阅读说明：本技术 一种工业造气炉炉渣中碳含量检测系统及其检测方法 (System and method for detecting carbon content in industrial gas making furnace slag ) 是由 董侠艳 于 2021-02-17 设计创作，主要内容包括：本发明公开了一种工业造气炉炉渣中碳含量检测系统及其检测方法,包括检测仪,所述检测仪内设有工作空间,所述工作空间上侧内壁固定设有刮板,所述工作空间下侧内壁设有开口朝上的第一环槽与第二环槽；本发明可对一定质量的造气炉炉渣进行碳含量检测,通过两个反向转动的粉碎轮将造气炉炉渣进行粉碎,从一方面使得造气炉炉渣便于燃烧,另一方面,通过刮板配合旋转的第一金属板与第二金属板可将粉碎后的造气炉炉渣均匀分布用于燃烧,从而保障了造气炉炉渣的充分燃烧,从上述两方面保证了造气炉炉渣中的碳含量检测的准确性,通过二氧化碳检测仪来检测二氧化碳的含量来间接判断造气炉炉渣中的碳含量,并通过显示面板显示,十分简单,准确且直观。(The invention discloses a system and a method for detecting the carbon content in slag of an industrial gas-making furnace, wherein the system comprises a detector, a working space is arranged in the detector, a scraper is fixedly arranged on the inner wall of the upper side of the working space, and a first annular groove and a second annular groove with upward openings are arranged on the inner wall of the lower side of the working space; the carbon content detection device can detect the carbon content of the gas making furnace slag with certain mass, and crush the gas making furnace slag through the two crushing wheels which rotate in opposite directions, so that the gas making furnace slag is convenient to burn on one hand, and the crushed gas making furnace slag can be uniformly distributed for burning through the first metal plate and the second metal plate which rotate in a matched manner by the scraper, so that the full burning of the gas making furnace slag is ensured, the accuracy of the carbon content detection in the gas making furnace slag is ensured on the other hand, the carbon content in the gas making furnace slag is indirectly judged by detecting the carbon dioxide content through the carbon dioxide detector, and the display panel displays the carbon content, so that the carbon content detection device is very simple, accurate and visual.)

1. The utility model provides a carbon content detecting system in industry gas making furnace slag, includes the detector, its characterized in that: the detector is internally provided with a working space, a scraper is fixedly arranged on the inner wall of the upper side of the working space, a first annular groove and a second annular groove with upward openings are arranged on the inner wall of the lower side of the working space, the second annular groove is positioned inside the first annular groove, an arc-shaped block is slidably arranged on the right side in the second annular groove, a connecting rod is fixedly arranged on the upper end face of the arc-shaped block, the upper end of the connecting rod is positioned in the working space, a second metal plate is fixedly arranged on the upper end of the connecting rod, three first heating wires are embedded in the second metal plate, a gear ring is fixedly arranged on the inner wall of the lower side of the first annular groove, a hollow slide block is slidably arranged on the left side in the first annular groove, a rotating motor is embedded in the hollow slide block, a rotating shaft is controlled at the left end of the rotating motor, a gear is fixedly arranged on the left, the hydraulic rod is controlled by a hydraulic cylinder, a first metal plate is fixedly arranged at the upper end of the hydraulic cylinder, three second electric heating wires are embedded in the first metal plate, two top sliding rods are symmetrically and fixedly arranged on the front side and the rear side of the lower end face of the first metal plate, the top sliding rods are arranged on the top sliding rods in a vertical sliding mode, each guide rod is fixedly arranged on a matching sliding block, and the matching sliding blocks are arranged in the first annular grooves in a sliding mode; the carbon dioxide detector is embedded in the inner wall of the left side of the working space, the control terminal in the detector is embedded in the upper side of the carbon dioxide detector, the control terminal is connected with the carbon dioxide detector through a first wire, a display panel is embedded in the left end face of the detector, and the display panel is connected with the control terminal through a second wire.

