WO2015180501A1

WO2015180501A1 - Reducing gas circulation recycling system for pickling-free continuous annealing furnace and utilisation method therefor

Info

Publication number: WO2015180501A1
Application number: PCT/CN2015/070984
Authority: WO
Inventors: 李俊; 谭宁; 马新建; 关闯
Original assignee: 宝山钢铁股份有限公司
Priority date: 2014-05-30
Filing date: 2015-01-19
Publication date: 2015-12-03
Also published as: RU2684465C2; JP6538088B2; CN105132666A; JP2017524807A; KR20170009903A; RU2016151999A; RU2016151999A3

Abstract

A reducing gas circulation recycling system for a pickling-free continuous annealing furnace and a utilisation method therefor. The continuous annealing furnace comprises a pre-heating section (2), a heating section (3), a soaking section (4), a slow cooling section (5) and a rapid cooling section (6). The reducing gas circulation process is: reducing gas is extracted at a strip steel inlet of the pre-heating section (2); the extracted low-temperature reducing gas is cooled via a heat exchanger (8); the cooled gas enters a gas drying agent purification device (9) for dehydration, drying and removal of impurities, so that the gas dew point reaches below -20^oC; the dried reducing gas is supplemented with reducing gas in a gas-mixing device (10), and the mixed gas enters the rapid cooling section to rapidly cool strip steel (1); the reducing gas heated by the strip steel (1) enters the slow cooling section (5) to be further pre-heated by the strip steel (1), then enters the soaking section of the annealing furnace to reduce the strip steel (1); the reducing gas sequentially enters the heating section (3) and the pre-heating section (2), and the heated reducing gas gradually transfers heat to the cold strip steel (1); the cooled reducing gas is extracted from the strip steel inlet section, and a new circulation begins.

Description

Acid-free continuous annealing furnace reducing gas circulation regeneration utilization system and utilization method thereof

Technical field

The invention relates to a recycling gas recycling and utilization technology, in particular to a hydrochloric acid-free continuous annealing furnace reducing gas circulation recycling system and a utilization method thereof.

Background technique

When the hot-rolled sheet is subjected to subsequent processing or use, the surface scale is usually removed by pickling. In recent years, it has been proposed that the hot-rolled sheet can be directly subjected to reduction annealing without pickling, and the surface oxide scale is reduced by a reducing gas. The direct use of metal iron, which not only improves the metal yield and product, but also simplifies the production process, is receiving much attention.

The international patents of US Pat. No. 6,402, 852 B2, US Pat. No. 6,588, 491 B2, WO 00/12233, WO 0003 815 A1 and WO 019 929 A1 disclose processes and equipment for the reduction of surface scale of hot rolled strip by hydrogen reduction. In the process, the hydrogen in the reducing medium is not excessive, and most of the hydrogen is consumed by the scale, and the remaining small amount of hydrogen is directly burned and discharged. No. 6,258,186, B1 discloses a process for reducing hot-rolled steel strip by hot gas and then hot-dip galvanizing, but the process does not involve the use of reducing gas. The Chinese patents with the publications CN101956061 and CN102653815 disclose the process of recycling and protecting the gas of the bell-type bright annealing furnace. The protective gas is condensed and removed by the condenser, the oil is absorbed by the oil absorber, and the deep-drying water is removed and then supplied to the bell-type bright annealing furnace. However, there is no question about the energy utilization of the protective gas from high temperature to low temperature and then from low temperature to high temperature. The Chinese patent application No. 200710039842.8 discloses an annealing furnace protective atmosphere recycling method, which is directed to the recovery of the atmosphere in the continuous silicon nitride annealing furnace of the oriented silicon steel. The basic process is condensation and dehydration of the reducing gas, filtering and removing impurities and then entering the combustion tube. The road system heats the strip steel, which is a single-cycle process, and the utilization efficiency is not high, resulting in waste of energy.

Summary of the invention

The object of the present invention is to provide a hydrochloric acid-free continuous annealing furnace reducing gas circulation recycling system and a utilization method thereof, thereby saving energy consumption and reducing cost.

