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@ -163,6 +163,12 @@
</a>
</li>
<li class="md-select__item">
<a href="/hu/" hreflang="hu" class="md-select__link">
Magyar
</a>
</li>
</ul>
</div>
</div>
@ -491,8 +497,8 @@
</li>
<li class="md-nav__item">
<a href="#mcu-mcu-my_extra_mcu" class="md-nav__link">
额外的mcu [mcu my_extra_mcu]
<a href="#mcu-my_extra_mcu" class="md-nav__link">
[mcu my_extra_mcu]
</a>
</li>
@ -504,10 +510,10 @@
<li class="md-nav__item">
<a href="#_4" class="md-nav__link">
的运动学设置
的运动学设置
</a>
<nav class="md-nav" aria-label="常的运动学设置">
<nav class="md-nav" aria-label="常的运动学设置">
<ul class="md-nav__list">
<li class="md-nav__item">
@ -553,15 +559,15 @@
</li>
<li class="md-nav__item">
<a href="#corexy_2" class="md-nav__link">
混合型 CoreXY 运动学
<a href="#hybrid-corexy-corexy" class="md-nav__link">
Hybrid-CoreXY (混合型 CoreXY) 运动学
</a>
</li>
<li class="md-nav__item">
<a href="#corexz" class="md-nav__link">
混合型 CoreXZ 运动学
<a href="#hybrid-corexz-corexz" class="md-nav__link">
Hybrid-CoreXZ (混合型 CoreXZ) 运动学
</a>
</li>
@ -574,8 +580,8 @@
</li>
<li class="md-nav__item">
<a href="#rotary-delta-kinematics" class="md-nav__link">
Rotary delta Kinematics
<a href="#rotary-delta" class="md-nav__link">
Rotary delta 运动学
</a>
</li>
@ -601,10 +607,10 @@
<li class="md-nav__item">
<a href="#_10" class="md-nav__link">
通用挤出机和热床支持
常见的挤出机和热床支持
</a>
<nav class="md-nav" aria-label="通用挤出机和热床支持">
<nav class="md-nav" aria-label="常见的挤出机和热床支持">
<ul class="md-nav__list">
<li class="md-nav__item">
@ -895,10 +901,10 @@
<li class="md-nav__item">
<a href="#_15" class="md-nav__link">
打印床探测硬件
床探测硬件
</a>
<nav class="md-nav" aria-label="打印床探测硬件">
<nav class="md-nav" aria-label="床探测硬件">
<ul class="md-nav__list">
<li class="md-nav__item">
@ -1047,7 +1053,7 @@
<li class="md-nav__item">
<a href="#pt1000" class="md-nav__link">
直接连接PT1000 传感器
直接连接PT1000 传感器
</a>
</li>
@ -1299,11 +1305,11 @@
</li>
<li class="md-nav__item">
<a href="#run-time-stepper-motor-current-configuration" class="md-nav__link">
Run-time stepper motor current configuration
<a href="#_23" class="md-nav__link">
运行时步进电机电流配置
</a>
<nav class="md-nav" aria-label="Run-time stepper motor current configuration">
<nav class="md-nav" aria-label="运行时步进电机电流配置">
<ul class="md-nav__list">
<li class="md-nav__item">
@ -1340,7 +1346,7 @@
</li>
<li class="md-nav__item">
<a href="#_23" class="md-nav__link">
<a href="#_24" class="md-nav__link">
显示屏支持
</a>
@ -1443,7 +1449,7 @@
</li>
<li class="md-nav__item">
<a href="#_24" class="md-nav__link">
<a href="#_25" class="md-nav__link">
耗材传感器
</a>
@ -1484,7 +1490,7 @@
</li>
<li class="md-nav__item">
<a href="#_25" class="md-nav__link">
<a href="#_26" class="md-nav__link">
控制板特定硬件支持
</a>
@ -1525,7 +1531,7 @@
</li>
<li class="md-nav__item">
<a href="#_26" class="md-nav__link">
<a href="#_27" class="md-nav__link">
其他自定义模块
</a>
@ -1552,11 +1558,11 @@
</li>
<li class="md-nav__item">
<a href="#_27" class="md-nav__link">
通用总线参数
<a href="#_28" class="md-nav__link">
