UA113800C2 - METHOD OF DETERMINATION OF THE PARTICULAR COST OF THE CIRCULATING GAS OF INSTALLATION OF DRY COOK EXHAUST AND DEVICES FOR ITS IMPLEMENTATION (OPTIONS) - Google Patents

Abstract

The invention relates to the coke industry and can be used in installations dry coke extinguishing (USGK). A method for determining the specific flow rate of circulating gases of USGK and a device for automatic determination of the specific flow rate of circulating gases (options). In accordance with the present invention measure: the temperature of hot circulating gases in oblique passages behind the extinguishing chamber, before adding them to the air after combustion of fuel components, on the basis of which determine: the amount of heat (Q) transmitted to the circulating gases by one kilogram of hot coke (the amount of hot coke) Q) received from hot coke by one cubic meter of circulating gases under normal conditions, after which make the determination of the specific flow of circulating gases according to the following ratio :, where b is the specific flow of circulating gases of establishments and CDQ nm / kg; Q- amount of heat transmitted by cooled circulating gases with one kilogram of hot coke; Q - amount of heat received from hot coke by one cubic meter of circulating gases under normal conditions. The invention provides an automatic continuous determination of the specific flow rate of circulating gases of USGC.

Description

The invention belongs to the coke industry and can be used in dry coke quenching installations.

Dry coke quenching installations (DCC), including the systems of the Gprokoks Institute (see MoMoeo patents 50217359, 50582674), have been successfully used all over the world for more than 50 years.

At this stage, there are USGKs with two types of means of coke discharge - a means of batch discharge of coke, see MoMo patents 50414286, 50835156, 50904315, 501177331 and means of continuous discharge of coke see MoMoeo patents 501600329, VNO2g388789, VIO2377273, there are also a combined type of batching device with elements (recirculation circuit) of continuous discharge, see MoMmeo patents VO2489472, HO2489471.

At the current stage, at many USGK units, the design value of the specific consumption of circulating gases is in the range of 1.45-1.5 nm3 per kilogram of quenched coke, and the temperature of the circulating gases behind the coke quenching chamber is "800 "С.

One of the main parameters of USGK is the specific consumption of circulating gases (PVG) for coke quenching, nm3/kg. PVG when extinguishing coke is an indicator of the efficiency of the extinguishing chamber and the USGK as a whole. A high value of PVG negatively characterizes the design and mode of operation of the USGK and leads to an increase in electricity consumption for the drive of the duct fan of the circulation system, high dustiness of the circulating gases, intensive wear of the oblique moves of the extinguishing chamber and power equipment and is one of the main reasons for limiting the load

USGK for coke, taking into account the limitations of the duct fan in terms of pressure and productivity.

At today's stage, the actual value of PVG exceeds the design value of PVG.

For example, in the construction of the Giprokoks institute, the operating index of the PVG exceeds the design value by 10-50 95, which leads to a significant deterioration of the performance of the USGK.

According to the known state of the art |1| PVH is periodically determined according to the following ratio:

Vk where

Ve - consumption of circulating gases that pass through the coke layer in the quenching chamber, nm/g;

Vk - output of quenched coke from USGK, kg/g.

According to the known state of the art, the PVG of the USGK block is determined based on test data at

From a fixed load on spent coke In. At the same time, the definition of B; is carried out on the basis of direct measurements of gas flows in the USGK. Various measuring devices are used for direct measurements. The output of quenched coke Vk from the USHK is determined by the amount of coke loaded into the forechamber or by the performance of the coke discharge device from the USHK quenching chamber.

In connection with the episodic and long-term determination of PVG, it becomes difficult to maintain the optimal (minimum possible with this design of the extinguishing chamber and its operating conditions) value of this parameter, which worsens the performance of the USGK. This is observed, for example, when reducing the load of the USGK unit on coke with the preservation or insufficient reduction of the consumption of circulating gases |2Ї1. In this regard, the development of an effective method of continuous determination and control of the PVG value is of great practical importance.

Thus, when determining PVG, according to the known state of the art, experimental data are required on the consumption of circulating gases for quenching coke in the quenching chamber and on the load of the USHK unit on quenched coke, which complicates the process of automatic (continuous) determination of PVH during the operation of the USHK unit.

The task of the invention is to develop a method and a device for continuous automatic determination of the specific flow rate of circulating gases of USGK.

