RU2761604C1 - Positive pressure coke oven heating system and method for temperature control - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention relates to the field of coke oven heating (heat curing) technologies, in particular to a positive pressure coke oven heating system (positive pressure heating system for a coke oven) and a temperature control method. A system of heating a coke oven at positive pressure and a method for temperature control are claimed. This method includes: setting the pressure on the heating gas main gas pipeline as a control object, automatic calculation and real-time regulation of the degree of opening of the electric control valve of the heating gas main gas pipeline (2) in accordance with the deviation between the actual and set pressure, as well as the rate of change of the deviation to ensure the stability of the heating gas pressure during the heating process. Regarding the regulation of the heating device (5) at positive pressure, input of the feedback value regarding the degree of opening of the control valve of the heating gas outlet to the control system for step regulation. In this case, the main circuit is designed to control the heating temperature of the coke oven, and the second circuit is designed to control the degree of opening of the specified control valve. With regard to controlling the opening degree of said control valve, adding the default opening degree control of said control valve to eliminate free play, thereby eliminating the influence caused by free running said control valve in the positive pressure coke oven heating device.

EFFECT: precise control of heating temperature and improved accuracy of automatic temperature control of the heating system under positive pressure.

16 cl, 6 dwg

Description

Cross-reference to related application

The present invention claims priority from Chinese patent application registration number 2019104265818, filed May 22, 2019 with the Chinese Patent Office, entitled "Positive pressure coke oven heating system and temperature control method", the contents of which are incorporated by reference in their entirety. ...

Technology area

The present invention relates to the field of coke oven heating (heat curing) technologies, in particular to a positive pressure coke oven heating system (positive pressure heating system for a coke oven) and a temperature control method.

State of the art

Heating is an important and challenging process before starting coke oven production, and its quality is critical to the life of coke ovens. With the development of the trend towards larger coke ovens, the advantages of the positive pressure heating method are becoming more and more evident. However, the existing positive pressure coke oven heating system can hardly accurately control the heating temperature.

Disclosure of the essence of the invention

An object of the present invention is to provide a positive pressure coke oven heating system and a temperature control method in order to solve the problem of poor control accuracy of the heating temperature of a positive pressure coke oven heating system in the prior art.

To achieve the above object, the present invention is realized by the following technical solution.

In one aspect, the present invention provides a positive pressure coke oven heating system including a plurality of flue gas vents coupled to a single heating gas main line, each flue gas outlet being connected to one positive pressure heating device, further comprising a sensor of the heating gas main pipeline pressure and the electric main pipeline control valve, while the heating gas main pipeline pressure sensor and the electric main pipeline control valve are electrically connected to the heating control system under positive pressure.

As an example of implementation of the invention, the electric control valve of the heating gas main pipeline is installed upstream of all gas outlet pipes, and the shut-off valve of the heating gas main pipeline is located upstream of all electric control valves of the heating gas main pipeline.

As an example of implementation of the invention, the pressure sensor of the heating gas main pipeline is installed upstream of all gas outlet pipes and is located downstream of the electric control valve of the heating gas main pipeline.

As an example of implementation of the invention, a positive pressure heating device comprises a first burner, a second burner, a gas supply pipe (or a fuel gas supply pipe) and an air supply pipe, one branch of the gas supply pipe being connected to the gas inlet of the first burner through a control valve of the first gas outlet. a nozzle, and the other branch of the gas supply pipe is connected to the gas inlet of the second burner through a control valve of the second gas outlet; and the air supply pipe has one branch connected to the air inlet of the first burner, and the other branch is connected to the air inlet of the second burner.

As an example of the implementation of the invention, the gas supply pipe is equipped with a gas shut-off valve.

As an example of the invention, the upstream end of the inlet of the air supply pipe is connected to a blower.

As an example of implementation of the invention, the positive pressure heating device further comprises a control cabinet, wherein both the first control valve of the gas outlet pipe and the second control valve of the gas outlet pipe are electrically connected to the control cabinet, and the control cabinet is electrically connected to the heating control system under positive pressure ...