常见的总线参数
</a>
<nav class="md-nav" aria-label="通用总线参数">
<nav class="md-nav" aria-label="常见的总线参数">
<ul class="md-nav__list">
<li class="md-nav__item">
@ -1568,7 +1574,7 @@
<li class="md-nav__item">
<a href="#i2c" class="md-nav__link">
通用 I2C 设置
常见的I2C 设置
</a>
</li>
@ -1924,7 +1930,7 @@
<li class="md-nav__item">
<a href="Multi_MCU_Homing.html" class="md-nav__link">
多微控制器复位与探测
多微控制器归位与探高
</a>
</li>
@ -2348,8 +2354,8 @@
</li>
<li class="md-nav__item">
<a href="#mcu-mcu-my_extra_mcu" class="md-nav__link">
额外的mcu [mcu my_extra_mcu]
<a href="#mcu-my_extra_mcu" class="md-nav__link">
[mcu my_extra_mcu]
</a>
</li>
@ -2361,10 +2367,10 @@
<li class="md-nav__item">
<a href="#_4" class="md-nav__link">
的运动学设置
的运动学设置
</a>
<nav class="md-nav" aria-label="常的运动学设置">
<nav class="md-nav" aria-label="常的运动学设置">
<ul class="md-nav__list">
<li class="md-nav__item">
@ -2410,15 +2416,15 @@
</li>
<li class="md-nav__item">
<a href="#corexy_2" class="md-nav__link">
混合型 CoreXY 运动学
<a href="#hybrid-corexy-corexy" class="md-nav__link">
Hybrid-CoreXY (混合型 CoreXY) 运动学
</a>
</li>
<li class="md-nav__item">
<a href="#corexz" class="md-nav__link">
混合型 CoreXZ 运动学
<a href="#hybrid-corexz-corexz" class="md-nav__link">
Hybrid-CoreXZ (混合型 CoreXZ) 运动学
</a>
</li>
@ -2431,8 +2437,8 @@
</li>
<li class="md-nav__item">
<a href="#rotary-delta-kinematics" class="md-nav__link">
Rotary delta Kinematics
<a href="#rotary-delta" class="md-nav__link">
Rotary delta 运动学
</a>
</li>
@ -2458,10 +2464,10 @@
<li class="md-nav__item">
<a href="#_10" class="md-nav__link">
通用挤出机和热床支持
常见的挤出机和热床支持
</a>
<nav class="md-nav" aria-label="通用挤出机和热床支持">
<nav class="md-nav" aria-label="常见的挤出机和热床支持">
<ul class="md-nav__list">
<li class="md-nav__item">
@ -2752,10 +2758,10 @@
<li class="md-nav__item">
<a href="#_15" class="md-nav__link">
打印床探测硬件
床探测硬件
</a>
<nav class="md-nav" aria-label="打印床探测硬件">
<nav class="md-nav" aria-label="床探测硬件">
<ul class="md-nav__list">
<li class="md-nav__item">
@ -2904,7 +2910,7 @@
<li class="md-nav__item">
<a href="#pt1000" class="md-nav__link">
直接连接PT1000 传感器
直接连接PT1000 传感器
</a>
</li>
@ -3156,11 +3162,11 @@
</li>
<li class="md-nav__item">
<a href="#run-time-stepper-motor-current-configuration" class="md-nav__link">
Run-time stepper motor current configuration
<a href="#_23" class="md-nav__link">
运行时步进电机电流配置
</a>
<nav class="md-nav" aria-label="Run-time stepper motor current configuration">
<nav class="md-nav" aria-label="运行时步进电机电流配置">
<ul class="md-nav__list">
<li class="md-nav__item">
@ -3197,7 +3203,7 @@
</li>
<li class="md-nav__item">
<a href="#_23" class="md-nav__link">
<a href="#_24" class="md-nav__link">
显示屏支持
</a>
@ -3300,7 +3306,7 @@
</li>
<li class="md-nav__item">
<a href="#_24" class="md-nav__link">
<a href="#_25" class="md-nav__link">
耗材传感器
</a>
@ -3341,7 +3347,7 @@
</li>
<li class="md-nav__item">
<a href="#_25" class="md-nav__link">
<a href="#_26" class="md-nav__link">
控制板特定硬件支持
</a>
@ -3382,7 +3388,7 @@
</li>
<li class="md-nav__item">