Thus, the installation of dry coke quenching, which contains: a vertically oriented mine, in the upper part of which there is a forechamber, a quenching chamber with a system of oblique moves, which is located under the said forechamber and the lower part of which is made in the form of a cone for discharging coke from the mentioned quenching chamber, a circulation system of gases with a nozzle device located in the lower part of the mentioned quenching chamber, means for discharging coke from the mentioned quenching chamber, which is adjacent to the mentioned lower conical part of the quenching chamber, according to the proposed invention, measure: the temperature of hot circulating gases in oblique passages behind the quenching chamber, to adding air to them for afterburning the fuel components, based on which the following are determined: the amount of heat (Ox) transferred to the circulating gases by one kilogram of hot coke, the amount of heat (02) absorbed from the hot coke by one cubic meter of circulating gases under normal conditions, after which determination of the specific consumption of circulating gases for us to the obtuse ratio:

(g. r--i o where p - specific consumption of circulating gases of the dry coke extinguishing installation nm3/kg; 0: - the amount of heat transferred to the cooled circulating gases by one kilogram of hot coke;

FO" - the amount of heat absorbed from hot coke by one cubic meter of circulating gases under normal conditions. rakozh, according to the invention of As"; and C; determined by the following ratios: 11 11 11 and

O2 (g x C -v) (l -v)

In" more . . . where "77 is the heat capacity of the hot circulating gases behind the extinguishing chamber, before adding air to them for afterburning the fuel components,

A -T x Sk -its x Sk at Tk -1025 C, Tk -200 (0; - 1025 b, Tk1-200 o: tus 1 9 v-Txs at t -1607s

A-330, B-51.4 when using the heat unit "calorie" in calculations;

At1380, B-215 when using the heat unit "joule" in calculations;

Teobk. temperature and heat capacity of hot coke in the lower part of the fore-chamber; 11th year the temperature and heat capacity of the quenched coke after the dutt device along the course of the coke movement; 11 vol. temperature and heat capacity of hot circulating gases at the exit from the extinguishing chamber in oblique passages before air is added to them for heating fuel components; i.e. temperature and heat capacity of circulating gases in front of the extinguishing chamber.

Also, according to the invention, the following are additionally measured: the temperature of the hot coke in the lower part of the forechamber, the temperature of the circulating gases that are fed into the quenching chamber from the mentioned circulation system, the temperature of the quenched coke after the dutt device along the course of the coke movement, on the basis of the mentioned data, CO is determined: according to the following ratios:

O.-tihsi-tho 1 Kk Kk Kk Kk

Fo t x sg -ti ho. that's it! with. what .

Koko - temperature and heat capacity of hot coke in the lower part of the fore-chamber; 11th year

From tob. the temperature and heat capacity of the quenched coke after the dutt device along the course of the coke movement; ts. more . . . goth - temperature and heat capacity of hot circulating gases at the exit from the extinguishing chamber in oblique passages before air is added to them for additional combustion of fuel components; i.e. temperature and heat capacity of circulating gases in front of the extinguishing chamber.

According to the proposed invention, PVG for coke quenching is equal to the ratio of the amount of heat (0), which is transferred by one kilogram of hot coke to the circulating gases in the quenching chamber, to the amount of heat (02) absorbed from the hot coke by one cubic meter of circulating gases under normal conditions.

At the same time, O.O" are defined according to the following ratios:

Ou -lkh Sk -kM xSe O.O and dovk dovk (2) 11 11 1 1

ОО» -Т хг -Х Ор (3) where

Oh - heat from coke smoke;

Ordovk. - heat loss to the environment from the extinguishing chamber;

Theo temperature and heat capacity of hot coke in the lower part of the fore-chamber; 11th year

Tok o. the temperature and heat capacity of the quenched coke after the dutt device along the course of the coke movement;

ts. with. . . . " - the temperature and heat capacity of the hot circulating gases at the exit from the extinguishing chamber in oblique passages before adding air to them for additional combustion of fuel components; i.e. the temperature and heat capacity of the circulating gases in front of the extinguishing chamber.

Since the heat from coke ash (04) is approximately equal to the heat loss to the environment (Odovk), SO In this case, Оу is determined by the following ratio:

Ou -ThxS-Tu x Sk «4)

The analysis shows that when the difference in heat from coke ash (C) and heat loss of the extinguishing chamber to the environment (Odovk) is up to 40 95, the calculation error does not exceed 1.0 95.

Also, according to the invention, the temperature of the quenched coke is measured in the quenching chamber under the nozzle device in the lower conical part of the quenching chamber in the course of the coke movement. This makes it possible to use the proposed invention at USGK with a system of portioned and continuous coke discharge.

The measurement of the temperature of the quenched coke discharged onto the conveyor is unrepresentative due to, for example, additional cooling of the coke by ventilation air during continuous discharge of coke from the quenching chamber. Also, according to the invention, the USGK additionally contains a gas recirculation circuit from the coke discharge means into the mentioned circulation system, while the temperature of the quenched coke is determined by measuring the temperature of the recirculating gases in the mentioned gas recirculation system.

Thus, when determining PVG by this method, data on the consumption of circulating gases for quenching coke and data on the load of the USGK block on quenched coke are not required.