As an example of the implementation of the invention, the positive pressure heating device further comprises:

a first thermocouple configured to measure the flame temperature of the first burner;

a second thermocouple configured to measure the flame temperature of the second burner;

a first high voltage igniter configured to ignite the first burner; and

a second high voltage igniter configured to ignite the second burner.

As an example of implementation of the invention, the gas pipelines between the control valve of the first gas outlet and the gas inlet of the first burner, as well as between the control valve of the second gas outlet and the gas inlet of the second burner are metal hoses.

As an example of the implementation of the invention, the air supply pipe is a PVC hose.

As an example of the implementation of the invention, each gas outlet is equipped with a shut-off valve at the outlet of the heating gas pipeline.

As an example of implementing the invention, a positive pressure heating control system is configured to:

calculating and regulating the degree of opening of the electric control valve of the heating gas main pipeline in accordance with the deviation between the actual and the set pressure in the coke oven, as well as the rate of change of the deviation, in order to ensure the stability of the heating gas pressure during the heating process.

According to a second aspect, an implementation of the present invention provides a temperature control method for a positive pressure coke oven heating system, the control method comprising the following:

(1) setting the pressure of the heating gas main pipe as a control object, automatically calculating and adjusting the opening degree of the electric control valve of the heating gas main pipe in real time in accordance with the deviation between the actual and target pressure and the deviation rate of change, in order to ensure the stability of the heating gas pressure during the entire heating process; and

(2) input, when controlling the heating device under positive pressure, the feedback value of the degree of opening of each control valve of the gas outlet to the control system to achieve step control, while the control of the heating temperature of the coke oven is the main loop, and the control of the degree of opening of each control valve is the valve of the gas outlet pipe is a secondary circuit; and

when controlling the degree of opening of each control valve of the gas outlet pipe, adding control of a given degree of opening of each control valve to eliminate the idle speed difference,

1) a gradual decrease in the preset degree of opening of the control valve at a certain step length and frequency, when the feedback value of the actual degree of opening of the control valve of the gas outlet is greater than the preset degree of opening, until the feedback value of the actual degree of opening of the valve changes downward, and immediately adjusting the predetermined degree of its opening to the original predetermined value, before the reduction is performed;

2) a gradual increase in the preset degree of opening of the control valve at a certain step length and frequency, when the feedback value of the actual degree of opening of the control valve of the gas outlet is less than the preset degree of opening, until the feedback value of the actual degree of opening of the valve changes upward, and immediately adjusting the predetermined degree of its opening to the original predetermined value, before the increase is performed;

3) maintaining the current degree of valve opening when the actual degree of opening of the control valve of the gas outlet pipe is adjusted within the permissible error range, and completing the current adjustment.

As an example of the implementation of the invention, the formula for calculating the control value of the degree of opening of the electric control valve of the main pipeline is as follows:

where:

- контрольная величина степени открытия регулирующего клапана в момент времени k;In the formula:

- control value of the degree of opening of the control valve at time k;

- отклонение между фактическим и заданным давлением в момент времени k, где фактическое давление измеряется системой, заданное давление устанавливается вручную, и заданное давление должно оставаться неизменным на протяжении всего процесса регулировки;

- the deviation between the actual and the set pressure at time k, where the actual pressure is measured by the system, the set pressure is set manually, and the set pressure must remain unchanged throughout the entire adjustment process;

- коэффициент пропорциональности; и

- coefficient of proportionality; and

,

,

- пропорциональные, интегральные и дифференциальные постоянные времени, соответственно.

,

,

- proportional, integral and differential time constants, respectively.

As an example of the implementation of the invention, the stage of input, when controlling the heating device under positive pressure, the feedback value of the degree of opening of the control valve of the gas outlet pipe to the control loop to achieve step regulation, includes:

reading, using a computer, the optimization of the heating process under positive pressure, the planned temperature when the temperature rises for heating in a computer that measures the heating temperature in the coke oven, as well as the current temperature and pressure in the coke oven, measured through the OPC gateway;

calculation of the permissible degree of opening of each control valve of the gas outlet in the heating system of the coke oven at positive pressure using the heating optimization control method at positive pressure;

sending, by a computer to optimize the heating process under positive pressure, the value of the allowable degree of opening of each control valve of the gas outlet, calculated for each control valve, and reading feedback regarding the degree of opening of each control valve of the gas outlet;

setting the permissible error range of the degree of opening of each control valve of the gas outlet pipe by setting the dead zone and setting the maximum permissible upper adjustment limit;

determining, using a positive pressure heating optimization computer, whether each gas outlet control valve has been adjusted to an acceptable range of the opening degree by comparing the value of the set opening degree and the actual feedback of the opening degree of each gas outlet control valve; as well as

adjustment of the control valve of the gas outlet pipe in the permissible range of the degree of opening.