<a href="#_26" class="md-nav__link">
<a href="#_27" class="md-nav__link">
其他自定义模块
</a>
@ -3409,11 +3415,11 @@
</li>
<li class="md-nav__item">
<a href="#_27" class="md-nav__link">
通用总线参数
<a href="#_28" class="md-nav__link">
常见的总线参数
</a>
<nav class="md-nav" aria-label="通用总线参数">
<nav class="md-nav" aria-label="常见的总线参数">
<ul class="md-nav__list">
<li class="md-nav__item">
@ -3425,7 +3431,7 @@
<li class="md-nav__item">
<a href="#i2c" class="md-nav__link">
通用 I2C 设置
常见的I2C 设置
</a>
</li>
@ -3454,7 +3460,7 @@
<h1 id="_1">配置参考<a class="headerlink" href="#_1" title="Permanent link">&para;</a></h1>
<p>本文档是 Klipper 配置文件中可用配置分段的参考。</p>
<p>本文档中的描述已经格式化,以便可以将它们剪切并粘贴到打印机配置文件中。 见 <a href="Installation.html">installation document</a> 有关设置 Klipper 和选择初始配置文件的信息。</p>
<p>本文档中的描述已经格式化,以便可以将它们剪切并粘贴到打印机配置文件中。 见 <a href="Installation.html">安装文档</a> 有关设置 Klipper 和选择初始配置文件的信息。</p>
<h2 id="_2">微控制器配置<a class="headerlink" href="#_2" title="Permanent link">&para;</a></h2>
<h3 id="_3">微控制器引脚名字的格式<a class="headerlink" href="#_3" title="Permanent link">&para;</a></h3>
<p>许多配置选项需要微控制器引脚的名称。Klipper 使用了这些引脚的硬件名称 - 例如<code>PA4</code></p>
@ -3491,13 +3497,13 @@ serial:
# communicates over a serial port, &#39;command&#39; otherwise.
</code></pre></div>
<h3 id="mcu-mcu-my_extra_mcu">额外的mcu [mcu my_extra_mcu]<a class="headerlink" href="#mcu-mcu-my_extra_mcu" title="Permanent link">&para;</a></h3>
<h3 id="mcu-my_extra_mcu">[mcu my_extra_mcu]<a class="headerlink" href="#mcu-my_extra_mcu" title="Permanent link">&para;</a></h3>
<p>额外的微控制器可以定义任意数量的带有“mcu”前缀的部分。 额外的微控制器引入了额外的引脚,这些引脚可以配置为加热器、步进器、风扇等。例如,如果引入了“[mcu extra_mcu]”部分那么诸如“extra_mcu:ar9”之类的引脚就可以在其他地方使用 在配置中其中“ar9”是给定 mcu 上的硬件引脚名称或别名)。</p>
<div class="highlight"><pre><span></span><code>[mcu my_extra_mcu]
# 请参阅&quot;mcu&quot;分段的配置参数。
</code></pre></div>
<h2 id="_4">的运动学设置<a class="headerlink" href="#_4" title="Permanent link">&para;</a></h2>
<h2 id="_4">的运动学设置<a class="headerlink" href="#_4" title="Permanent link">&para;</a></h2>
<h3 id="printer">[printer]<a class="headerlink" href="#printer" title="Permanent link">&para;</a></h3>
<p>打印机控制的高级设置部分。</p>
<div class="highlight"><pre><span></span><code>[printer]
@ -3607,7 +3613,7 @@ position_max:
</code></pre></div>
<h3 id="_5">笛卡尔运动学<a class="headerlink" href="#_5" title="Permanent link">&para;</a></h3>
<p>有关示例笛卡尔运动学配置文件,请参阅 <a href="https://github.com/Klipper3d/klipper/blob/master/config/example-cartesian.cfg">example-cartesian.cfg</a></p>
<p>cartesian 运动学配置文件参考<a href="https://github.com/Klipper3d/klipper/blob/master/config/example-cartesian.cfg">example-cartesian.cfg</a></p>
<p>此处描述的参数只适用于笛卡尔打印机,有关可用参数,请参阅 <a href="#common-kinematic-settings">常用运动设置</a></p>
<div class="highlight"><pre><span></span><code>[printer]
kinematics: cartesian
@ -3635,7 +3641,7 @@ max_z_accel:
</code></pre></div>
<h3 id="_6">线性三角洲运动学<a class="headerlink" href="#_6" title="Permanent link">&para;</a></h3>