According to the first version of the invention, the device for automatically determining the specific consumption of circulating gases of a dry coke quenching installation contains: at least one sensor of the temperature of hot circulating gases in oblique passages behind the quenching chamber, before air is added to them for additional combustion of fuel components, a block of tabular values of coke heat capacities and gases at different temperatures, the first unit for calculating the amount of heat transferred to circulating gases by one kilogram of hot coke in the quenching chamber (Ox), the second unit for calculating the amount of heat absorbed from coke by one cubic meter of circulating gases under normal conditions (02), while the mentioned the second block is connected at the input with the mentioned hot temperature sensors and the mentioned tabular block

Of the values, the third unit for calculating the specific flow of circulating gases is connected at the input with the mentioned first and second units.

According to the second embodiment of the invention, the device for automatically determining the specific flow of circulating gases of the dry coke quenching installation contains: at least one hot coke temperature sensor located in the lower part of the forechamber, at least one quenched coke temperature sensor located under the nozzle device in the lower conical part of the extinguishing chamber, at least one sensor for the temperature of hot circulating gases in oblique passages behind the extinguishing chamber, before adding air to them for additional combustion of fuel components, at least one sensor for the temperature of the circulating gases cooled in the recovery boiler, which are fed to the dutt device, a block of tabular values of heat capacities coke and gases at different temperatures, the first unit for calculating the amount of heat that is transferred to the circulating gases by one kilogram of hot coke in the quenching chamber (0), while the mentioned first unit is connected at the input with the mentioned hot and quenched coke temperature sensors and the mentioned block m of tabular values, the second block for calculating the amount of heat absorbed from coke by one cubic meter of circulating gases under normal conditions (02), while the mentioned second block is connected at the input with the mentioned temperature sensors of hot and cooled circulating gases and the block of tabular values, the third block for calculating the specific flow of circulating gases, connected at the entrance to the mentioned first and second blocks.

According to another version of the invention, the device for automatically determining the specific consumption of circulating gases of the dry coke quenching installation includes: at least one hot coke temperature sensor located in the lower part of the forechamber, at least one recirculating gas temperature sensor in the mentioned recirculation circuit, at least one temperature sensor of hot circulating gases in oblique passages behind the quenching chamber, before air is added to them for additional combustion of fuel components, at least one temperature sensor of the cooled circulating gases that are fed into the dutt device, a block of tabular values of heat capacities of coke and gases at different temperatures, the first block for calculating the amount of heat , which is transmitted to the circulating gases by one kilogram of hot coke in the quenching chamber (01), while the mentioned first block is connected at the input with the mentioned hot coke and recirculating gas temperature sensors and the mentioned block of table values, the second block for calculating the amount of heat , received from coke by one cubic meter of circulating gases under normal conditions (02), while the mentioned second block is connected at the input with the mentioned temperature sensors of hot and cooled circulating gases and a block of tabular values, the third block for calculating the specific flow of circulating gases is connected at the input with the mentioned first and second blocks.

The first version of the device implementation

According to the first implementation option, the device for automatically determining the specific consumption of circulating gases of the USGK, which contains: at least one hot coke temperature sensor, which is located in the lower part of the forechamber, at least one quenched coke temperature sensor, which is located under the nozzle device in the lower conical part of the quenching chamber, at least one sensor of the temperature of hot circulating gases in oblique passages behind the extinguishing chamber, before adding air to them for additional combustion of fuel components, at least one temperature sensor, cooled in the boiler-utilizer of circulating gases, which is fed to the dutt device, a block of tabular values of heat capacities of coke and gases at different temperatures, the first block for calculating the amount of heat (01), which is transferred to the circulating gases by one kilogram of hot coke in the quenching chamber, while the mentioned first block is connected at the input with the mentioned hot and quenched coke temperature sensors and the mentioned block of table values, the second b block for calculating the amount of heat (02) absorbed from coke by one cubic meter of circulating gases under normal conditions, while the mentioned second block is connected at the input with the mentioned temperature sensors of hot and cold circulating gases and a block of table values, the third block for calculating the specific flow of circulating gases, connected at the entrance with the mentioned first and second blocks.

Based on the data received from the above-mentioned sensors, the device performs the following actions: - based on the temperatures of hot and quenched coke and data from the block of table values of heat capacities, the first block calculates the amount of heat that is transferred by one kilogram of hot coke to the circulating gases in the quenching chamber, - CO; - on the basis of the temperature of hot circulating gases in oblique passages behind the quenching chamber, the temperature of cooled circulating gases in front of the quenching chamber and the given block of tabular heat capacities, the second block calculates the amount of heat absorbed from hot coke by one cubic meter of circulating gases under normal conditions, - О2;

Зо - based on the values of С and О2, the third unit calculates the specific consumption of circulating gases for coke quenching (B) according to the ratio: о

Thus, according to the proposed invention, when determining PVG, data on the consumption of circulating gases for the actual quenching of coke and on the load of the USGK block on quenched coke is not required, which simplifies and increases the accuracy of determination of PVG and ensures its continuous automatic determination.