As an example of the implementation of the invention, a method for controlling the optimization of heating under positive pressure includes:

simulate the temperature rise for heating, control the Smith's pre-estimate compensation, control simulate human intelligence and control the shutdown of the temperature of adjacent combustion chambers, while simulating the temperature rise for heating analyzes the relationship between combustion chamber temperature, flue gas pressure, temperatures of adjacent combustion chambers, etc. the suction force of the secondary smoke channel and determines the functional relationship between the variable temperature in the furnace and the control value of the heating device; Controlling the Smith Estimated Compensation to avoid or reduce the effect of temperature control hysteresis by calculating the estimate; the human intelligence simulation control makes appropriate decisions by detecting various features of the temperature deviation, and calculates the control value of the heating device; and the control of turning off the temperature of the adjacent combustion chambers is dynamically correcting the control value of the heating device in accordance with the temperature change of the adjacent combustion chambers, thereby realizing the temperature equalization in the furnace.

Compared with the prior art, the present invention has the following beneficial effects:

1.The main gas pipeline pressure stability control unit can ensure the stability of the heating gas pressure during the heating process, eliminate the influence of the gas pressure of the heating gas main gas at a heating temperature under positive pressure, avoid temperature fluctuations in the furnace caused by changes in the heating gas pressure, and improve the temperature control accuracy , as well as

2.When controlling the degree of opening of the control valve of the gas outlet pipe, the control of the set degree of opening of the control valve was also added to eliminate the difference in idle speed, which effectively avoids the influence of the difference in idle speed of the control valve of the gas outlet pipe of the coke oven heating device under positive pressure on the accuracy of control of the heating temperature and significantly improve the quality of heating the coke oven.

Brief Description of Drawings

FIG. 1 is a schematic view of a positive pressure coke oven heating system in an embodiment of the present invention;

FIG. 2 is a block diagram of a positive pressure coke oven heating system in an embodiment of the present invention;

FIG. 3 is a schematic view of a positive pressure heating device in an embodiment of the present invention;

FIG. 4 is a block diagram of a positive pressure heating apparatus in an embodiment of the present invention;

FIG. 5 is a schematic view of a positive pressure heating control system in an embodiment of the present invention; as well as

FIG. 6 is a block diagram of a coke oven positive pressure heating device temperature control in an embodiment of the present invention.

Reference positions: 1-shut-off valve of the heating gas main pipeline; 2-electric control valve of the heating gas main pipeline; 3-pressure sensor of the heating gas main pipeline; 4 - shut-off valve for the heating gas pipeline; 5 - heating device at positive pressure; 51 - gas supply pipe; 511-gas safety shut-off valve; 52 - control valve of the first gas outlet pipe; 53 - control valve of the second gas outlet pipe; 54 - the first burner; 541 - the first thermocouple; 542 - first high voltage igniter; 55 - second burner; 551 - second thermocouple; 552 - second high voltage igniter; 56 - blower; 57 - air supply pipe; 58 - control cabinet.

Implementation of the invention

The purpose of heating is to remove natural and crystallized water from the substrate of the furnace body to prevent rupture, blistering, deformation or destruction of the furnace body or even the furnace wall due to the furnace heating up too quickly and the expansion of a large amount of water at the start of the process, which affects the strength and the service life of the furnace wall. Existing coke ovens usually go through a heating process before starting operation, and as coke ovens grow in size, positive pressure heating has clear advantages. Especially for coke ovens of 7.63 m and larger, positive pressure heating is usually used. The heating process has a significant effect on the life of coke ovens and therefore the temperature must be precisely controlled. However, the existing positive pressure heating system for coke ovens has the following disadvantages.