<p>有关示例线性三角洲运动学配置文件,请参阅 <a href="https://github.com/Klipper3d/klipper/blob/master/config/example-delta.cfg">example-delta.cfg</a>有关校准的信息,请参阅 <a href="Delta_Calibrate.html">三角洲校准指南</a></p>
<p>linear delta运动学配置文件参考<a href="https://github.com/Klipper3d/klipper/blob/master/config/example-delta.cfg">example-delta.cfg</a>关于校准方法 <a href="Delta_Calibrate.html">三角洲校准指南</a></p>
<p>此处仅描述了线性三角洲打印机的特定参数 - 有关可用参数,请参阅 <a href="#common-kinematic-settings">常用运动设置</a></p>
<div class="highlight"><pre><span></span><code>[printer]
kinematics: delta
@ -3712,7 +3718,7 @@ radius:
</code></pre></div>
<h3 id="corexy">CoreXY 运动学<a class="headerlink" href="#corexy" title="Permanent link">&para;</a></h3>
<p>See <a href="https://github.com/Klipper3d/klipper/blob/master/config/example-corexy.cfg">example-corexy.cfg</a> for an example corexy (and h-bot) kinematics file.</p>
<p>corexy或者h-bot运动学配置文件参考<a href="./config/example-corexy.cfg">example-corexy.cfg</a></p>
<p>这里只描述了 CoreXY 打印机特有的参数 -- 有关可用参数,请参阅 <a href="#common-kinematic-settings">常见运动学设置</a></p>
<div class="highlight"><pre><span></span><code>[printer]
kinematics: corexy
@ -3740,7 +3746,7 @@ max_z_accel:
</code></pre></div>
<h3 id="corexy_1">CoreXY 运动学<a class="headerlink" href="#corexy_1" title="Permanent link">&para;</a></h3>
<p>See <a href="https://github.com/Klipper3d/klipper/blob/master/config/example-corexz.cfg">example-corexz.cfg</a> for an example corexz kinematics config file.</p>
<p>corexz 运动学配置文件参考<a href="https://github.com/Klipper3d/klipper/blob/master/config/example-corexz.cfg">example-corexz.cfg</a></p>
<p>此处描述的参数只适用于笛卡尔打印机—有关全部可用参数,请参阅 <a href="#common-kinematic-settings">常用的运动学设置</a></p>
<div class="highlight"><pre><span></span><code>[printer]
kinematics: corexz
@ -3764,8 +3770,8 @@ max_z_accel:
[stepper_z]
</code></pre></div>
<h3 id="corexy_2">混合型 CoreXY 运动学<a class="headerlink" href="#corexy_2" title="Permanent link">&para;</a></h3>
<p>See <a href="https://github.com/Klipper3d/klipper/blob/master/config/example-hybrid-corexy.cfg">example-hybrid-corexy.cfg</a> for an example hybrid corexy kinematics config file.</p>
<h3 id="hybrid-corexy-corexy">Hybrid-CoreXY (混合型 CoreXY) 运动学<a class="headerlink" href="#hybrid-corexy-corexy" title="Permanent link">&para;</a></h3>
<p>hybrid corexy运动学配置文件参考<a href="https://github.com/Klipper3d/klipper/blob/master/config/example-hybrid-corexy.cfg">example-hybrid-corexy.cfg</a></p>
<p>This kinematic is also known as Markforged kinematic.</p>
<p>此处仅描述了线性三角洲打印机的特定参数—有关全部可用参数,请参阅 <a href="#common-kinematic-settings">常用的运动学设置</a></p>
<div class="highlight"><pre><span></span><code>[printer]
@ -3790,8 +3796,8 @@ max_z_accel:
[stepper_z]
</code></pre></div>
<h3 id="corexz">混合型 CoreXZ 运动学<a class="headerlink" href="#corexz" title="Permanent link">&para;</a></h3>
<p>See <a href="https://github.com/Klipper3d/klipper/blob/master/config/example-hybrid-corexz.cfg">example-hybrid-corexz.cfg</a> for an example hybrid corexz kinematics config file.</p>