According to an aspect of the present invention, there is provided an acid-free continuous annealing furnace reducing gas circulation recycling system, comprising a continuous annealing furnace, which has a preheating section, a heating section, a soaking section, and a slow connection in the strip conveying direction. The cold section and the quick cooling section are characterized by:

An exhaust fan is provided at the inlet of the strip in the preheating section for extracting the reducing gas in the preheating section;

a heat exchanger, the input end is connected to the exhaust fan through a pipeline, and is used for heat exchange and cooling of the extracted reducing gas;

a gas desiccant purification device, wherein the input end is connected to the heat exchanger through a pipeline for removing a small amount of water vapor generated by the reduction of the strip by the reducing gas;

The mixing device has an input end connected to the gas desiccant purifying device through a pipeline, a reducing gas supplementing tube at the other input end, and an output end connected to the quick cooling section through the pipeline, and the reducing gas and the supplementary reducing by drying After the gas is fully mixed to form a new reducing gas, it is input into the continuous annealing furnace from the rapid cooling section, and is reversed with the strip steel, and the strip steel is rapidly cooled in the rapid cooling section, and preheated and soaked in the slow cooling section. After the annealing in the section, the heating in the heating section, and the heat exchange in the preheating section, the heat is exchanged by the exhaust fan to the heat exchanger to form a new cycle.

Also included are two flow control valves, wherein the first flow control valve is mounted between the heat exchanger and the strip preheating section, and the second flow control valve is mounted to the reducing gas supplemental line of the agitation unit.

The utility model further comprises a plurality of boosting pumps, which are arranged on the pipeline between the first flow control valve and the heat exchanger, the quick cooling section and the slow cooling section, the slow cooling section and the heating section and the soaking section respectively.

Also included is a disturbance device that is installed in the soaking section of the annealing furnace.

It also includes two pressure detecting devices connected to the preheating section of the continuous annealing furnace and the air mixing device through a pipeline to detect the pressure in the furnace and the aeration pressure of the air mixing device.

A reducing gas concentration detector is further disposed on the reducing gas supply tube for detecting the concentration of the reducing gas to be replenished.

Also included is a dew point detecting device that is connected by a pipe between the gas desiccant purification device and the aeration device.

Also included is a dew point detection feedback device mounted on a conduit between the gas desiccant purification unit and the dew point detection unit.

A sealing roller is further disposed between the heating section and the soaking section in the continuous annealing furnace, and between the soaking section and the cooling section.

Also included is a bleed valve disposed at the other output of the aeration device for venting excess reducing gas.

The heating section and the soaking section are also supplemented by means of electric resistance heating, radiant heating, infrared heating or induction heating.

The drying medium used in the gas drying and purifying device is any one of molecular sieve, silica gel, activated alumina, anhydrous calcium chloride, calcium oxide, concentrated sulfuric acid, and phosphorus pentoxide.

According to another aspect of the present invention, there is provided a method for reducing and recycling a reducing gas in a pickling-free continuous annealing furnace, which is carried out in the acid-free continuous annealing furnace reducing gas circulation recycling system according to any one of claims 1 to 12, Includes the following steps:

Extracting the preheated reducing gas from the strip inlet of the preheating section, and transmitting the measured pressure signal to the exhaust fan through the pressure detecting device to control the speed of the exhaust fan and adjust the pumping flow rate;

The heat of the extracted reducing gas is exchanged by a heat exchanger, and further cooled to a temperature acceptable for the subsequent gas desiccant purification device;

Passing the cooled reducing gas into the gas desiccant purification device for deep dehydration, removing trace impurities, drying, and inputting into the gas mixing device;

After the component is detected, a new reducing gas is added and thoroughly mixed to form a new reducing gas, and then input from the rapid cooling section of the continuous annealing reduction furnace, and the strip is reversed in the entire continuous annealing furnace, and is successively fast. The strip is rapidly cooled in the cold section. After the rapid cooling, the gas heated by the strip enters the slow cooling section to slowly cool the strip and is further preheated by the strip. The preheated gas enters the soaking section to reduce the strip. After the heating section and the preheating section, the hot reducing gas is gradually transferred to the cold strip, and the cooled reducing gas is taken out from the strip inlet to start a new cycle.