1. The heating temperature under positive pressure is largely influenced by the gas pressure in the heating gas main pipeline, and when the pressure in the heating gas gas source fluctuates, it is often impossible to adjust it in a timely manner, therefore the heating temperature will vary greatly and directly affect the heating quality, and also create a heavy workload for heating personnel.

2. Since all flue gas control valves corresponding to the existing positive pressure heating system have a certain idle difference, the control valves cannot accurately meet the control value given by the positive pressure heating control system, so this greatly affects the accuracy of heating temperature control. especially when the temperature of the coke oven is low at the initial stage of heating, the impact is more severe.

To obviate at least one of the disadvantages noted above, an embodiment of the present invention provides a positive pressure coke oven heating system and a temperature control method. In the following, specific embodiments presented in the present invention are described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic view of a positive pressure coke oven heating system in an embodiment of the present invention; FIG. 2 is a block diagram of a positive pressure coke oven heating system in an embodiment of the present invention. As shown in FIG. 1 and FIG. 2, the coke oven heating system at positive pressure includes a shut-off valve 1 of the heating gas main gas pipeline, an electric control valve 2 of the heating gas main gas pipeline, a pressure sensor 3 of the heating gas main gas pipeline, a shut-off valve 4 on the heating gas pipeline 4, a heating device 5 at positive pressure and the heating control system 6 at positive pressure.

The heating gas main pipeline is configured to supply gas to the gas outlet pipe, which supplies gas to the heating device 5 at positive pressure during the heating process. In the present implementation of the invention, the heating gas main pipeline is connected to a plurality of gas outlet pipes, and a shut-off valve 4 on the heating gas gas pipe outlet is located on the gas outlet pipe. Each gas outlet is connected to one or more control valves of the gas outlet (see FIG. 3) of one of the positive pressure heating devices 5. The pressure sensor 3 of the heating gas main gas pipeline, the positive pressure heating device 5 and the electric control valve 2 of the heating gas main gas pipeline are electrically connected to the heating gas control system under positive pressure.

In the present implementation of the invention, the electric control valve 2 of the heating gas main gas pipeline is installed upstream of all gas outlet pipes. The pressure sensor 3 of the heating gas main gas pipeline is located upstream of all gas outlet pipes and is located downstream of the electric control valve 2 of the heating gas main gas pipeline. The shut-off valve 1 of the heating gas main gas line is located upstream of the electric control valve 2 of the heating gas main gas line.

The positive pressure heating device 5 may be a known positive pressure heating device. In the present implementation of the invention, the positive pressure heating device 5 includes two burners, a gas supply pipe 51 and an air supply pipe 57, the two burners corresponding to two coking chambers, namely, the first burner 54 and the second burner 55. The gas supply pipe 51 is equipped with a gas shutoff valve 511. One branch of the gas supply pipe 51 is connected to the gas inlet of the first burner 54 by means of the control valve of the first gas outlet 52, and the second branch of the gas supply pipe 51 is connected to the gas inlet of the second burner 55 by means of the control valve 53 of the second gas outlet. The gas lines between the control valve 52 of the first gas outlet and the gas inlet of the first burner 54 and between the control valve of the second gas outlet 53 and the gas inlet of the second burner 55 can be metal hoses, and the other gas lines can be in the form of galvanized pipes.

The air supply pipe 57 is equipped with a blower 56 at the inlet, therefore one branch of the air supply pipe 57 is connected to the air intake of the first burner 54, the other branch of the air supply pipe 57 is connected to the air intake of the second burner 55, and the blower 56 is equipped with a manually adjustable damper (not shown in the drawing) at the inlet blowers. The air supply pipe 57 can be made of PVC hose. The first burner 54 is equipped with a first thermocouple 541 and a first high voltage igniter 542, and the second burner 55 is equipped with a second thermocouple 551 and a second high voltage igniter 552.