<h3 id="hybrid-corexz-corexz">Hybrid-CoreXZ (混合型 CoreXZ) 运动学<a class="headerlink" href="#hybrid-corexz-corexz" title="Permanent link">&para;</a></h3>
<p>hybrid corexz 运动学配置文件参考 <a href="https://github.com/Klipper3d/klipper/blob/master/config/example-hybrid-corexz.cfg">example-hybrid-corexz.cfg</a></p>
<p>This kinematic is also known as Markforged kinematic.</p>
<p>此处仅描述了线性三角洲打印机的特定参数—有关全部可用参数,请参阅 <a href="#common-kinematic-settings">常用的运动学设置</a></p>
<div class="highlight"><pre><span></span><code>[printer]
@ -3817,7 +3823,7 @@ max_z_accel:
</code></pre></div>
<h3 id="_7">极坐标运动学<a class="headerlink" href="#_7" title="Permanent link">&para;</a></h3>
<p>See <a href="https://github.com/Klipper3d/klipper/blob/master/config/example-polar.cfg">example-polar.cfg</a> for an example polar kinematics config file.</p>
<p>polar运动学配置文件参考 <a href="https://github.com/Klipper3d/klipper/blob/master/config/example-polar.cfg">example-polar.cfg</a></p>
<p>这里只描述了极地打印机特有的参数—全部可用的参数请见<a href="#common-kinematic-settings">常用的运动学设置</a></p>
<p>POLAR KINEMATICS ARE A WORK IN PROGRESS. Moves around the 0, 0 position are known to not work properly.</p>
<div class="highlight"><pre><span></span><code>[printer]
@ -3850,10 +3856,10 @@ gear_ratio:
[stepper_z]
</code></pre></div>
<h3 id="rotary-delta-kinematics">Rotary delta Kinematics<a class="headerlink" href="#rotary-delta-kinematics" title="Permanent link">&para;</a></h3>
<p>See <a href="https://github.com/Klipper3d/klipper/blob/master/config/example-rotary-delta.cfg">example-rotary-delta.cfg</a> for an example rotary delta kinematics config file.</p>
<h3 id="rotary-delta">Rotary delta 运动学<a class="headerlink" href="#rotary-delta" title="Permanent link">&para;</a></h3>
<p>Rotary Delta运动学配置文件参考<a href="https://github.com/Klipper3d/klipper/blob/master/config/example-rotary-delta.cfg">example-rotary-delta.cfg</a></p>
<p>此处仅介绍特定于旋转三角洲打印机的参数—有关可用参数,请参阅<a href="#common-kinematic-settings">常用的运动学设置</a></p>
<p>ROTARY DELTA KINEMATICS ARE A WORK IN PROGRESS. Homing moves may timeout and some boundary checks are not implemented.</p>
<p>ROTARY DELTA运动学正在进行的修复工作。归位动作可能会超时并且一些边界检查也没有实现。</p>
<div class="highlight"><pre><span></span><code>[printer]
kinematics: rotary_delta
max_z_velocity:
@ -3934,7 +3940,7 @@ radius:
<h3 id="_8">缆绳绞盘运动学<a class="headerlink" href="#_8" title="Permanent link">&para;</a></h3>
<p>See the <a href="https://github.com/Klipper3d/klipper/blob/master/config/example-winch.cfg">example-winch.cfg</a> for an example cable winch kinematics config file.</p>
<p>这里只描述了缆绳铰盘式打印机特有的参数 — 全部可用的参数见<a href="#common-kinematic-settings">常用的运动学设置</a></p>
<p>CABLE WINCH SUPPORT IS EXPERIMENTAL. Homing is not implemented on cable winch kinematics. In order to home the printer, manually send movement commands until the toolhead is at 0, 0, 0 and then issue a <code>G28</code> command.</p>
<p>缆绳铰盘支持是实验性的。归位在缆绳绞盘运动学中没有实现。在打印机归位时需要手动发送运动指令将工具头处于0, 0, 0位置然后发出<code>G28</code>归位。</p>
<div class="highlight"><pre><span></span><code>[printer]