To increase the accuracy of measuring the temperature of hot coke in the lower part of the fore-chamber, it is necessary to measure the temperatures of the coke at several points along the perimeter of the lower part of the fore-chamber with subsequent averaging.

The temperature of the hot circulating gases behind the extinguishing chamber should be measured in oblique strokes - before the addition of cold air, which changes the value of this temperature. In connection with the uneven distribution of hot circulating gases along oblique passages, the temperature of the gases in them has different values. As a result, it is necessary to measure the temperature of the gases at several points along the perimeter of the extinguishing chamber in oblique strokes.

A fairly accurate determination of the average temperature of the quenched coke under the nozzle device in the quenching chamber during its continuous or combined discharge of the USHK, in which the recirculation circuit is used, is provided by the measurement of the temperature of the recirculating gases in the recirculation circuit, which shows the average temperature of the coke in the lower conical part of the quenching chamber. 5О The second version of the device implementation

According to the second embodiment of the invention, the device for automatically determining the specific consumption of circulating gases of the dry coke quenching installation includes: at least one hot coke temperature sensor located in the lower part of the forechamber, at least one recirculating gas temperature sensor in the mentioned recirculation circuit, at least one temperature sensor of hot circulating gases in oblique passages behind the quenching chamber, before adding air to them for afterburning fuel components, at least one sensor of the temperature of circulating gases that are fed into the quenching chamber from the circulation system, a block of tabular values of heat capacities of coke and gases at different temperatures, the first calculation block of the amount of heat that is transferred to the circulating gases by one kilogram of hot coke in the quenching chamber (O:), while the mentioned first unit is connected at the input with the mentioned sensors of the temperature of the hot coke and recirculating gases and the mentioned unit of table values, the second unit for calculating the amount heat absorbed from coke by one cubic meter of circulating gases under normal conditions (02), while the mentioned second block is connected at the input with the mentioned temperature sensors of hot and cooled circulating gases and a block of table values, the third block for calculating the specific flow of circulating gases, connected at the input with mentioned first and second blocks.

Based on the data received from the above-mentioned sensors, the device performs the following actions: - the amount of heat transferred by one kilogram of hot coke to the circulating gases is calculated based on the temperature of the hot coke and the temperature of the recirculating gases in the recirculation circuit (equal to the temperature of the quenched coke) and the data from the block of tabular values of heat capacities in the quenching chamber, - C; - the amount of heat absorbed from hot coke by one cubic meter of circulating gases under normal conditions is calculated from the temperature of hot circulating gases in the oblique passages behind the quenching chamber, the temperature of cooled circulating gases in front of the quenching chamber and the data of the block of tabular heat capacities, - О2; - the specific consumption of circulating gases for coke quenching (B) is calculated as the ratio C: to

AT".

Figures

Narrow terminology is used when considering variants of the invention. However, the invention is not limited by the accepted terms and it should be understood that each such term covers all equivalent elements that operate in a similar manner and are used to solve the same problems.

Fig. 1 - the USGK is depicted, according to the first version of the invention.

Fig. 2 - shows the USGK, according to the second embodiment of the invention, which contains a recirculation circuit.

Fig. C - the device for automatic determination of the specific flow rate of circulating gases is depicted

USGK

Fig. 4 - the dependence of the temperature of the circulating gases in the oblique passages of the extinguishing chamber is shown

From the coke from the specific consumption of gases.

Fig. 5 - shows the USGK, according to the third embodiment of the invention, which contains a recirculation circuit.

Fig. 6 - the device for automatic determination of the specific consumption of circulating gases is depicted

USGK, shown in fig. 5.

In Fig. 1 shows the USGK, which contains a vertically oriented mine, in the upper part of which there is a fore-chamber 1, an extinguishing chamber 2 with a system of oblique passages Z, located under the fore-chamber 1. A circulation system of 4 gases in the extinguishing chamber 2, which contains a hopper, a dust collector 5, a recovery boiler 6, cyclones 7, exhaust fan 8, candle 9U for discharging the excessive volume of gases and exhaust device 10, located in the lower part of the extinguishing chamber 2. The system for unloading 11 of coke from the extinguishing chamber 2 is also adjacent to the lower part of the extinguishing chamber 2.

In Fig. 1 also shows sensors: 12 - temperature of hot coke; 15 - temperature of cold coke; 13 - temperatures of hot circulating gases, in oblique passages 3; 14 - temperature of cooled circulating gases.

In Fig. 2 shows the USGK, according to the second embodiment of the invention, which additionally includes a recirculation circuit 20.

At the same time, the temperature of the quenched coke after the nozzle device 10 in the course of the coke movement is determined by measuring the temperature of the recirculating gases in the recirculation circuit 20 using the sensor 21.