After the reducing gas is treated by the gas drying and purifying device, the gas dew point is below -20 °C.

After the reducing gas is treated by the gas drying and purifying device, the gas dew point is below -40 °C.

Compared with the prior art, the present invention has the following advantages:

1. Excessive reducing medium (hydrogen) that does not participate in the reaction in the reducing gas can be recycled 100%, saving resources and reducing production costs;

2. The energy can be utilized efficiently, that is, the gas which has been cooled and dried in the outlet section of the furnace is used to cool the hot strip after reduction, and the soaked high temperature gas is used to sequentially heat and preheat the steel, thereby Both the reducing gas and the heat energy of the strip are effectively utilized.

3. Gas recycling, with less pollutant emissions, can basically achieve zero emissions.

DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view showing a system for reducing gas recycling of an acid-free continuous annealing furnace according to an embodiment of the present invention.

detailed description

The above described objects, features and advantages of the present invention will become more apparent from the aspects of the appended claims. It should be noted that the present invention is not limited to the specific embodiments described below, and those skilled in the art should understand the present invention from the spirit embodied in the following embodiments. The technical terms may be understood broadly based on the spirit of the invention. The same reference numerals in the drawings denote the same parts.

1 shows a hydrogenation-free continuous annealing furnace reducing gas circulation recycling system according to an embodiment of the present invention, as shown in the drawing, including a preheating section 2, a heating section 3, a soaking section 4, a slow cooling section 5, and a fast Continuous annealing furnace of cold section 6, heat exchanger 8, gas desiccant purification device (using deep drying tower) 9, aeration device 10, preheating section 2, heating section 3, soaking section 4, slow cooling section 5 And the quick cooling section 6 is sequentially connected in the conveying direction of the strip 1 , and an exhaust fan (not shown) is installed at the inlet of the strip in the preheating section for extracting the reducing gas in the preheating section 2, And the pressure signal in the furnace transmitted by the pressure sensor P1 is used to control the rotation speed and adjust the pumping flow rate, and the input end of the heat exchanger 8 is connected to the exhaust fan through a pipeline for heat exchange and cooling of the extracted reducing gas; gas drying The input end of the agent purifying device 9 is connected to the heat exchanger 8 through a pipeline for removing a small amount of water vapor generated by the reduction of the reducing gas, and performing deep drying of the reducing gas to remove water and filtering out other impurities; Device 10 is connected to gas desiccant purification device 9 and fast On the pipe between the segments 6, an input end is connected to the gas desiccant purifying device 9 through a pipe, and the other input end is provided with a reducing gas replenishing pipe 16, and an output end is connected to the quick cooling portion 6 through a pipe, and after drying, The reducing gas is thoroughly mixed with a supplementary reducing gas (such as H2 or CO) to form a new reducing gas, and then input into the continuous annealing furnace from the rapid cooling section, and the strip 1 is reversed, and the strip 1 is sequentially fastened. Rapid cooling in the cold section 6, preheating in the slow cooling section 5, annealing in the soaking section 4, heating in the heating section 3, heat exchange in the preheating section 2, and then pumped out to the heat exchanger by the extractor , a new cycle is formed, and during this period, the reducing gas is reversely exchanged with the strip 1 for heat exchange, that is, the reducing gas sequentially absorbs the heat of the strip in the fast cooling section 6 and the slow cooling section 5, so that it is heated to a high temperature, and the soaking section 4 A process of reducing the strip and then transferring the heat to the strip in the heating section 3 and the preheating section 2 to gradually cool itself.