The positive pressure heating device 5 further includes a control cabinet 58 and a gas shutoff valve 511, a control valve 52 of the first gas outlet 52, a first thermocouple 541, a first high voltage igniter 542, a control valve 53 of the second gas outlet, a second thermocouple 551, a second igniter 552 high voltage and blower 56, accessing the control cabinet 58 via cables. The control cabinet 58 is electrically connected to the positive pressure heating control system 6.

The gas safety shutoff valve 511 is designed to shut off the gas supply, and the first and second gas control valves (52, 53) regulate the gas flow rate.

The first and second thermocouples (541, 551) are made with the possibility of measuring the flame temperature in the burners, detecting the combustion of the flame by the flame temperature and immediately stopping the gas supply when the flame is extinguished in order to avoid emergencies; and the first and second high voltage igniters (542, 552) are ready for ignition.

A controller in the control cabinet 58 monitors the control signals of the gas shutoff valve 511, blower 56, gas control valves (52, 53), thermocouples (541, 551) and high voltage ignitors (542, 552) to remotely control the device, and each device is equipped with an alarm device (not shown in the drawings). The alarm signal generated by each device in the heating area notifies the heating maintenance personnel exactly in time and prevents the occurrence of emergency situations as much as possible.

The gas can be coal gas or another combustible gas such as natural gas. The gas supply pipe 51 is connected to the gas outlet pipe, and in some embodiments, the gas safety shut-off valve 511 may be absent, there is only a shut-off valve 4 of the heating gas gas outlet on the gas outlet, and the shut-off valve of the heating gas outlet 4 is connected to the control cabinet 58, and it operates in the same way as the gas shutoff valve 511 described above. With regard to the structure and operation of the positive pressure heating device 5, specific reference can be made to one to two positive pressure heating devices shown in Patent Publication No. CN 109439345 A.

In addition, the positive pressure coke oven heating system may further include a temperature sensor and a pressure sensor for measuring the current temperature and current pressure in the coke oven, and the temperature sensor and pressure sensor are electrically connected to the positive pressure heating control system 6.

In this system, the pressure in the heating gas main pipe is taken as a control object, and the opening degree of the electric control valve 2 of the heating gas main pipe is automatically calculated and adjusted in real time according to the deviation between the actual and target pressure and the rate of change of the deviation, thereby ensuring the stability of the heating gas pressure throughout the entire heating process.

The formula for calculating the control value of the degree of opening of the electric control valve of the main pipeline is as follows:

where:

- контрольная величина степени открытия регулирующего клапана в момент времени k;In the formula:

- control value of the degree of opening of the control valve at time k;

- отклонение между фактическим и заданным давлением в момент времени k, при этом фактическое давление измеряется системой, заданное давление устанавливается вручную, и заданное давление должно оставаться неизменным на протяжении всего процесса регулировки;

- the deviation between the actual and the set pressure at time k, while the actual pressure is measured by the system, the set pressure is set manually, and the set pressure must remain unchanged throughout the entire adjustment process;

- пропорциональный коэффициент; и

- proportional factor; and

,

,

- пропорциональные, интегральные и дифференциальные постоянные времени, соответственно.

,

,

- proportional, integral and differential time constants, respectively.

Since the control valves (52, 53) of the gas outlet in the positive pressure heating device 5 have an idle difference, there is always a certain deviation between the actual and the target valve opening, which affects the control accuracy of the heating temperature. To solve this problem, the present invention provides a positive pressure coke oven heating temperature control method applicable to the above-described positive pressure coke oven heating system. FIG. 5 is a schematic view of a positive pressure heating control system in an embodiment of the present invention; FIG. 6 is a block diagram of the temperature control of a positive pressure coke oven heating device in an embodiment of the present invention. As shown in FIG. 5 and FIG. 6, this method of temperature control includes:

(1) setting the pressure of the heating gas main pipe as a control object, automatically calculating and adjusting the opening degree of the electric control valve 2 of the heating gas main pipe in real time in accordance with the deviation between the actual and target pressure and the rate of deviation change, in order to ensure the stability of the heating pressure gas during the entire heating process; as well as

(2) input, when controlling the opening degree of the gas outlet pipe control valve, the feedback value of the degree of opening of the gas outlet pipe control valve to the control system in order to carry out step control, while the coke oven heating temperature control is the main loop, and the control valve opening degree adjustment The flue gas outlet is a secondary circuit that includes the following steps:

Ш1, computer readout of the optimization of the heating process at positive pressure of the planned temperature with increasing temperature for heating in a device that measures the heating temperature of the coke oven and the current temperature and pressure of the coke oven, measured through the OPC gateway.