2. The system for detecting the carbon content in the slag of the industrial gas-making furnace according to claim 1, wherein: the detector right-hand member face is equipped with the opening and towards the right storage space, storage space communicates through the seal groove in the left side working space, the fixed screw thread piece that is equipped with of storage space rear side inner wall, screw thread piece female connection has the screw thread axle that runs through the screw thread piece left and right sides, the screw thread axle right-hand member is located external space and fixed the handle that is equipped with, the screw thread axle left end is fixed and is equipped with sealed piece, sealed piece with seal groove is sealed within a definite time.

3. The system for detecting the carbon content in the slag of the industrial gas-making furnace according to claim 2, wherein: the working space upside be equipped with detector fixed connection's rotation motor, it has the power shaft to rotate motor front side control, the epaxial fixed rotary drum that is equipped with of power, the rotary drum upside is equipped with opening standing groove up, the detector up end is equipped with opening crushing space up, install first crushing wheel and second crushing wheel in the crushing space, the second crushing wheel is located first crushing wheel right side, the second crushing wheel with first crushing wheel has solitary power supply control respectively, first crushing takes turns to evenly to be fixed and is equipped with six first crushing pieces, the second crushing takes turns to evenly to be fixed and is equipped with six second crushing pieces.

4. The system for detecting the carbon content in the slag of the industrial gas-making furnace according to claim 1, wherein: the friction force between the arc-shaped block and the second ring groove is larger.

5. The method for detecting the carbon content in the industrial gas-making furnace slag according to claim 1, which is characterized in that: the method specifically comprises the following steps:

the carbon dioxide detector firstly detects the concentration of carbon dioxide in a working space and transmits the concentration data to the control terminal through a first electric wire;

after the industrial gas making furnace slag to be detected is manually weighed to a certain mass, the industrial gas making furnace slag is manually put into the device through a crushing space, power sources of a first crushing wheel and a second crushing wheel are started to drive the first crushing wheel and the second crushing wheel to rotate in opposite directions, the industrial gas making furnace slag can be crushed through a first crushing block on the first crushing wheel and a second crushing block on the second crushing wheel, and the crushed industrial gas making furnace slag falls into a placing groove;

after a period of time, the industrial gas making furnace slag is crushed and changed into powder, the rotating motor is started, the rotating motor controls the power shaft to rotate, the power shaft drives the rotating drum to rotate, the rotating drum rotates to pour the industrial gas making furnace slag powder in the placing groove to the rear side of the upper end surface of the first metal plate, the rotating drum rotates to reset, and the rotating motor stops working;

the rotary motor is started to drive the rotary shaft to rotate, the rotary shaft drives the gear to rotate, the hollow sliding block is driven to move along the first annular groove through the meshing of the gear and the gear ring, the hollow sliding block drives the hydraulic rod to move along the first annular groove, the hydraulic rod drives the hydraulic cylinder to move along the first annular groove, the hydraulic cylinder drives the first metal plate to move along the first annular groove, the first metal plate drives the second metal plate to move synchronously, the second metal plate drives the arc-shaped block to move along the second annular groove, under the action of the scraper, the industrial gas-making furnace slag powder on the upper end face of the first metal plate is uniformly distributed on the upper end face of the first metal plate and the upper end face of the second metal plate, and the height of the industrial gas-making furnace slag powder is the same as;

after the operation is finished, the rotating motor stops working, the second heating wire and the first heating wire are electrified simultaneously to generate heat, the industrial gas making furnace slag powder on the upper surfaces of the first metal plate and the second metal plate is ignited at high temperature through conduction of the first metal plate and the second metal plate, carbon components in the industrial gas making furnace slag powder are combusted to generate carbon dioxide, so that the concentration of the carbon dioxide in the working space is increased, after a period of time, the second heating wire and the first heating wire stop heating, the carbon dioxide detector is started to detect the carbon dioxide content in the working space, data detected by the carbon dioxide detector is provided for the first wire to be conducted into the control terminal, the control terminal analyzes the carbon dioxide concentration difference twice in the working space, can separate out the carbon content in the industrial gas making furnace slag, and analyzes whether the industrial gas making furnace normally works or not through the carbon content in the industrial gas making furnace slag, the control terminal can transmit the carbon content data in the industrial gas making furnace slag and the analyzed working condition of the industrial gas making furnace to the display panel through a second wire for displaying;

