Tian et al., 2018 - Google Patents
Radar detection-based modeling in a blast furnace: A prediction model of burden surface shape after chargingTian et al., 2018
View PDF- Document ID
- 5573960825409315295
- Author
- Tian J
- Tanaka A
- Hou Q
- Chen X
- Publication year
- Publication venue
- ISIJ international
External Links
Snippet
Radar detection is an advanced method for monitoring a blast furnace's inner burden surface shape, which is an important factor that largely affects the production efficiency of the iron-making process. In this paper, a radar detection-based model for the prediction of …
- 238000001514 detection method 0 title abstract description 28
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Tian et al. | Radar detection-based modeling in a blast furnace: A prediction model of burden surface shape after charging | |
| US9886526B2 (en) | 3D printing shrinkage compensation using radial and angular layer perimeter point information | |
| CN101898324B (en) | Method for polishing ion beam with high-gradient mirror surface | |
| Li et al. | Efficient force prediction for incremental sheet forming and experimental validation | |
| Desai et al. | On cutter deflection surface errors in peripheral milling | |
| KR102023613B1 (en) | Method of radar melting level data assimilation based on um vdaps, computer readable medium and apparatus for performing the method | |
| CN106226764A (en) | A kind of assay method of sunken region, coal mining based on D InSAR ground | |
| CN1738680A (en) | Method for defining the degree of fullness in a mill | |
| CN110222454B (en) | Process design method for milling precision consistency | |
| CN104615082B (en) | A kind of real-time compensation device in place of working angles middle guide coupling error and method | |
| Wang et al. | 3D surface representation and trajectory optimization with a learning-based adaptive model predictive controller in incremental forming | |
| Tian et al. | Tracking the burden surface radial profile of a blast furnace by a B-mode mechanical swing radar system | |
| CN103472447B (en) | Multipoint-radar collaborative imaging device based on chute position judgment and method thereof | |
| CN108776713A (en) | A kind of chain grate machine temperature field Region Decomposition modeling method | |
| Chen et al. | Mathematical model of burden distribution in bell-less top blast furnace | |
| Min et al. | Design and experiment of dynamic measurement method for bulk material of large volume belt conveyor based on laser triangulation method | |
| CN113609936B (en) | Method for determining radial descending speed distribution of furnace burden at upper part of blast furnace | |
| CN105039621A (en) | Burden surface profile measurement method for blast furnace | |
| Duan et al. | Research on the blast furnace charge position tracking based on machine learning regression model | |
| Wang et al. | Optimal design of motion control for scan tracking measurement: a CMAC approach | |
| JP5232269B2 (en) | How to measure material flow width | |
| Yue et al. | An integrated method for measurement of diamond tools based on AFM | |
| Chen et al. | Application of blast furnace falling materials trajectories measurement using laser scan technology | |
| CN114961863B (en) | Fully mechanized coal mining face coal-rock interface identification method based on natural gamma rays | |
| Cao et al. | A profile feature mining method for burden surface in blast furnace based on monocular video images |