In particular, the current temperature of the coke oven can be measured with a temperature sensor, and the current pressure of the coke oven can be measured with a pressure sensor.

Ш2, calculation of the permissible degree of opening of each control valve of the gas outlet in the heating system of the coke oven at positive pressure using the method of controlling the optimization of heating at positive pressure.

Specifically, in the present embodiment, a positive pressure heating optimization control method includes: simulating a temperature rise process for heating, controlling Smith's prediction compensation, controlling simulated human intelligence, and controlling temperature shutdown of adjacent combustion chambers, while simulating a temperature rise for heating. heating analyzes the relationship between the temperature of the combustion chamber, the pressure in the gas outlet, the temperatures of the adjacent combustion chambers and the suction force of the secondary smoke channel and determines the functional relationship between the variable temperature in the furnace and the control value of the heating device; Controlling the Smith Estimated Compensation to avoid or reduce the effect of temperature control hysteresis by calculating the estimate; human intelligence simulation control makes appropriate decisions by detecting various features of the temperature deviation, and calculates the control value of the heating device; and the control to turn off the temperature of the adjacent combustion chambers is dynamically adjusting the control value of the heating device in accordance with a change in the temperature of the adjacent combustion chambers, thereby equalizing the temperature in the furnace. For a specific method, reference may also be made to a method for controlling the optimization of heating under positive pressure disclosed in prior art patent publication No. CN 105700383 B.

Ш3, sending, using a computer to optimize the heating process under positive pressure, the value of the allowable degree of opening of each control valve of the gas outlet, calculated for each control valve and reading the feedback regarding the degree of opening of each control valve of the gas outlet.

Ш4, setting the permissible error range of the degree of opening of each control valve of the gas outlet pipe by setting the dead zone and setting the maximum permissible upper adjustment limit.

Ш5, determination, using a computer to optimize the heating process under positive pressure, whether each control valve in the flue gas outlet has been adjusted to the allowable range of the opening degree by comparing the feedback value of the set and the actual degree of opening of each control valve in the flue pipe.

Ш6, adjustment of the control valve of the gas outlet in relation to the permissible range of the degree of opening.

In addition, when controlling the degree of opening of the control valve of the gas outlet pipe, the control of the set degree of opening of the control valve has been added to eliminate the difference in idle speed, which, in particular, includes:

Ш61, when the feedback value of the actual opening degree of the gas outlet pipe control valve is greater than the predetermined opening degree, the predetermined opening degree of the control valve gradually decreases at a certain step length and frequency until the feedback value of the actual valve opening degree changes downward, and the setpoint opening degree is immediately adjusted to the original setpoint before the decrease takes place.

Ш62, when the feedback value of the actual opening degree of the gas outlet pipe control valve is less than the predetermined opening degree, the predetermined opening degree of the control valve gradually increases at a certain step length and frequency until the feedback value of the actual valve opening degree changes upward, and the setpoint opening degree is immediately adjusted to the original setpoint before the increase takes place.

Ш63, when the actual opening degree of the gas valve control valve is adjusted to be within the permissible error range, the current opening degree of the valve is retained and the current adjustment is completed.

The application of the positive pressure coke oven heating technology presented in the present invention can automatically adjust the pressure in the heating gas main pipeline in real time, ensure the gas pressure stability during the entire heating process, and can eliminate the influence caused by the difference in idle speed of the control valves of the gas outlet. positive pressure coke oven heating devices, precise control of heating temperature, improving the accuracy of automatic temperature control of the heating system under positive pressure, and therefore improving the quality of heating.

The above-described embodiments are implemented in accordance with the premise of the technical solutions of the present invention, and detailed embodiments and specific workflows are set forth, but the protection scope of the present invention is not limited to the above-mentioned embodiments. Unless otherwise indicated, the method used in the above embodiments is conventional.