after the primary detection is finished, the handle is rotated to drive the threaded shaft to rotate, the threaded shaft is driven to rotate out through the threading of the threaded shaft and the threaded block, the threaded shaft drives the sealing block to rotate out, so that the working space is communicated with the external space until the concentration of carbon dioxide in the working space is reduced to be close to the external space, meanwhile, the hydraulic cylinder is started, the control hydraulic rod extends out to drive the first metal plate to ascend to be attached to the lower end face of the scraper plate, meanwhile, the lower end face of the first metal plate moves to the upper end face of the second metal plate, the rotary motor is started to drive the first metal plate to move, at the moment, the scraper plate can scrape away combustion residues of industrial gas-making furnace slag on the upper end face of the first metal plate, the residues fall to the lower side of the working space, meanwhile, because the friction force between the arc-shaped block and the second ring groove is large, the first metal plate does not drive the second metal plate to move, the first metal plate can scrape away the combustion residues of, the residue equally drops to the workspace downside, and the back is accomplished, and pneumatic cylinder control hydraulic stem is withdrawed and to be taken back and to drive first metal sheet and the detection that the second metal sheet resets and can continue next time, scrapes the purpose of getting the residue and is not influenced in order to guarantee the burning of next batch industry gas making stove slag, guarantees to detect the accuracy.

Technical Field

The invention relates to the technical field of industrial carbon content detection, in particular to a system and a method for detecting the carbon content in industrial gas making furnace slag.

Background

The gas making furnace is the common industrial mechanical equipment of intermittent type manufacturing semi-water gas, in the working process of gas making furnace, utilize the coal cinder as the raw materials, the utilization ratio about the coal cinder can be judged through the carbon content detection that detects in the gas making furnace slag, and in current equipment, it is less to the detection of the carbon content in the gas making furnace slag, mostly need a large amount of manual assistance to go on, it is very inconvenient, and in the testing process, because the structural feature of gas making furnace slag self, it also can't realize complete combustion to pile up burning together, reduce the precision that detects.

Disclosure of Invention

The invention aims to provide a system and a method for detecting the carbon content in industrial gas-making furnace slag, which aim to solve the problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme: a detection system and a detection method for carbon content in industrial gas making furnace slag comprise a detector, wherein a working space is arranged in the detector, a scraper is fixedly arranged on the inner wall of the upper side of the working space, a first annular groove and a second annular groove with upward openings are arranged on the inner wall of the lower side of the working space, the second annular groove is positioned inside the first annular groove, an arc-shaped block is arranged on the inner right side of the second annular groove in a sliding manner, a connecting rod is fixedly arranged on the upper end face of the arc-shaped block, the upper end of the connecting rod is positioned in the working space, a second metal plate is fixedly arranged on the upper end of the connecting rod, three first heating wires are embedded in the second metal plate, a gear ring is fixedly arranged on the inner wall of the lower side of the first annular groove, a hollow slide block is arranged on the inner left side of the first annular groove in a sliding manner, the gear is meshed with the gear ring, a hydraulic rod with the upper end positioned in the working space is fixedly arranged on the upper end face of the hollow sliding block, the hydraulic rod is controlled by a hydraulic cylinder, a first metal plate is fixedly arranged at the upper end of the hydraulic cylinder, three second heating wires are embedded in the first metal plate, two top sliding rods are symmetrically and fixedly arranged on the front side and the rear side of the lower end face of the first metal plate, the top sliding rods are vertically and slidably arranged on the top sliding rods, each guide rod is fixedly arranged on a matching sliding block, and the matching sliding block is slidably arranged in the first annular groove;

the carbon dioxide detector is embedded in the inner wall of the left side of the working space, the control terminal in the detector is embedded in the upper side of the carbon dioxide detector, the control terminal is connected with the carbon dioxide detector through a first wire, a display panel is embedded in the left end face of the detector, and the display panel is connected with the control terminal through a second wire.

