CN107894291A - The device of temperature in a kind of measurement ignition furnace - Google Patents

Abstract

The invention provides a device for measuring the temperature in an ignition furnace, comprising: the stabilizing part is provided with a plurality of slots, and the plurality of slots are evenly distributed on the stabilizing part; a plurality of temperature measuring parts, the One end of the plurality of temperature measuring components is respectively connected to the slot; the temperature tracker is connected to the other end of the temperature measuring component through a data transmission line, and the temperature tracker is used to collect samples according to the predicted sampling times and sampling frequency. A plurality of sets of temperature data of a plurality of temperature measuring components; thus, the device is placed horizontally at the entrance of the ignition furnace, and since the stable component is evenly provided with a plurality of slots, after the sintering machine is started, the device follows the sintering machine Moving to the inside of the ignition furnace, each temperature measuring component is directly close to the surface of the sintering material. During the temperature measurement process, as the sintering machine moves in the furnace, the actual temperature data on the surface of the sintering material can be continuously measured, so it can truly reflect the temperature in the ignition furnace. The ignition state can accurately judge the ignition quality of the ignition furnace.

Description

A device for measuring the temperature in an ignition furnace

technical field

The invention belongs to the technical field of sintering, in particular to a device for measuring the temperature in an ignition furnace.

Background technique

The ignition process is the initial link of the entire iron ore sintering process. When the sintered material layer passes through the ignition furnace, the solid fuel on the surface of the material layer is ignited to provide heat for the subsequent continuous sintering. Therefore, the quality of the ignition effect is not only It affects the ore-forming quality of sinter ore, and also has a direct impact on the gas consumption of the ignition process.

At present, the process monitoring of sintering ignition mainly relies on 2-6 thermocouples arranged in the ignition furnace to conduct online detection of the temperature values of several main points in the ignition furnace. However, because the temperature field in the ignition furnace is not evenly distributed, the discretely distributed temperature measurement points above cannot fully reflect the ignition state in the ignition furnace, and furthermore cannot truly reflect the heated state of the sintered material surface.

Contents of the invention

Aiming at the problems existing in the prior art, the embodiment of the present invention provides a device for measuring the temperature in the ignition furnace, which is used to solve the problems caused by the temperature field set in the ignition furnace in the prior art when monitoring the ignition state in the ignition furnace. It is not evenly distributed, which leads to the technical problem that the monitoring data cannot truly reflect the ignition state, and thus the actual temperature of the sintered material surface cannot be determined.

An embodiment of the present invention provides a device for measuring the temperature in an ignition furnace, the device comprising:

a stabilizing component, the stabilizing component is provided with a plurality of slots, and the plurality of slots are evenly distributed on the stabilizing component;

A plurality of temperature measuring components, one end of the plurality of temperature measuring components is respectively connected to the slot;

A temperature tracker is connected to the other end of the temperature measurement component through a data transmission line, and the temperature tracker is used to collect multiple sets of temperature data of multiple temperature measurement components according to the predicted sampling times and sampling frequency.

In the above solution, the device further includes: a balance pressing block installed above the slot, and a groove is arranged on the balance pressing block.

In the above solution, a temperature measuring hole is also arranged on the balance pressing block.

In the above solution, the measuring point of the temperature measuring component is on one side of the temperature measuring hole.

In the above solution, the transmission wire is further covered with a thermal insulation sleeve.

In the above solution, the stabilizing component includes: a stabilizing bar.

In the above solution, the temperature measuring component includes: a thermocouple.

In the above solution, the device further includes: an industrial computer, the industrial computer is connected to the temperature tracker through a wireless network or a transmission wire, and the industrial computer is used to receive the temperature data sent by the temperature tracker .

In the above solution, the temperature data includes: the start time of sampling, the total number of sampling points and the position of the temperature measuring component.

In the above solution, the temperature tracker is in the furnace for 10-11 hours at 1300°C.