Industrial applicability

The positive pressure coke oven heating system and the temperature control method in the present invention can realize real-time automatic pressure control in the heating gas main pipeline, ensure the gas pressure stability during the entire heating process, and can eliminate the influence caused by the idle speed difference of the gas outlet control valve. positive pressure coke oven heating device, accurately control the heating temperature and improve the accuracy of automatic temperature control of the positive pressure heating system.

Claims (45)

1. A system for heating a coke oven at positive pressure, containing a plurality of gas outlet pipes connected to one main heating gas pipeline, while each gas outlet pipe is connected to one heating device at positive pressure, characterized in that it additionally comprises a pressure sensor of the heating gas main pipeline and an electric control valve of the main pipeline, and the pressure sensor of the heating gas main pipeline and an electric control valve of the main pipeline are electrically connected to the heating control system at positive pressure. 2. The coke oven heating system at positive pressure according to claim 1, in which the electric control valve of the heating gas main pipeline is installed upstream of all gas outlet pipes, and the shut-off valve of the heating gas main pipeline is located upstream of the electric control valve of the heating gas main pipeline gas. 3. The coke oven heating system at positive pressure according to claim 2, in which the pressure sensor of the heating gas main pipeline is installed upstream of all gas outlet pipes and is located downstream of the electric control valve of the heating gas main pipeline. 4. Heating system for a coke oven at positive pressure according to any one of paragraphs. 1-3, in which the positive pressure heating device comprises a first burner, a second burner, a gas supply pipe and an air supply pipe, wherein one branch of the gas supply pipe is connected to the gas inlet of the first burner through a control valve of the first gas outlet, and the other branch of the gas supply pipe is connected to the gas inlet of the second burner via a control valve of the second gas outlet; and the air supply pipe has one branch connected to the air inlet of the first burner, and the other branch is connected to the air inlet of the second burner. 5. A positive pressure coke oven heating system according to claim 4, in which the gas supply pipe is equipped with a gas-protective shut-off valve. 6. The positive pressure coke oven heating system according to claim 4, in which the upstream end of the inlet pipe of the air supply pipe is connected to the blower. 7. The system for heating a coke oven at positive pressure according to claim 4, in which the heating device at positive pressure additionally contains a control cabinet, wherein both the control valve of the first gas outlet and the control valve of the second gas outlet are electrically connected to the control cabinet, and the control cabinet is electrically connected to the heating control system under positive pressure. 8. A positive pressure coke oven heating system according to claim 4, in which the positive pressure heating device additionally contains: a first thermocouple configured to measure the flame temperature of the first burner; a second thermocouple configured to measure the flame temperature of the second burner; a first high voltage igniter configured to ignite the first burner; and a second high voltage igniter configured to ignite the second burner. 9. The positive pressure coke oven heating system according to claim 4, in which the gas lines between the control valve of the first gas outlet and the gas inlet of the first burner, as well as between the control valve of the second gas outlet and the gas inlet of the second burner are metal hoses. 10. Positive pressure coke oven heating system according to claim 4, in which the air supply pipe is a PVC hose. 11. Heating system for a coke oven at positive pressure according to any one of paragraphs. 1-10, in which each gas outlet is equipped with a shut-off valve on the heating gas outlet. 12. Heating system for a coke oven at positive pressure according to any one of paragraphs. 1-11, in which the positive pressure heating control system is configured to: calculating and regulating the degree of opening of the electric control valve of the heating gas main pipeline in accordance with the deviation between the actual and the set pressure in the coke oven, as well as the rate of change of the deviation, in order to ensure the stability of the heating gas pressure during the heating process. 13. A method of temperature control for a heating system of a coke oven at positive pressure according to claim 1, characterized in that the control method comprises the following: (1) setting the pressure of the heating gas main pipe as a control object, automatically calculating and adjusting the opening degree of the electric control valve of the heating gas main pipe in real time in accordance with the deviation between the actual and target pressure and the deviation rate of change, so as to ensure pressure stability heating gas during the entire heating process; and (2) input, when controlling the heating device under positive pressure, the feedback value of the opening degree of each control valve of the gas outlet to the control system to achieve step regulation, while the control of the coke oven heating temperature is realized by the main loop, and the opening degree of each control valve is controlled the gas outlet is realized with a secondary circuit; and adding, when controlling the degree of opening of each control valve of the gas outlet, control of the predetermined degree of opening of each control valve in order to eliminate the difference in idle speed, 1) a gradual decrease in the preset degree of opening of the control valve at a certain step length and frequency, when the feedback value of the actual degree of opening of the control valve of the gas outlet is greater than the preset degree of opening, until the feedback value of the actual degree of opening of the valve changes downward, and immediately adjusting the predetermined degree of its opening to the original predetermined value, before the reduction is performed; 2) a gradual increase in the preset degree of opening of the control valve at a certain step length and frequency, when the feedback value of the actual degree of opening of the control valve of the gas outlet is less than the preset degree of opening, until the feedback value of the actual degree of opening of the valve changes upward, and immediately adjusting the predetermined degree of its opening to the original predetermined value before the increase is performed; 3) maintaining the current valve opening degree when the actual opening degree of the gas outlet pipe control valve is adjusted within the permissible error range, and completing the current adjustment. 14. The method of temperature control for a coke oven heating system at positive pressure according to claim 13, in which the formula for calculating the control value of the degree of opening of the electric control valve of the main pipeline is as follows:

, where

, In the formula:

- control value of the degree of opening of the control valve at time k;

- the deviation between the actual and the set pressure at time k, where the actual pressure is measured by the system, the set pressure is set manually, and the set pressure must remain unchanged throughout the entire adjustment process;

- coefficient of proportionality; and

,

,

- proportional, integral and differential time constants, respectively. 15. The method of temperature control for a coke oven heating system at positive pressure according to claim 13, according to which the input, when controlling the heating device at positive pressure, the feedback value of the degree of opening of each control valve of the gas outlet pipe to the control loop, in order to achieve step regulation, includes : reading by a computer the optimization of the heating process under positive pressure through the OPC gateway of the planned temperature when the temperature for heating increases, as well as the current temperature and pressure in the coke oven, while the planned temperature is in the computer that measures the heating temperature in the coke oven, and the current temperature and the pressure in the coke oven is measured by a computer to measure the heating temperature in the coke oven; calculation of the permissible degree of opening of each control valve of the gas outlet pipe in the heating system of the coke oven at positive pressure using the method for controlling the optimization of heating at positive pressure; sending to each control valve the value of the permissible degree of opening of each control valve of the gas outlet pipe, calculated using a computer to optimize the heating process under positive pressure, and reading feedback on the degree of opening of each control valve of the gas outlet pipe; setting the permissible error range of the degree of opening of each control valve of the gas outlet pipe by setting the dead zone and setting the maximum permissible upper adjustment limit; determining, using a computer to optimize the heating process under positive pressure, whether each control valve of the gas outlet pipe has been adjusted to an acceptable range of the opening degree by comparing the value of the set opening degree and the actual feedback of the degree of opening of each control valve in the gas outlet pipe; and adjustment of each control valve of the gas outlet pipe in the permissible range of the degree of opening. 16. A method for controlling the temperature for a heating system for a coke oven at positive pressure according to claim 15, according to which the method for controlling the optimization of heating at a positive pressure includes: simulate the temperature rise for heating, control the Smith estimate compensation, control simulate human intelligence and control the shutdown of the temperature of adjacent combustion chambers, while simulating the temperature rise for heating analyzes the relationship between combustion chamber temperature, flue gas pressure, temperatures of adjacent combustion chambers, etc. the suction forces of the secondary smoke duct to determine the functional relationship between the variable temperature in the furnace and the reference value of the heating device; Controlling the Smith Estimated Compensation to avoid or reduce the effect of temperature control hysteresis by calculating the estimate; the human intelligence simulation control makes appropriate decisions by detecting various features of the temperature deviation, and calculates the control value of the heating device; and the control to turn off the temperature of the adjacent combustion chambers is dynamically correcting the control value of the heating device in accordance with a change in the temperature of the adjacent combustion chambers, thereby realizing temperature equalization in the furnace.

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