kinematics: winch
@ -3963,7 +3969,7 @@ max_accel: 1
# values are not used for &quot;none&quot; kinematics.
</code></pre></div>
<h2 id="_10">通用挤出机和热床支持<a class="headerlink" href="#_10" title="Permanent link">&para;</a></h2>
<h2 id="_10">常见的挤出机和热床支持<a class="headerlink" href="#_10" title="Permanent link">&para;</a></h2>
<h3 id="extruder">[extruder]<a class="headerlink" href="#extruder" title="Permanent link">&para;</a></h3>
<p>The extruder section is used to describe the heater parameters for the nozzle hotend along with the stepper controlling the extruder. See the <a href="G-Codes.html#extruder">command reference</a> for additional information. See the <a href="Pressure_Advance.html">pressure advance guide</a> for information on tuning pressure advance.</p>
<div class="highlight"><pre><span></span><code>[extruder]
@ -4242,34 +4248,33 @@ max_temp:
<p>Tool to help adjust bed leveling screws. One may define a [bed_screws] config section to enable a BED_SCREWS_ADJUST g-code command.</p>
<p>See the <a href="Manual_Level.html#adjusting-bed-leveling-screws">leveling guide</a> and <a href="G-Codes.html#bed_screws">command reference</a> for additional information.</p>
<div class="highlight"><pre><span></span><code>[bed_screws]
#screw1
# 第一颗打印机调平螺丝的X,Y坐标。这是将命令喷嘴移动到螺丝正
# 上方时的位置(或在床上方时尽可能接近的位置)。
# 必须提供此参数。
#screw1_name
# 给定螺丝的名称。当调平助手脚本运行时会使用该名称。
# 默认值是螺丝的 XY 位置
#screw1_fine_adjust
# 用于精细调整第一颗调平螺丝时的喷嘴被命令移动到的X,Y坐标。
# 默认值为不执行对打印床螺丝的精细调整。
#screw2
#screw2_name
#screw2_fine_adjust
#screw1:
# 第一颗打印机调平螺丝的X,Y坐标。这是将命令喷嘴移动到螺丝正
# 上方时的位置(或在床上方时尽可能接近的位置)。
# 必须提供此参数。
#screw1_name:
# 给定螺丝的名称。当调平助手脚本运行时会使用该名称。
# 默认值是螺丝的 XY 位置
#screw1_fine_adjust:
# 用于精细调整第一颗调平螺丝时的喷嘴被命令移动到的X,Y坐标。
# 默认值为不执行对打印床螺丝的精细调整。
#screw2:
#screw2_name:
#screw2_fine_adjust:
#...
# 额外的调平螺丝。
# 至少必须定义三个螺丝
#horizontal_move_z 5
# 打印头在两个螺丝位置间移动时应被命令移动到的高度(以毫米为单位)
# 默认值为 5。
#probe_height 0
# 探针高度(毫米)在打印床和热端热膨胀后探针的高度。
# 默认值为零。
#speed 50
# 校准过程中非探测移动的速度(以毫米/秒为单位)。
# 默认值为 50。
#probe_speed 5
# 从 horizontal_move_z 位置移动到 probe_height 位置的速度(以毫米/秒为单位)。
# 默认值为 5。
# 可以有而外的调平螺丝但是至少需要3个
#horizontal_move_z: 5
# 打印头在两个点之间移动时候的高度
# 默认值为 5
#probe_height: 0
# 探针高度 (mm) 在打印床和热端热膨胀后探针的高度。
# 默认值为 0
#speed: 50
# 校准过程中非探测移动的速度 (mm/s)
# 默认值为 50
#probe_speed: 5
# 从 horizontal_move_z 位置移动到 probe_height 位置的速度 (mm/s)
# 默认值为 5
</code></pre></div>
<h3 id="screws_tilt_adjust">[screws_tilt_adjust]<a class="headerlink" href="#screws_tilt_adjust" title="Permanent link">&para;</a></h3>
@ -4546,28 +4551,28 @@ path:
</code></pre></div>
<h3 id="pause_resume">[pause_resume]<a class="headerlink" href="#pause_resume" title="Permanent link">&para;</a></h3>
<p>Pause/Resume functionality with support of position capture and restore. See the <a href="G-Codes.html#pause_resume">command reference</a> for more information.</p>
<p>暂停/恢复功能,支持位置储存和恢复。更多信息见<a href="G-Code.md#pause_resume">命令参考</a></p>
<div class="highlight"><pre><span></span><code>[pause_resume]
#recover_velocity: 50.