The invention provides a device for measuring the temperature in the ignition furnace, which is applied in the ignition furnace, and the device includes: a stabilizing part, and a plurality of slots are arranged on the stabilizing part, and the plurality of slots are evenly distributed On the stable component; a plurality of temperature measuring components, one end of the multiple temperature measuring components is respectively connected to the slot; a temperature tracker is connected to the other end of the temperature measuring component through a data transmission line, the The temperature tracker is used to collect multiple sets of temperature data of a plurality of temperature measuring components according to the predicted sampling times and sampling frequency; thus, the device is horizontally placed at the entrance of the ignition furnace, since multiple Slot, after the sintering machine is started, the device moves to the inside of the ignition furnace with the sintering machine, and each temperature measuring part is directly close to the surface of the sintering material. During the temperature measurement process, as the sintering machine moves in the furnace, the sintering material can be continuously measured The actual temperature data on the surface, so it can truly reflect the ignition state in the ignition furnace, and then can accurately judge the ignition quality of the ignition furnace.

Description of drawings

Fig. 1 is a schematic structural diagram of a device for measuring the temperature in an ignition furnace provided by Embodiment 1 of the present invention.

Detailed ways

In order to solve the technical problem of monitoring the ignition state in the ignition furnace in the prior art, because the temperature field set in the ignition furnace is not evenly distributed, the monitoring data cannot truly reflect the ignition state, and the actual temperature of the sintered material surface cannot be determined. , the present invention provides a device for measuring the temperature in the ignition furnace, which is applied in the ignition furnace, and the device includes: a stabilizing part, a plurality of slots are arranged on the stabilizing part, and the plurality of slots are uniform Distributed on the stable component; a plurality of temperature measuring components, one end of the multiple temperature measuring components is respectively connected to the slot; a temperature tracker is connected to the other end of the temperature measuring component through a data transmission line, and the The temperature tracker is used to collect multiple sets of temperature data of multiple temperature measuring components according to the predicted sampling times and sampling frequency.

The technical solution of the present invention will be further described in detail below with reference to the drawings and specific embodiments.

Embodiment one

This embodiment provides a device for measuring the temperature in the ignition furnace, which is applied in the ignition furnace. As shown in Figure 1, the device includes: a stabilizing component 1, a slot 2, a temperature measuring component 3, and a temperature tracker 4 ;

The stabilizing component 1 is provided with a plurality of slots 2, and the plurality of slots 2 are evenly distributed on the stabilizing component 1; the stabilizing component 1 can be a stabilizing bar, and the material of the stabilizing bar can include resistant High temperature stainless steel. The slot 2 is used for placing the temperature measuring component 3 . The number of slots 2 can be set according to actual production requirements.

One ends of the plurality of temperature measuring components 3 are respectively connected to the sockets 2; the temperature measuring components 3 may include thermocouples. The temperature measuring component 3 includes: a thermocouple body 5, a measuring point 6 and a data transmission line 7; wherein,

The thermocouple body 5 is inserted into the slot 2, and the number of the thermocouple body 5 can be set according to actual production requirements.

The temperature tracker 4 is connected to the other end of the temperature measuring component 3 through the data transmission line 7, and the temperature tracker 4 is used to collect multiple sets of temperature data of a plurality of the temperature measuring components 3 according to the predicted sampling times and sampling frequency ; The temperature data includes: the start time of sampling, the total number of sampling points and the position of each temperature measuring component 3 . The sampling frequency can be set according to actual production requirements, generally 10-15s.

Here, the data transmission line 7 is also provided with a thermal insulation sleeve 8 to prevent the data transmission line 7 from being damaged by high temperature.

The temperature tracker 4 can be called a high-temperature black box, and the temperature tracker 4 is in the furnace for 10-11 hours at 1300°C.

The device also includes: a balance pressing block 9, which is installed above the slot 2, and a groove 10 is arranged on the balance pressing block 9, and the groove is used to fix the thermocouple One end of body 5. The balance pressure block 9 is also provided with a temperature measuring hole 11 . The measuring point of the temperature measuring component 3 is on the side of the temperature measuring hole 11, so as to ensure that the thermocouple body 5 is not blown away by the turbulent air flow in the ignition furnace during the measurement process, and at the same time ensure that the thermocouple measuring point 6 can obtain the ignition furnace The actual temperature data inside.