The detector right-hand member face is equipped with the opening and towards the right storage space, storage space communicates through the seal groove in the left side working space, the fixed screw thread piece that is equipped with of storage space rear side inner wall, screw thread piece female connection has the screw thread axle that runs through the screw thread piece left and right sides, the screw thread axle right-hand member is located external space and fixed the handle that is equipped with, the screw thread axle left end is fixed and is equipped with sealed piece, sealed piece with seal groove is sealed within a definite time.

The working space upside be equipped with detector fixed connection's rotation motor, it has the power shaft to rotate motor front side control, the epaxial fixed rotary drum that is equipped with of power, the rotary drum upside is equipped with opening standing groove up, the detector up end is equipped with opening crushing space up, install first crushing wheel and second crushing wheel in the crushing space, the second crushing wheel is located first crushing wheel right side, the second crushing wheel with first crushing wheel has solitary power supply control respectively, first crushing takes turns to evenly to be fixed and is equipped with six first crushing pieces, the second crushing takes turns to evenly to be fixed and is equipped with six second crushing pieces.

The friction force between the arc-shaped block and the second ring groove is larger.

A detection method of a carbon content detection system in industrial gas making furnace slag comprises the following specific steps:

the carbon dioxide detector firstly detects the concentration of carbon dioxide in a working space and transmits the concentration data to the control terminal through a first electric wire;

after the industrial gas making furnace slag to be detected is manually weighed to a certain mass, the industrial gas making furnace slag is manually put into the device through a crushing space, power sources of a first crushing wheel and a second crushing wheel are started to drive the first crushing wheel and the second crushing wheel to rotate in opposite directions, the industrial gas making furnace slag can be crushed through a first crushing block on the first crushing wheel and a second crushing block on the second crushing wheel, and the crushed industrial gas making furnace slag falls into a placing groove;

after a period of time, the industrial gas making furnace slag is crushed and changed into powder, the rotating motor is started, the rotating motor controls the power shaft to rotate, the power shaft drives the rotating drum to rotate, the rotating drum rotates to pour the industrial gas making furnace slag powder in the placing groove to the rear side of the upper end surface of the first metal plate, the rotating drum rotates to reset, and the rotating motor stops working;

the rotary motor is started to drive the rotary shaft to rotate, the rotary shaft drives the gear to rotate, the hollow sliding block is driven to move along the first annular groove through the meshing of the gear and the gear ring, the hollow sliding block drives the hydraulic rod to move along the first annular groove, the hydraulic rod drives the hydraulic cylinder to move along the first annular groove, the hydraulic cylinder drives the first metal plate to move along the first annular groove, the first metal plate drives the second metal plate to move synchronously, the second metal plate drives the arc-shaped block to move along the second annular groove, under the action of the scraper, the industrial gas-making furnace slag powder on the upper end face of the first metal plate is uniformly distributed on the upper end face of the first metal plate and the upper end face of the second metal plate, and the height of the industrial gas-making furnace slag powder is the same as;