The acid-free continuous annealing furnace reducing gas circulation recycling system of the present invention further comprises the following components: two flow control valves 7, and the first flow control valve 7 is installed between the heat exchanger 8 and the preheating section 2 The second flow control valve 7 is installed in the reducing gas supplement pipe 16 of the air mixing device 10 for controlling the gas flow rate; the plurality of booster pumps M are disposed in the first flow control valve 7 and the heat exchanger 8, respectively. The cold section 6 and the slow cooling section 5, the slow cooling section 5 and the pipe connecting the heating section 3 and the soaking section 4 are used for pressurization; the disturbance device 11 is installed in the soaking section 4 in the annealing furnace to make the gas In the turbulent state, two pressure detecting devices P are respectively connected to the preheating section 2 of the continuous annealing furnace and the air mixing device 10 through a pipeline for detecting the pressure in the furnace and the mixing pressure of the air mixing device; The meter 13 is disposed on the reducing gas supplement pipe 16 for detecting the concentration of the reducing gas to be replenished; a dew point detecting device DP is connected between the gas desiccant purifying device 9 and the air mixing device 10 through a pipe for detecting the Gas drying and purification The dew point of the device after treatment; a dew point detection feedback device is installed on the pipeline between the gas desiccant purification device 9 and the dew point detecting device DP to determine whether the dew point of the dry gas meets the requirements, and if the undesired 122 gas is returned to dry The device is re-dried until the dew point setting value; two pairs of sealing rollers 12 are respectively installed between the heating section 3 and the soaking section 4 in the annealing furnace and between the soaking section 4 and the cooling section 6, for isolating different sections a hot and cold gas to prevent cross flow of the gas; and a discharge valve 14 disposed at the other output end of the air mixing device 10 to determine whether to release excess drying according to the pressure detection signal of the air mixing device 10 detected by the pressure detecting device P After the reducing gas to ensure safety.

In addition, the heating section 3 and the soaking section 4 may be heated by a high-temperature reducing gas, and may be supplemented by means of resistance heating, radiant heating, infrared heating or induction heating.

The drying medium used in the gas drying and purifying device 9 may be any one or a mixture of molecular sieve, silica gel, activated alumina, anhydrous calcium chloride, calcium oxide, concentrated sulfuric acid or phosphorus pentoxide.

The method for recovering and recycling the reducing gas in the pickling-free continuous annealing furnace of the present invention is carried out in the above-mentioned acid-free continuous annealing furnace reducing gas circulation recycling system shown in FIG. 1, comprising the steps of: reducing gas in the entire continuous annealing furnace The inner side is stripped with the strip 1 (in the entire continuous annealing furnace, the flow direction of the reducing gas is reversed with the strip 1), and is taken out from the strip inlet of the preheating section 2 and preheated with the strip 1 The reducing gas is passed through the pressure detecting device P to transmit the measured pressure signal in the furnace to the exhaust fan to control the rotating speed of the exhaust fan and adjust the pumping flow rate; and the pre-tropical steel in the preheating section of the reducing gas before being extracted 1, the gas temperature decreases after preheating;

The extracted lower temperature reducing gas is further subjected to heat exchange through the heat exchanger 8, and further cooled to a temperature acceptable for the subsequent gas desiccant purification device;

The cooled reducing gas is input into the gas desiccant purification device 9 to perform deep dehydration, remove trace impurities, and dry, and is detected by the dew point detecting device DP to ensure that the gas dew point is below -20 ° C after being treated by the gas drying and purifying device. Good to below -40 ° C.

After the component is detected, the fresh reducing gas is appropriately added and thoroughly mixed to form a new reducing gas, and then input from the rapid cooling section 6 of the continuous annealing reduction furnace, and the strip 1 is reversed in the continuous annealing furnace, and sequentially The strip is rapidly cooled in the fast cooling section 6. After the rapid cooling, the gas heated by the strip enters the slow cooling section 5 to slowly cool the strip 1 and is further preheated by the strip, and the preheated gas enters the soaking section. 4 to carry out the reduction strip, and then through the heating section 3 and the preheating section 2, the hot reducing gas is gradually transferred to the cold strip 1, and the cooled reducing gas is extracted from the strip inlet to start a new cycle. .

The reducing medium of the present invention is much higher than the theoretical value required for the scale, in order to increase the scale reduction rate and efficiency, but the reducing gas of the present invention is recycled and utilized, and the excess reducing medium does not significantly increase the production cost. .