In practical application, place the device horizontally at the entrance of the sintering ignition furnace, cover each slot 2 with a balance pressing block 9, ensure that the thermocouple body 5 is placed in the groove 10 of the balance pressing block 9, and the thermocouple measuring point 6 below the Japanese temperature measuring hole 11. Start the sintering machine, the device enters the ignition furnace entrance along with the sintering material surface, and record the time at this time as t1, and then collect the temperature data of each temperature measuring component 3 according to the preset sampling frequency and sampling times until the device moves out of the ignition furnace, The time at this time is recorded as t2; finally, the temperature curves of the sintered material surface within the time period from t1 to t2 are derived. Here, during the temperature measurement process, each temperature measuring component 3 is directly close to the surface of the sintered material, and the actual temperature data on the surface of the sintered material can be continuously measured. Therefore, the temperature curve can truly reflect the ignition state in the ignition furnace, and thus can accurately judge the ignition furnace. The ignition quality; then the temperature curve can be used as the basis for judging the ignition quality of the ignition furnace, and then the ignition parameters can be adjusted according to the temperature curve.

Here, the device further includes an industrial computer, which is connected to the temperature tracker 4 by means of a wireless network or a transmission wire, and the industrial computer is used to receive the temperature data sent by the temperature tracker 4 . When the industrial computer and the temperature tracker 4 use a wireless network for data transmission, the temperature tracker 4 is provided with a wireless bridging terminal inside. After the temperature curve is transmitted to the industrial computer, the operator can use the industrial computer to print the temperature curve.

Embodiment two

In practical applications, according to the device provided in Embodiment 1, when measuring the temperature in a certain ignition furnace, the details are as follows:

As shown in Figure 1, the device includes: a stabilizing component 1, a slot 2, a temperature measuring component 3, and a temperature tracker 4;

The stabilizing component 1 is provided with a plurality of slots 2, and the plurality of slots 2 are evenly distributed on the stabilizing component 1; the stabilizing component 1 can be a stabilizing bar, and the material of the stabilizing bar can include resistant High temperature stainless steel. The slot 2 is used for placing the temperature measuring component 3 . The number of slots 2 can be set according to actual production requirements. The number of slots 2 in this embodiment includes five.

One ends of the plurality of temperature measuring components 3 are respectively connected to the sockets 2; the temperature measuring components 3 may include thermocouples. The temperature measuring component 3 includes: a thermocouple body 5, a measuring point 6 and a data transmission line 7; wherein,

The thermocouple body 5 is inserted into the slot 2, and the number of the thermocouple body 5 can be set according to actual production requirements. The number of thermocouple bodies 5 in this embodiment also includes five.

The temperature tracker 4 is connected to the other end of the temperature measuring component 3 through the data transmission line 7, and the temperature tracker 4 is used to collect multiple sets of temperature data of a plurality of the temperature measuring components 3 according to the predicted sampling times and sampling frequency ; The temperature data includes: the start time of sampling, the total number of sampling points and the position of each temperature measuring component 3 . The sampling frequency can be set according to actual production requirements, and the sampling frequency in this embodiment is 10s.

Here, the data transmission line 7 is also provided with a thermal insulation sleeve 8 to prevent the data transmission line 7 from being damaged by high temperature.

The temperature tracker 4 can be called a high-temperature black box, and the temperature tracker 4 is in the furnace for 10-11 hours at 1300°C.

The device also includes: a balance pressing block 9, which is installed above the slot 2, and a groove 10 is arranged on the balance pressing block 9, and the groove is used to fix the thermocouple One end of body 5. The balance pressure block 9 is also provided with a temperature measuring hole 11 . The measuring point of the temperature measuring component 3 is on the side of the temperature measuring hole 11, so as to ensure that the thermocouple body 5 is not blown away by the turbulent air flow in the ignition furnace during the measurement process, and at the same time ensure that the thermocouple measuring point 6 can obtain the ignition furnace The actual temperature data inside.