In Fig. A schematic diagram of the device for automatically determining the specific consumption of circulating gases of the USGK is shown according to the first (Fig. 1) and second (Fig. 2) versions of the device.

The device for automatic determination of the specific consumption of circulating gases of the USGK, according to the first version of implementation, which is shown in Fig. 1 and Fig. 3, and contains: 12 - hot coke temperature sensor; 15 - cold coke temperature sensor; 13 - temperature sensor of hot circulating gases; 14 - temperature sensor of cooled circulating gases; because 16 - a block of tabular values of heat capacities of coke and gases at different temperatures;

17 - the first unit for calculating the amount of heat (01), which is transferred to the circulating gases by one kilogram of hot coke in the quenching chamber 2. At the same time, the first unit 17 is connected at the input to the temperature sensors of hot 12 and quenched 15 coke and unit 16 of table values; 18 - the second unit for calculating the amount of heat (02) absorbed from coke by one cubic meter of circulating gases under normal conditions. At the same time, the second block 18 is connected at the input with temperature sensors of hot 13 and cooled circulating gases 14 and block 16 of table values; 19 - the third unit for calculating the specific consumption of circulating gases, connected at the input to the first 17 and second 18 units.

The device for automatic determination of the specific consumption of the USGK, according to the second variant of implementation, shown in Fig. 2 and Fig. 3, contains: 12 - hot coke temperature sensor; 21 - temperature sensor of recirculating gases in the recirculation circuit 20; 13 - temperature sensor of hot circulating gases; 14 - temperature sensor of cooled circulating gases; 16 - block of table values; 17 - the first unit for calculating the amount of heat that is transferred to the circulating gases by one kilogram of hot coke in the quenching chamber (0). At the same time, the first block 17 is connected at the input with hot coke temperature sensors 12 and recirculating gas temperature sensor 21 and block 16 of table values; 18 - the second unit for calculating the amount of heat (02) absorbed from coke by one cubic meter of circulating gases under normal conditions. At the same time, the second block 18 is connected at the input with temperature sensors of hot 13 and cooled circulating gases 14 and block 16 of table values; 19 - the third unit for calculating the specific consumption of circulating gases, connected at the entrance to the first 17 and second 18 units.

The first version of the invention

During the operation of the USGK, shown in Fig. 1, hot coke is loaded into

From the forechamber 1, which moves from the forechamber 1 to the quenching chamber 2 as a result of coke discharge through the coke discharge means 11, which is adjacent to the lower conical part of the quenching chamber 2. In the lower part of the forechamber 1, hot coke temperature sensors 12 are installed around the entire perimeter, which connected to the entrance of the first block 17.

Through the nozzle device 10, the cooled circulating gases enter the lower part of the quenching chamber 2. In the quenching chamber 2, the circulating gases move countercurrently to the hot coke, which provides effective heat exchange, as a result of which the hot coke gives its heat to the circulating gases. The circulating gases heated in the extinguishing chamber 2 are removed from it through the system of oblique passages Z, which is located in the upper part of the extinguishing chamber 2. With the help of sensors 13, the temperature of the hot circulating gases in the oblique passages Z behind the extinguishing chamber 2 is determined, while the sensors 13 are connected with the entrance of the second block 18.

From the extinguishing chamber 2, through oblique passages 3, hot circulating gases are diverted to the dust collector hopper 5, where they are dedusted. From the bunker 5, the hot circulating gases are diverted to the recovery boiler 6, in which the cooling of the hot circulating gases takes place. Cooled circulating gases from the boiler-utilizer 6 are diverted to cyclones 7, in which fine dedusting of the circulating gases takes place. After cyclones 7, the circulating gases are diverted through the nozzle device 10 to the extinguishing chamber 4. At the entrance of the cooled circulating gases to the nozzle device 10, a sensor 14 of the temperature of the cooled circulating gases is installed, which is connected to the input of the second unit 18.

The movement of circulating gases is ensured by means of a duct fan 8, and the excess volume of circulating gases, which was formed in the circulation system 4 as a result of air suction, is removed through the candle 9.

In the process of discharging coke from the quenching chamber 2 through the means of discharging coke 11, which is adjacent to the lower conical part of the quenching chamber 2, there are cold coke temperature sensors 15, which are connected to the input of the first block 17.

On the basis of the data received from sensors 12, 13, 14 and 15, the following actions are performed: - based on the temperature of hot and quenched coke and the data of the block of table values 16, the first block 17 determines the amount of heat (Ox), which is transferred by one kilogram of hot coke to the circulating gases in the extinguishing chamber 2. The obtained data of C values: from the first block 17 are transmitted to the third block 19;

- the amount of heat (O2) absorbed from hot coke by one cubic meter of circulating gases under normal conditions is determined by the temperature of hot circulating gases in oblique passages Z behind the quenching chamber 2, the temperature of circulating gases in front of the quenching chamber 2 and the data of the block of table values 16 of heat capacities by the calculation block 18 . The received value data from the second block 18 is transferred to the third block 19; - on the basis of CO and O2 values, the third block 19 calculates the specific consumption of circulating gases for coke quenching (B), as the ratio of C: to O", - the received specific consumption data (B) is transmitted to the USGK control panel (not shown in the figures) .