after the operation is finished, the rotating motor stops working, the second heating wire and the first heating wire are electrified simultaneously to generate heat, the industrial gas making furnace slag powder on the upper surfaces of the first metal plate and the second metal plate is ignited at high temperature through conduction of the first metal plate and the second metal plate, carbon components in the industrial gas making furnace slag powder are combusted to generate carbon dioxide, so that the concentration of the carbon dioxide in the working space is increased, after a period of time, the second heating wire and the first heating wire stop heating, the carbon dioxide detector is started to detect the carbon dioxide content in the working space, data detected by the carbon dioxide detector is provided for the first wire to be conducted into the control terminal, the control terminal analyzes the carbon dioxide concentration difference twice in the working space, can separate out the carbon content in the industrial gas making furnace slag, and analyzes whether the industrial gas making furnace normally works or not through the carbon content in the industrial gas making furnace slag, the control terminal can transmit the carbon content data in the industrial gas making furnace slag and the analyzed working condition of the industrial gas making furnace to the display panel through a second wire for displaying;

after the primary detection is finished, the handle is rotated to drive the threaded shaft to rotate, the threaded shaft is driven to rotate out through the threading of the threaded shaft and the threaded block, the threaded shaft drives the sealing block to rotate out, so that the working space is communicated with the external space until the concentration of carbon dioxide in the working space is reduced to be close to the external space, meanwhile, the hydraulic cylinder is started, the control hydraulic rod extends out to drive the first metal plate to ascend to be attached to the lower end face of the scraper plate, meanwhile, the lower end face of the first metal plate moves to the upper end face of the second metal plate, the rotary motor is started to drive the first metal plate to move, at the moment, the scraper plate can scrape away combustion residues of industrial gas-making furnace slag on the upper end face of the first metal plate, the residues fall to the lower side of the working space, meanwhile, because the friction force between the arc-shaped block and the second ring groove is large, the first metal plate does not drive the second metal plate to move, the first metal plate can scrape away the combustion residues of, the residue equally drops to the workspace downside, and the back is accomplished, and pneumatic cylinder control hydraulic stem is withdrawed and to be taken back and to drive first metal sheet and the detection that the second metal sheet resets and can continue next time, scrapes the purpose of getting the residue and is not influenced in order to guarantee the burning of next batch industry gas making stove slag, guarantees to detect the accuracy.

Compared with the prior art, the invention has the beneficial effects that: the carbon content detection device can detect the carbon content of the gas making furnace slag with certain mass, and crush the gas making furnace slag through the two crushing wheels which rotate in opposite directions, so that the gas making furnace slag is convenient to burn on one hand, and the crushed gas making furnace slag can be uniformly distributed for burning through the first metal plate and the second metal plate which rotate in a matched manner by the scraper, so that the full burning of the gas making furnace slag is ensured, the accuracy of the carbon content detection in the gas making furnace slag is ensured on the other hand, the carbon content in the gas making furnace slag is indirectly judged by detecting the carbon dioxide content through the carbon dioxide detector, and the display panel displays the carbon content, so that the carbon content detection device is very simple, accurate and visual.

Drawings

FIG. 1 is a schematic view of the overall structure of a system for detecting the carbon content in slag of an industrial gas-generating furnace according to the present invention;

FIG. 2 is an enlarged schematic view of the structure at A in FIG. 1;

FIG. 3 is a schematic view of the structure in the direction B-B in FIG. 1;

FIG. 4 is a schematic view of the structure in the direction C-C in FIG. 1;

