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HuangHai 2 weeks ago
parent 07086e3c0c
commit a5c5149bd2
9 changed files with 315 additions and 34 deletions
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30
dsRagAnything/Doc/RagAnything配置.md
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@ -24,7 +24,7 @@ conda activate raganything
https://zh-cn.libreoffice.org/
```sh
# 下载的版本:
# 下载的版本:
https://mirrors.nju.edu.cn/tdf/libreoffice/stable/25.2.4/win/x86_64/LibreOffice_25.2.4_Win_x86-64.msi
```
@ -52,31 +52,18 @@ mineru-models-download
#### 四、代码调试
- 解决在国内网络无法下载$huggingface$的问题
```sh
# 要修改的文件
D:\anaconda3\envs\raganything\Lib\site-packages\huggingface_hub\constants.py
# 修改文件
HUGGINGFACE_CO_URL_HOME = "https://hf-mirror.com/"
_HF_DEFAULT_ENDPOINT = "https://hf-mirror.com"
```
- 将soffice.exe添加到环境变量
```
- ```
C:\Program Files\LibreOffice\program
```
![](https://dsideal.obs.cn-north-1.myhuaweicloud.com/HuangHai/BlogImages/%7Byear%7D/%7Bmonth%7D/%7Bmd5%7D.%7BextName%7D/20250706155805724.png)
- **注意**:需要提前配置好环境变量后,再进入$PyCharm$进行调试,因为我发现,如果是在打开$PyCharm$的前提下,添加了环境就是$PyCharm$里面的代码是检测不到的。
- 因为原版的程序有$soffice.exe$版本检测框弹出,不能直接用于生产环境,手动修改代码:
```cmd
@ -200,3 +187,14 @@ https://blog.csdn.net/lovechris00/article/details/140584728
https://zhuanlan.zhihu.com/p/1908942870666282723
```
- 解决在国内网络无法下载$huggingface$的问题
```sh
# 要修改的文件
D:\anaconda3\envs\raganything\Lib\site-packages\huggingface_hub\constants.py
# 修改文件
HUGGINGFACE_CO_URL_HOME = "https://hf-mirror.com/"
_HF_DEFAULT_ENDPOINT = "https://hf-mirror.com"
```

4
dsRagAnything/T2_Query.py
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@ -1,9 +1,9 @@
import asyncio
import os
from lightrag import LightRAG
from lightrag.kg.shared_storage import initialize_pipeline_status
from raganything import RAGAnything
from lightrag import LightRAG
from Util.RagUtil import create_llm_model_func, create_vision_model_func, create_embedding_func

282
dsRagAnything/Topic/Chemistry/graph_chunk_entity_relation.graphml
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@ -178,10 +178,10 @@
<node id="Reaction Kinetics">
<data key="d0">Reaction Kinetics</data>
<data key="d1">category</data>
<data key="d2">Reaction kinetics is the study of the rates at which chemical reactions occur. The given equation relates to this field when considering how quickly hydrogen and oxygen combine to form water under different conditions.&lt;SEP&gt;The study of rates of chemical reactions and the factors that affect them.&lt;SEP&gt;Reaction kinetics studies the rates and mechanisms of chemical reactions. It relates to the molar proportions defined in the equation $ 2 H_2 + O_2 \rightarrow 2 H_2O $, influencing how quickly the reaction proceeds.</data>
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<data key="d2">Reaction kinetics is the study of the rates at which chemical reactions occur. The given equation relates to this field when considering how quickly hydrogen and oxygen combine to form water under different conditions.&lt;SEP&gt;The study of rates of chemical reactions and the factors that affect them.&lt;SEP&gt;Reaction kinetics studies the rates and mechanisms of chemical reactions. It relates to the molar proportions defined in the equation $ 2 H_2 + O_2 \rightarrow 2 H_2O $, influencing how quickly the reaction proceeds.&lt;SEP&gt;The study of reaction rates and mechanisms, relevant to understanding how quickly H2 and O2 convert into H2O.</data>
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<node id="Enthalpy Change">
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@ -226,10 +226,10 @@
<node id="Water Synthesis Reaction Equation (equation)">
<data key="d0">Water Synthesis Reaction Equation (equation)</data>
<data key="d1">equation</data>
<data key="d2">This equation models the stoichiometric reaction of hydrogen and oxygen forming water, illustrating conservation of mass and atomic balance. It plays a central role in understanding combustion, electrochemistry, and clean energy systems like hydrogen fuel cells.</data>
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<data key="d2">This equation describes the stoichiometrically balanced formation of water from hydrogen and oxygen gases. It is central to understanding combustion reactions, fuel efficiency, and energy production in chemical and aerospace engineering contexts.</data>
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@ -290,10 +290,10 @@
<node id="Chemical Thermodynamics">
<data key="d0">Chemical Thermodynamics</data>
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<data key="d2">Chemical thermodynamics deals with the energy changes during chemical reactions. The hydrogen-oxygen reaction described in the text is analyzed within this framework to understand its energetic feasibility and efficiency.</data>
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<data key="d2">A field within physical chemistry that studies energy transformations during chemical reactions and the spontaneity of processes.&lt;SEP&gt;Chemical thermodynamics deals with the energy changes during chemical reactions. The hydrogen-oxygen reaction described in the text is analyzed within this framework to understand its energetic feasibility and efficiency.</data>
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@ -335,6 +335,86 @@
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<data key="d2">A molecule composed of two hydrogen atoms and one oxygen atom (H2O), produced as the product in the synthesis reaction.</data>
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<data key="d2">The event of representing a balanced stoichiometric chemical reaction, specifically the synthesis of water from hydrogen and oxygen.</data>
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<data key="d2">A branch of chemistry dealing with the physical principles underlying chemical systems, including thermodynamics, kinetics, and electrochemistry.</data>
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<data key="d4">氢气与氧气反应化学方程式.docx</data>
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<data key="d0">Enthalpy Changes</data>
<data key="d1">category</data>
<data key="d2">Thermodynamic quantities representing heat transfer at constant pressure, analyzed using Hesss Law in this reaction.</data>
<data key="d3">chunk-e80e2698c1728e9ea5b4f84f9f5d4786</data>
<data key="d4">氢气与氧气反应化学方程式.docx</data>
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<data key="d1">category</data>
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<data key="d4">氢气与氧气反应化学方程式.docx</data>
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<data key="d1">category</data>
<data key="d2">A branch of physical chemistry concerned with the interplay between electrical energy and chemical change, such as in fuel cells using this reaction.</data>
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<data key="d4">氢气与氧气反应化学方程式.docx</data>
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<node id="Fuel Cell Systems">
<data key="d0">Fuel Cell Systems</data>
<data key="d1">organization</data>
<data key="d2">Technological systems that utilize the hydrogen-oxygen reaction to generate electricity through electrochemical means.</data>
<data key="d3">chunk-e80e2698c1728e9ea5b4f84f9f5d4786</data>
<data key="d4">氢气与氧气反应化学方程式.docx</data>
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