The second variant of the implementation of the invention

During the operation of the USGK, shown in Fig. 2, hot coke is loaded into the fore-chamber 1, in the lower part of which sensors 12 of hot coke temperatures are installed around the entire perimeter, which are connected to the entrance of the first block 17.

Through the duct device 10, the circulating gases cooled in the recovery boiler 6 enter the lower part of the quenching chamber 2. In the quenching chamber 2, the circulating gases move countercurrently to the hot coke, which ensures effective heat exchange, as a result of which the hot coke gives its heat to the circulating gases. The hot circulating gases heated in the extinguishing chamber 2 are removed from it through the system of oblique passages Z, which is located in the upper part of the extinguishing chamber 2. With the help of sensors 13, the temperature of the hot circulating gases in the oblique passages C behind the extinguishing chamber 2 is determined, while the sensors 13 connected to the entrance of the second block 18.

The recirculation circuit 20 adjoins the coke discharge means 11, while part of the circulating gases from the quenching chamber 2 is diverted to the discharge means 11, from which they are discharged through the recirculation circuit 20 in the form of recirculating gases. In the recirculation circuit 20, a recirculating gas temperature sensor 21 is installed, which is connected to the input of the first block 17.

Based on the data received from the sensors 12, 13, 14 and 21, the following actions are performed: - according to the temperature of the hot coke and the temperature of the recirculating gases (equal to the temperature of the quenched coke) and the data of the block of table values 16 of heat capacities, the first block 17 determines the amount of heat (0) , which is transmitted by one kilogram of hot coke

With circulating gases in the extinguishing chamber 2. The obtained data of C values: from the first block 17 are transmitted to the third block 19; - based on the temperature of the hot circulating gases in the oblique passages Z behind the quenching chamber 2, the temperature of the circulating gases in front of the quenching chamber 2 and the data of the table values block 16, the calculation block 18 determines the amount of heat (02) absorbed from the hot coke by one cubic meter of circulating gases (under normal conditions ). The received data of the values of Sg from the second block 18 are transferred to the third block 19; - on the basis of CO and O2 values, the third block 19 calculates the specific consumption of circulating gases for coke quenching (B), as the ratio of C: to O", - the received specific consumption data (B) is transmitted to the USGK control panel (not shown in the figures) .

In Fig. 4 shows the dependences of the temperature of hot circulating gases in the oblique passages of the coke quenching chamber from PVC, built according to the proposed invention, for hot coke with a temperature from 950 to 1050 "C with an interval of 25 "C (graph 1-1050 "C; graph 2- 1025 C; graph 3-1000 "C; graph 4-975 "C; graph 5-950 "C) at the following average values of other parameters of USGK: - quenched coke temperature -200 "C; - coke ash content -10,905; - temperature cooled circulating gases in front of the extinguishing chamber -160 "С; - calculated composition of circulating gases 90: 2О2-10.0, СбО0-12.0, На-4.5, 02-0.5, M2-73.

The main parameter determining PVG is the temperature of the circulating gases in the oblique passages 3. The temperature of the hot coke has less influence.

When the hot coke temperature deviates from the average calculated value of 1000 C (graph 4 in Fig. 4) within 50 "C, the calculation error does not exceed 23.9 95. When the temperature of the cooled circulating gases in front of the extinguishing chamber C deviates within 52570, the calculation error does not exceed 0.2 95. When the temperature of the quenched coke deviates within 25 "С, the calculation error does not exceed 0.2 95. The influence of the deviation of the ash content within 2 У5, as well as changes in the composition of circulating gases in the working range slightly affects the accuracy of the calculations.

In literary sources, the temperature of hot coke is in the range of 1000-1050 "C, because the relationship between the temperature of hot circulating gases behind the quenching chamber and PVG at an average temperature of hot coke of 1025 "C is of practical interest. As a result, PVG is determined according to the following ratio:

In more . where "7 is the heat capacity of the hot circulating gases behind the extinguishing chamber, before adding air to them for afterburning the fuel components,

A-Thsk-TK hOk at T-10257C,7, -200 0. 1025 C, Tk1-200 2 in-thix at t. -160"s

A-330, B-51.4 when using the heat unit "calorie" in calculations;

A-1380, B-215 when using the "joule" heat unit in calculations;

When the hot coke temperature deviates from the average calculated value of 102570 (graph 2 in Fig. 4) within 25 "C, the accuracy of the calculations does not exceed "51.9 95 with the above-mentioned deviations of the parameters: the temperature of the cooled circulating gases in front of the quenching chamber, the temperature of the quenched coke and ash content .