fig. 5 is a schematic view of the structure in the direction D-D in fig. 1.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: the system comprises a detector 10, a working space 30 is arranged in the detector 10, a scraper 35 is fixedly arranged on the inner wall of the upper side of the working space 30, a first annular groove 25 and a second annular groove 31 with upward openings are arranged on the inner wall of the lower side of the working space 30, the second annular groove 31 is positioned inside the first annular groove 25, an arc block 27 is arranged on the inner right side of the second annular groove 31 in a sliding manner, a connecting rod 24 is fixedly arranged on the upper end face of the arc block 27, the upper end of the connecting rod 24 is positioned in the working space 30, a second metal plate 23 is fixedly arranged on the upper end of the connecting rod 24, three first electric heating wires 52 are embedded in the second metal plate 23, a gear ring 26 is fixedly arranged on the inner wall of the lower side of the first annular groove 25, a hollow sliding block 41 is arranged on the inner left side of the first annular groove 25 in a sliding manner, a rotating motor 44, a rotating shaft 43 is controlled at the left end of the rotating motor 44, a gear 42 is fixedly arranged at the left end of the rotating shaft 43, the gear 42 is meshed with the gear ring 26, a hydraulic rod 33 with the upper end positioned in the working space 30 is fixedly arranged on the upper end face of the hollow slide block 41, the hydraulic rod 33 is controlled by a hydraulic cylinder 32, a first metal plate 34 is fixedly arranged at the upper end of the hydraulic cylinder 32, three second electric heating wires 51 are embedded in the first metal plate 34, two top slide rods 28 are symmetrically and fixedly arranged at the front side and the rear side of the lower end face of the first metal plate 34, the top slide rods 28 are vertically slidably arranged on the top slide rods 28, each guide rod 29 is fixedly arranged on a matching slide block 45, and the matching slide block 45 is slidably arranged in the first annular groove 25;

the inner wall of the left side of the working space 30 is embedded with a carbon dioxide detector 36, the upper side of the carbon dioxide detector 36 is provided with a control terminal 38 embedded in the detector 10, the control terminal 38 is connected with the carbon dioxide detector 36 through a first electric wire 37, the left end face of the detector 10 is embedded with a display panel 40, and the display panel 40 is connected with the control terminal 38 through a second electric wire 39.

The right end face of the detector 10 is provided with a containing space 19 with an opening facing the right, the left side of the containing space 19 is communicated with the working space 30 through a sealing groove 17, a thread block 21 is fixedly arranged on the inner wall of the rear side of the containing space 19, the thread block 21 is internally connected with a thread shaft 20 penetrating through the left side and the right side of the thread block 21, the right end of the thread shaft 20 is located in the external space and is fixedly provided with a handle 22, a sealing block 18 is fixedly arranged at the left end of the thread shaft 20, and the sealing block 18 is sealed with the sealing groove 17.

The utility model discloses a detector 10, including working space 30 upside be equipped with detector 10 fixed connection's rotation motor 15, rotation motor 15 front side control has power shaft 16, the last fixed rotary drum 54 that is equipped with of power shaft 16, rotary drum 54 upside is equipped with opening standing groove 14 up, detector 10 up end is equipped with opening crushing space 11 up, install first crushing wheel 12 and second crushing wheel 13 in the crushing space 11, second crushing wheel 13 is located first crushing wheel 12 right side, second crushing wheel 13 with first crushing wheel 12 has solitary power source control respectively, evenly fixed being equipped with six first crushing pieces 50 on the first crushing wheel 12, evenly fixed being equipped with six second crushing pieces 48 on the second crushing wheel 13.

The friction between the arc-shaped block 27 and the second annular groove 31 is relatively large.

A detection method of a carbon content detection system in industrial gas making furnace slag comprises the following specific steps:

the carbon dioxide detector 36 first detects the concentration of carbon dioxide in the workspace 30 and transmits the concentration data to the control terminal 38 via the first wire 37;

after the industrial gas making furnace slag to be detected is manually taken out to be of a certain mass, the industrial gas making furnace slag is manually put into the device through the crushing space 11, power sources of the first crushing wheel 12 and the second crushing wheel 13 are started to drive the first crushing wheel 12 and the second crushing wheel 13 to rotate reversely, the industrial gas making furnace slag can be crushed through the first crushing block 50 on the first crushing wheel 12 and the second crushing block 48 on the second crushing wheel 13, and the crushed industrial gas making furnace slag falls into the placing groove 14;

after a period of time, the slag of the industrial gas making furnace is crushed and turns into powder, the rotating motor 15 is started, the rotating motor 15 controls the power shaft 16 to rotate, the power shaft 16 drives the rotary drum 54 to rotate, the rotary drum 54 rotates to pour the slag powder of the industrial gas making furnace in the placing groove 14 to the rear side of the upper end surface of the first metal plate 34, the rotary drum 54 rotates to reset, and the rotating motor 15 stops working;