In practical application, place the device horizontally at the entrance of the sintering ignition furnace, cover each slot 2 with a balance pressing block 9, ensure that the thermocouple body 5 is placed in the groove 10 of the balance pressing block 9, and the thermocouple measuring point 6 below the Japanese temperature measuring hole 11. Start the sintering machine, the device enters the ignition furnace entrance along with the sintering material surface, and record the time at this time as t1, and then collect the temperature data of each temperature measuring component 3 according to the preset sampling frequency and sampling times until the device moves out of the ignition furnace, The time at this time is recorded as t2; finally, the temperature curves of the sintered material surface within the time period from t1 to t2 are derived. Here, during the temperature measurement process, each temperature measuring component 3 is directly close to the surface of the sintered material, and the actual temperature data on the surface of the sintered material can be continuously measured. Therefore, the temperature curve can truly reflect the ignition state in the ignition furnace, and thus can accurately judge the ignition furnace. Ignition quality; then the temperature curve can be used as the basis for judging the ignition quality of the ignition furnace, and then the ignition parameters can be adjusted according to the temperature curve.

Here, the device further includes an industrial computer, which is connected to the temperature tracker 4 by means of a wireless network or a transmission wire, and the industrial computer is used to receive the temperature data sent by the temperature tracker 4 . When the industrial computer and the temperature tracker 4 use a wireless network for data transmission, the temperature tracker 4 is provided with a wireless bridging terminal inside. After the temperature curve is transmitted to the industrial computer, the operator can use the industrial computer to print the temperature curve.

The beneficial effects that the device for measuring the temperature in the ignition furnace provided by the embodiments of the present invention can bring are at least:

An embodiment of the present invention provides a device for measuring the temperature in the ignition furnace, which is applied in the ignition furnace, and the device includes: a stabilizing component, a plurality of slots are arranged on the stabilizing component, and the plurality of slots Evenly distributed on the stable component; a plurality of temperature measuring components, one end of the multiple temperature measuring components is respectively connected to the slot; a temperature tracker is connected to the other end of the temperature measuring component through a data transmission line, The temperature tracker is used to collect multiple sets of temperature data of a plurality of temperature measuring components according to the predicted sampling times and sampling frequency; in this way, the device is horizontally placed at the entrance of the ignition furnace, since the stable components are uniformly arranged with Multiple slots, after the sintering machine is started, the device moves to the inside of the ignition furnace with the sintering machine, and each temperature measuring part is directly close to the surface of the sintering material. During the temperature measurement process, as the sintering machine moves in the furnace, it can continuously measure The actual temperature data on the surface of the sintered material can truly reflect the ignition state in the ignition furnace, and then accurately judge the ignition quality of the ignition furnace.

The above description is only a preferred embodiment of the present invention, and is not used to limit the protection scope of the present invention. Any modifications, equivalent replacements and improvements made within the spirit and principles of the present invention shall be included in the within the protection scope of the present invention.

Claims (10)

1. An apparatus for measuring a temperature in an ignition furnace, the apparatus comprising:

the stabilizing component is provided with a plurality of slots which are uniformly distributed on the stabilizing component;

one end of each temperature measuring component is connected with the corresponding slot;

and the temperature tracker is connected with the other end of the temperature measurement component through a data transmission line and is used for acquiring multiple groups of temperature data of the temperature measurement components according to the predicted sampling times and sampling frequency.

2. The apparatus of claim 1, wherein the apparatus further comprises: and the balance pressing block is arranged above the slot and is provided with a groove.

3. The apparatus of claim 2, wherein the balance block is further provided with a temperature sensing hole.

4. The apparatus of claim 3, wherein the temperature measuring member has a measuring point on one side of the temperature measuring hole.

5. The apparatus of claim 1, wherein the transmission conductor is further sheathed with an insulating sleeve.

6. The apparatus of claim 1, wherein the stabilizing component comprises: a stabilizer bar.

7. The apparatus of claim 1, wherein the thermometric component comprises: and a thermocouple.

8. The apparatus of claim 1, wherein the apparatus further comprises: the industrial computer is connected with the temperature tracker in a wireless network or transmission wire mode and used for receiving the temperature data sent by the temperature tracker.

9. The apparatus of claim 1, wherein the temperature data comprises: the initial time of sampling, the total number of sampling points and the position of the temperature measurement component.

10. The device of claim 1, wherein the in-furnace time of the temperature tracker 1300 ℃ is 10-11 h.