mol/L and the content of the hydroxylamine nitrate to be 0.000009 mol/L.

Example 4

Weighing 700g of catalyst, placing the catalyst in a catalyst filling cylinder (5), covering a stainless steel sieve plate (8) above a feed liquid distribution plate (6), compacting the catalyst by using a compression spring, covering an end cover of a reactor, and screwing. Feed liquid containing 0.3mol/L hydroxylamine nitrate, 0.1mol/L hydrazine nitrate, 1.0mol/L nitric acid and 0.06g/L hexavalent uranium is preheated to 90 ℃, the feed liquid is pumped into a reactor for reaction through a feed liquid port (1) at a flow rate of 50mL/min, the solution after the reaction flows out from a product outlet (9), and the contents of the hydrazine nitrate and the hydroxylamine nitrate in the solution after the reaction are not detected.

Although the present application has been described with reference to a few embodiments, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the application as defined by the appended claims.

Claims (10)

1. A fixed bed catalytic reactor is characterized by comprising a shell, a feed liquid distribution plate and a feed liquid conveying core pipe, wherein the shell is enclosed to form a cavity;

the top of the shell is provided with a feed liquid inlet and a product outlet;

the feed liquid distribution plate is positioned at the inner lower part of the cavity;

the feed liquid conveying core pipe is positioned in the cavity;

the upper end of the feed liquid conveying core pipe is communicated with the feed liquid inlet;

the lower end of the feed liquid conveying core pipe penetrates through the feed liquid distribution plate and is located above the bottom of the shell.

2. The reactor of claim 1, wherein a sieve plate is arranged on the inner upper part of the shell;

and a spring is arranged on the sieve plate.

3. The reactor of claim 1, wherein the housing comprises a reactor end cap and a catalyst loading cartridge;

the reactor end cover is hermetically connected with the catalyst filling cylinder.

Preferably, the inner diameter of the end cover of the reactor is 140-160 mm, and the height of the end cover of the reactor is 25-35 mm;

preferably, the inner diameter of the catalyst filling cylinder is consistent with the inner diameter of the end cover of the reactor, and the cylinder height is 160-200 mm.

4. The reactor of claim 1, wherein the drift diameter of the feed liquid inlet is 6-10 mm;

preferably, the drift diameter of the product outlet is 10-12 mm.

5. The reactor according to claim 1, wherein the feed liquid conveying core pipe is a hollow pipe having an inner diameter of 4 to 6mm, an outer diameter of 10 to 12mm, and a length of 200 to 300 mm.

6. The reactor according to claim 1, wherein the feed liquid distribution plate is a multilayer sintered mesh, the thickness of the mesh is 1-2 mm, and the filtering precision is 40-80 meshes;

preferably, the spring is a compression spring; the wire diameter of the compression spring is 2-4 mm, and the maximum working stroke is not less than 10 mm.

7. The reactor of claim 1, wherein the fixed bed catalytic reactor is externally and integrally wrapped with heat insulation cotton; the thickness of the heat preservation layer is 50-80 mm.

8. A method for removing hydrazine nitrate and hydroxylamine nitrate from nitric acid, which is characterized in that a fixed bed catalytic reactor according to any one of claims 1 to 7 is used.

9. The method as claimed in claim 8, wherein the feed liquid containing hydrazine nitrate, hydroxylamine nitrate and nitric acid is delivered to the bottom of the shell through the feed liquid inlet and the feed liquid delivery core pipe, is uniformly distributed by the feed liquid distribution plate and then is applied to the catalyst bed layer from bottom to top, the feed liquid contacts with the catalyst to perform catalytic reaction, and the product is discharged through the product outlet.

10. The method according to claim 9, wherein the concentration of nitric acid in the feed liquid is 0.5-2.0 mol/L; the concentration of the hydrazine nitrate is 0.1-0.5 mol/L; the concentration of hydroxylamine nitrate is 0.1-0.5 mol/L;

preferably, the catalyst is a supported ruthenium-based catalyst, the particle size is 4-8 meshes, porous activated carbon is used as a carrier, and the ruthenium loading is 1-5 wt%;

preferably, the operating conditions of the fixed-bed catalytic reactor are: the preheating temperature of the feed liquid is 60-95 ℃; the flow rate of the feed liquid is 0.02-4.0L/min.

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