the rotating motor 44 is started to drive the rotating shaft 43 to rotate, the rotating shaft 43 drives the gear 42 to rotate, the gear 42 is meshed with the gear ring 26 to drive the hollow sliding block 41 to move along the first annular groove 25, the hollow sliding block 41 drives the hydraulic rod 33 to move along the first annular groove 25, the hydraulic rod 33 drives the hydraulic cylinder 32 to move along the first annular groove 25, the hydraulic cylinder 32 drives the first metal plate 34 to move along the first annular groove 25, the first metal plate 34 drives the second metal plate 23 to move synchronously, the second metal plate 23 drives the arc-shaped block 27 to move along the second annular groove 31, under the action of the scraper 35, the industrial gas-making furnace slag powder on the upper end surface of the first metal plate 34 is uniformly distributed on the upper end surface of the first metal plate 34 and the upper end surface of the second metal plate 23, and the height of the industrial gas-making furnace slag powder layer is the same as the;

after the operation is completed, the rotating motor 44 stops working, the second heating wire 51 and the first heating wire 52 are simultaneously electrified to generate heat, the industrial gas making furnace slag powder on the upper surfaces of the first metal plate 34 and the second metal plate 23 is ignited at high temperature through the conduction of the first metal plate 34 and the second metal plate 23, carbon in the industrial gas making furnace slag powder is combusted to generate carbon dioxide, so that the concentration of the carbon dioxide in the working space 30 is increased, after a period of time, the second heating wire 51 and the first heating wire 52 stop heating, the carbon dioxide detector 36 is started to detect the carbon dioxide content in the working space 30, data detected by the carbon dioxide detector 36 is provided to the first wire 37 to be conducted into the control terminal 38, the control terminal 38 analyzes the carbon dioxide concentration difference between the front and back times in the working space 30, the carbon content in the industrial gas making furnace slag can be separated, and whether the industrial gas making furnace works normally or not is analyzed through the carbon content in the industrial gas making furnace slag, the control terminal 38 can transmit the carbon content data in the slag of the industrial gas making furnace and the analyzed working condition of the industrial gas making furnace to the display panel 40 through the second wire 39 for displaying;

after the detection is finished once, the handle 22 is rotated to drive the threaded shaft 20 to rotate, the threaded shaft 20 is driven to rotate out by threading the threads of the threaded shaft 20 and the threaded block 21, the threaded shaft 20 drives the sealing block 18 to rotate out, so that the working space 30 is communicated with the external space until the concentration of carbon dioxide in the working space 30 is reduced to be close to the external space, meanwhile, the hydraulic cylinder 32 is started to control the hydraulic rod 33 to extend out to drive the first metal plate 34 to ascend to be attached to the lower end face of the scraper 35, meanwhile, the lower end face of the first metal plate 34 moves to the upper end face of the second metal plate 23, the rotating motor 44 is started to drive the first metal plate 34 to move, at the moment, the scraper 35 can scrape away combustion residues of industrial gas making furnace slag on the upper end face of the first metal plate 34, the residues fall to the lower side of the working space 30, meanwhile, because the friction force between the arc-shaped block 27 and the second annular groove 31 is large, the first metal plate 34, first metal sheet 34 moves and can scrape away the industry gas making stove slag burning residue of second metal sheet 23 up end, and the residue equally drops to workspace 30 downside, accomplishes the back, and pneumatic cylinder 32 control hydraulic stem 33 is withdrawed and to be withdrawed and to drive first metal sheet 34 and second metal sheet 23 and reset and can continue the next detection, scrapes the purpose of getting the residue and is not influenced in order to guarantee the burning of next batch industry gas making stove slag, guarantees to detect the accuracy.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.