Taking into account the above relationship (5) and the constructed graphical dependence - Fig. 4, line 2 - have a universal character and can be effectively used as a tool for the analysis of existing structures and modes of operation of USGK, which are being developed.

To implement automatic control of PVG using ratio 5, it is necessary to measure only the temperature of circulating gases in oblique passages From the extinguishing chamber 2 see Fig. 5.

At the same time, the device for automatic detection of PVG, see Fig. 6 contains: 13 - temperature sensor of hot circulating gases; 16 - block of table values; 17 - the first unit for calculating the amount of heat (0), in which for CO: the index A is set by default. 18 - the second unit for calculating the amount of heat (02) received from coke by one cubic meter of circulating re under normal conditions. At the same time, 02 is determined by the following ratio in -B; 19 - the third unit for calculating the specific consumption of circulating gases, connected at the entrance to the first 17 and second 18 units.

Thus, the use of the proposed invention provides automatic

From continuous determination of PVG.

It is clear that the proposed invention is not limited to the examples presented above.

So, for example, it is obvious that in order to increase the reliability and accuracy of the determination of PVG, a variant of the invention is possible, according to which the temperature of the quenched coke in the lower conical part of the quenching chamber is simultaneously measured and the temperature of the recirculating gases in the recirculation circuit is measured. At the same time, the device for automatic determination of the specific consumption of circulating gases of the USGK contains: 12 - hot coke temperature sensor; 13 - temperature sensor of hot circulating gases; 14 - temperature sensor of cooled circulating gases; 15 - cold coke temperature sensor; 21 - temperature sensor of recirculating gases in the recirculation circuit 20; 16 - block of table values; 17 - the first block for calculating the amount of heat (01), which is transferred to the circulating gases by one kilogram of hot coke in the quenching chamber 2, while the first block 17 is connected at the input to the temperature sensors of hot 12 and cold 15 coke, sensor 21 of the temperature of recirculating gases and a block of tabular values 16. The first unit 17 on the basis of these sensors 12 and 21 determines the temperature of hot coke, while in case of a strong discrepancy of these sensors 121121, it is possible to easily establish their breakdown, which is also an advantage of the proposed invention; 18 - the second block for calculating the amount of heat (02) absorbed from coke by one cubic meter of circulating gases under normal conditions, while the second block 18 is connected at the input to the temperature sensors of hot 13 and cooled 14 circulating gases and the block of table values 16; 19 - the third unit for calculating the specific consumption of circulating gases, connected at the entrance to the first 17 and second 18 units.

Technical result

The technical result of the proposed invention is the automatic continuous determination of the specific consumption of circulating gases of the USGK.

Sources of information: 1. Teplytskyi M.G., Gordon I.3. etc.

Dry quenching of coke M.: Metallurgy, 1971, p. 139. 2. Kucheryava V.S., Menyakina V.S., Tolmakova V.A.

Increasing the efficiency of USGK. // Coke and chemistry. 1986. Mo. 2. P. 55-56.

Claims (1)