In order to more clearly understand the features and advantages of the system and method of the present invention, the specific implementation steps of the recycling gas recycling and utilization mode are further illustrated by:

The strip 1 runs from the right (inlet) to the left (outlet), and the reducing gas is extracted from the inlet of the strip. The furnace pressure sensor P transmits the furnace pressure signal to the exhaust fan port, controls the fan speed, and adjusts the flow control valve 7 to ensure The furnace pressure (micro positive pressure) is stable. At this time, the extracted protective gas has a small amount of water vapor generated by the reaction with the iron oxide scale on the surface of the steel strip, and the gas has a certain temperature, and is cooled by the heat exchanger 8 to enter the gas desiccant purification device 9 to remove water vapor and impurity components. The dew point detection feedback device 15 adjusts the action until the gas dew point is below -20 °C. The dried reducing gas enters the aeration device 10, and is appropriately replenished with fresh hydrogen according to the component detection result detected by the reducing gas concentration detector 13, because a small amount of reducing medium is consumed through the scale, the hydrogen concentration is continuously detected, and feedback is made to the flow control. Valve 7 is controlled until the concentration reaches the set value. The relief valve 14 mainly ensures the safety of the mixing station, and determines whether to release through the relief valve 14 based on the pressure detection signal of the air mixing device. The mixed reducing gas is injected into the quick cooling section 6 through a booster pump M, and can be sprayed on the strip surface at a certain angle by a cyclic spray method for rapidly cooling the strip steel, and is quickly cooled and stripped. The heated reducing gas is introduced into the slow cooling section 5 via another booster pump M and further preheated by the strip 1 and then the hot gas enters the soaking section 4 and the heating section 3. The reducing gas entering the furnace flows from the left (outlet) to the right (inlet) into the preheating section 2, so that the heat of the hot reducing gas is gradually transferred to the cold strip, and the strip heating reduces the temperature of the reducing gas and is cooled. The reducing gas (where the hydrogen concentration has decreased and the water content has increased) is withdrawn from the strip inlet section and a new cycle of water removal, purification, regeneration (recovering its reducing performance) begins.

Compared with the prior art, the invention has the following advantages: excess reducing medium in the reducing gas which is not involved in the reaction can be recycled 100%, saving energy and reducing production cost; energy can be utilized efficiently, and high temperature gas can be used in the soaking section To heat and pre-tropical steel, the cooled and dried reducing gas entering from the outlet section of the furnace can be used to cool the hot strip, and the heat of the reducing gas and the strip can be effectively utilized and recycled. With less pollutant emissions, it can basically achieve zero emissions, and the effect is very significant.

It is to be understood that various modifications and changes may be made to the present invention, and the scope of the invention is defined by the scope of the appended claims.

Claims

An acid-free continuous annealing furnace reducing gas circulation regeneration utilization system, comprising a continuous annealing furnace, which has a preheating section, a heating section, a soaking section, a slow cooling section and a quick cooling section which are sequentially connected in a strip conveying direction , characterized in that it also includes:

An exhaust fan is provided at the inlet of the strip in the preheating section for extracting the reducing gas in the preheating section;

a heat exchanger, the input end is connected to the exhaust fan through a pipeline, and is used for heat exchange and cooling of the extracted reducing gas;

a gas desiccant purification device, wherein the input end is connected to the heat exchanger through a pipeline for removing a small amount of water vapor generated by the reduction of the strip by the reducing gas;

The mixing device has an input end connected to the gas desiccant purifying device through a pipeline, a reducing gas supplementing tube at the other input end, and an output end connected to the quick cooling section through the pipeline, and the reducing gas and the supplementary reducing by drying After the gas is fully mixed to form a new reducing gas, it is input into the continuous annealing furnace from the rapid cooling section, and is reversed with the strip steel, and the strip steel is rapidly cooled in the rapid cooling section, and preheated and soaked in the slow cooling section. After the annealing in the section, the heating in the heating section, and the heat exchange in the preheating section, the heat is exchanged by the exhaust fan to the heat exchanger to form a new cycle.
The acid-free continuous annealing furnace reducing gas circulation regeneration utilization system according to claim 1, further comprising two flow control valves, wherein the first flow control valve is installed in the heat exchanger and the strip preheating section The intermediate flow control valve is installed on the reducing gas supply pipe of the aeration device.
The acid-free continuous annealing furnace reducing gas circulation recycling system according to claim 2, further comprising a plurality of boosting pumps, which are disposed in the first flow control valve and the heat exchanger, the quick cooling section and the slow cooling The section and the slow cooling section are respectively on the pipeline between the heating section and the heating section.
The acid-free continuous annealing furnace reducing gas circulation recycling system according to claim 1, further comprising a disturbance device installed in the soaking section of the annealing furnace.
The acid-free continuous annealing furnace reducing gas circulation recycling system according to claim 1, further comprising two pressure detecting devices respectively connected to the preheating section and the air mixing device of the continuous annealing furnace through the pipeline, In order to detect the pressure in the furnace and the aeration pressure of the aeration device.
The acid-free continuous annealing furnace reducing gas circulation recycling system according to claim 1, further comprising a reducing gas concentration detector disposed on the reducing gas supply pipe for detecting the concentration of the reducing gas to be charged.
The acid-free continuous annealing furnace reducing gas circulation recycling system according to claim 1, further comprising a dew point detecting device connected between the gas desiccant purifying device and the air mixing device via a pipe.
The acid-free continuous annealing furnace reducing gas circulation regeneration utilization system according to claim 7, further comprising a dew point detecting feedback device installed on a pipe between the gas desiccant purification device and the dew point detecting device.
The acid-free continuous annealing furnace reducing gas circulation recycling system according to claim 1, wherein a heating section and a soaking section in the continuous annealing furnace, and a soaking section and a cooling section are further provided Sealing roller.
The acid-free continuous annealing furnace reducing gas circulation regeneration utilization system according to claim 1, further comprising a discharge valve disposed at the other output end of the air mixing device for discharging excess reducing gas.
The acid-free continuous annealing furnace reducing gas circulation recycling system according to claim 1, wherein the heating section and the soaking section are further supplemented by means of resistance heating, radiant heating, infrared heating or induction heating. .
The acid-free continuous annealing furnace reducing gas circulation recycling system according to claim 1, wherein the drying medium used in the gas drying and purifying device is molecular sieve, silica gel, activated alumina, anhydrous calcium chloride, Any of calcium oxide, concentrated sulfuric acid, and phosphorus pentoxide.
An acid-free continuous annealing furnace reducing gas recycling and utilization method, characterized in that it is implemented in the acid-free continuous annealing furnace reducing gas circulation recycling system according to any one of claims 1 to 12, comprising the following steps :

Extracting the preheated reducing gas from the strip inlet of the preheating section, and transmitting the measured pressure signal to the exhaust fan through the pressure detecting device to control the speed of the exhaust fan and adjust the pumping flow rate;

The heat of the extracted reducing gas is exchanged by a heat exchanger, and further cooled to a temperature acceptable for the subsequent gas desiccant purification device;

Passing the cooled reducing gas into the gas desiccant purification device for deep dehydration, removing trace impurities, drying, and inputting into the gas mixing device;

After the component is detected, the reducing gas is replenished and thoroughly mixed to form a new reducing gas, and then input from the rapid cooling section of the continuous annealing reduction furnace, and the strip is reversed in the entire continuous annealing furnace, and sequentially in the rapid cooling section. The strip steel is rapidly cooled. After the rapid cooling, the gas heated by the strip enters the slow cooling section to slowly cool the strip and is further preheated by the strip. The preheated gas enters the soaking section to reduce the strip, and then Heating section And the preheating section causes the hot reducing gas to gradually transfer heat to the cold strip, and the cooled reducing gas is withdrawn from the strip inlet to start a new cycle.
The method for recycling and recycling a reducing gas in a pickling-free continuous annealing furnace according to claim 13, wherein the reducing gas is treated by a gas drying and purifying device, and the gas dew point is -20 ° C or lower.
The method for recycling and recycling a reducing gas in a pickling-free continuous annealing furnace according to claim 14, wherein the reducing gas is treated by a gas drying and purifying device, and the gas dew point is below -40 °C.