FORMULA OF THE INVENTION 1. The method of determining the specific consumption of circulating gases of a dry coke extinguishing installation, which contains: a vertically oriented mine, in the upper part of which there is a fore-chamber, an extinguishing chamber with a system of oblique moves, which is located under the mentioned fore-chamber and the lower part of which is made in the form of a cone for discharging coke from the mentioned quenching chamber, a gas circulation system with a nozzle device located in the lower part of the said quenching chamber, a means of discharging coke from the said quenching chamber, which is adjacent to the said lower conical part of the quenching chamber, which differs in that, according to the mentioned method, it is measured: the temperature of the hot circulating gases in the oblique passages behind the quenching chamber, before adding air to them for afterburning the fuel components, on the basis of which the following are determined: the amount of heat (01) transferred to the circulating gases by one kilogram of hot coke, the amount of heat (02) absorbed from the hot coke one cubic meter of circulating gases under normal conditions, after which they determine the specific consumption of circulating gases according to the following ratio: C where B - specific consumption of circulating gases of the dry coke quenching installation, nmz/kg; From OS: - the amount of heat transferred to the cooled circulating gases by one kilogram of hot coke; FO" - the amount of heat absorbed from hot coke by one cubic meter of circulating gases under normal conditions. g Sivfsib according to p.A, in which Cx and C" are determined by the following ratios: ЗБ b" (хихсий-в) PV and that g is the heat capacity of hot circulating gases behind the extinguishing chamber, before adding air to them for afterburning fuel components, . , A-Trh b-r x Sk at t-10257С, t-20070 tov 1 zdpo ! to 00В-ТХС pru TO -1607С A-330, B-51.4 when using the heat unit "calorie" in calculations; At1380, B-215 when using the heat unit "joule" in calculations; i.e. temperature and heat capacity of hot coke in the lower part of the fore-chamber; 11 1 vol. the temperature and heat capacity of the quenched coke after the dutt device along the course of the coke movement; te" and 2, and and and pogo - the temperature and heat capacity of hot circulating gases at the exit from the extinguishing chamber in oblique passages before air is added to them for additional combustion of fuel components; i.e. temperature and heat capacity of circulating gases in front of the extinguishing chamber. 3. The method according to claim 1, in which the following are additionally measured: the temperature of the hot coke in the lower part of the fore-chamber, the temperature of the circulating gases that are supplied to the quenching chamber from the mentioned circulation system, the temperature of the quenched coke after the dutt device along the coke movement, on the basis of the mentioned data, it is determined СО: and О» according to the following ratios: Су -хСк-Тх Ок Oo SHICH -ti ho! that's it! still Mr. and the temperature and heat capacity of hot coke in the lower part of the fore-chamber; i.e. temperature and heat capacity of the quenched coke after the dutt device along the course of 9 Koru; at. goth - temperature and heat capacity of hot circulating gases at the exit from the extinguishing chamber in oblique passages before air is added to them for additional combustion of fuel components; then. temperature and heat capacity of circulating gases in front of the extinguishing chamber. 4. The method according to point 3, in which the temperature of the quenched coke is measured in the quenching chamber under the nozzle device in the lower conical part of the quenching chamber along the course of the coke movement. 5. The method according to claim 3, in which the dry coke quenching installation additionally includes a gas recirculation circuit from the coke discharge means into the mentioned circulation system, while the temperature of the quenched coke is determined by measuring the temperature of the recirculating gases in the mentioned gas recirculation circuit. 6. A device for automatically determining the specific flow of circulating gases of a dry coke quenching installation, according to the method described in claim 2, which is characterized by the fact that it contains: at least one sensor of the temperature of hot circulating gases in oblique passages behind the quenching chamber, before adding air to them for the afterburning of fuel components, a block of tabular values of the heat capacities of coke and gases at different temperatures, the first block of calculating the amount of heat transferred to the circulating gases by one kilogram of hot coke in the quenching chamber (C), the second block of calculating the amount of heat absorbed from the coke by one cubic meter of circulating gases by normal conditions (02), while the mentioned second block is connected at the input with the mentioned sensors of the temperature of hot circulating gases and the mentioned block of table values, the third block for calculating the specific flow of circulating gases is connected at the input with the mentioned first and second blocks. 7. A device for automatically determining the specific flow rate of circulating gases of a dry coke quenching installation, according to the method described in claim 3, which is characterized by the fact that it contains: at least one hot coke temperature sensor located in the lower part of the fore-chamber, at least one extinguished temperature sensor of coke, which is located under the nozzle device in the lower conical part of the extinguishing chamber, at least one sensor of the temperature of hot circulating gases in oblique passages behind the extinguishing chamber, before adding air to them for additional combustion of fuel components, at least one sensor of the temperature of the cooled circulating gases in the boiler-utilizer, which are fed into the dutte device, a block of tabular values of heat capacities of coke and gases at different temperatures, a first block for calculating the amount of heat transferred to the circulating gases by one kilogram of hot coke in the quenching chamber (01), while the mentioned first block is connected at the input with the mentioned sensors of the temperature of the hot and of extinguished coke and the mentioned block of table values, the second block for calculating the amount of heat absorbed from coke by one cubic meter of circulating gases under normal conditions (02), while the mentioned second block is connected at the input with the mentioned temperature sensors of hot and cooled circulating gases and the block of table values, the third unit for calculating the specific flow of circulating gases, connected at the input with the mentioned first and second units. 8. A device for automatically determining the specific flow of circulating gases of a dry coke quenching installation, according to the method characterized by claim 5, which is characterized by the fact that it contains: at least one hot coke temperature sensor, which is located in the lower part of the prechamber, at least one recirculating temperature sensor gases in the mentioned recirculation circuit, at least one sensor of the temperature of hot circulating gases in oblique passages behind the extinguishing chamber, before adding air to them for additional combustion of fuel components, at least one sensor of the temperature of the cooled circulating gases that are fed to the dutt device, a block of tabular values of heat capacities of coke and gases at different temperatures, the first block for calculating the amount of heat transferred to the circulating gases by one kilogram of hot coke in the quenching chamber (01), while the mentioned first block connected at the input with the mentioned sensors of the temperature of hot coke and recirculating gases and the mentioned block of tabular values, the second block for calculating the amount of heat absorbed from the coke by one cubic meter of circulating gases under normal conditions (02), while the said second block is connected at the input with the mentioned temperature sensors of hot and cooled circulating gases and a block of tabular values, the third block for calculating the specific flow of circulating gases, connected at the input with the mentioned first and second blocks. 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