# 当捕捉/恢复功能被启用时,返回到捕获的位置的速度(单位:毫米/秒)。
# 默认为50.0 mm/s。
# 当捕捉/恢复功能被启用时,返回到捕获的位置的速度(单位:毫米/秒)。
# 默认为50.0 mm/s。
</code></pre></div>
<h3 id="firmware_retraction">[firmware_retraction]<a class="headerlink" href="#firmware_retraction" title="Permanent link">&para;</a></h3>
<p>Firmware filament retraction. This enables G10 (retract) and G11 (unretract) GCODE commands issued by many slicers. The parameters below provide startup defaults, although the values can be adjusted via the SET_RETRACTION <a href="G-Codes.html#firmware_retraction">command</a>), allowing per-filament settings and runtime tuning.</p>
<div class="highlight"><pre><span></span><code>[firmware_retraction]
#retract_length: 0
# 当 G10 被运行时回抽的长度(以毫米(mm)为单位)
# 和当 G11 被运行时退回的长度(但同时也包括
# 以下的unretract_extra_length
# 默认为0毫米。
# 当 G10 被运行时回抽的长度(以毫米(mm)为单位)
# 和当 G11 被运行时退回的长度(但同时也包括
# 以下的unretract_extra_length
# 默认为0毫米。
#retract_speed: 20
# 回抽速度,以毫米每秒(mm/s)为单位。默认为每秒20毫米。
# 回抽速度,以毫米每秒(mm/s)为单位。默认为每秒20毫米。
#unretract_extra_length: 0
# 退回时增加*额外*长度(以毫米(mm)为单位)的耗材。
# 退回时增加*额外*长度(以毫米(mm)为单位)的耗材。
#unretract_speed: 10
# 退回速度,以毫米(mm)为单位。
# 默认为每秒10毫米
# 退回速度,以毫米(mm)为单位。
# 默认值为10mm/s
</code></pre></div>
<h3 id="gcode_arcs">[gcode_arcs]<a class="headerlink" href="#gcode_arcs" title="Permanent link">&para;</a></h3>
@ -4731,7 +4736,7 @@ pins:
# 必须提供此参数。
</code></pre></div>
<h2 id="_15">打印床探测硬件<a class="headerlink" href="#_15" title="Permanent link">&para;</a></h2>
<h2 id="_15">床探测硬件<a class="headerlink" href="#_15" title="Permanent link">&para;</a></h2>
<h3 id="probe">[probe]<a class="headerlink" href="#probe" title="Permanent link">&para;</a></h3>
<p>Z height probe. One may define this section to enable Z height probing hardware. When this section is enabled, PROBE and QUERY_PROBE extended <a href="G-Codes.html#probe">g-code commands</a> become available. Also, see the <a href="Probe_Calibrate.html">probe calibrate guide</a>. The probe section also creates a virtual "probe:z_virtual_endstop" pin. One may set the stepper_z endstop_pin to this virtual pin on cartesian style printers that use the probe in place of a z endstop. If using "probe:z_virtual_endstop" then do not define a position_endstop in the stepper_z config section.</p>
<div class="highlight"><pre><span></span><code>[probe]
@ -4862,7 +4867,7 @@ control_pin:
<h3 id="extruder1">[extruder1]<a class="headerlink" href="#extruder1" title="Permanent link">&para;</a></h3>
<p>在一个多挤出机的打印机中,为每个额外的挤出机添加一个额外挤出机分段。额外挤出机分段应被命名为"extruder1"、"extruder2"、"extruder3",以此类推。有关可用参数,参见"extruder"章节。</p>
<p>See <a href="https://github.com/Klipper3d/klipper/blob/master/config/sample-multi-extruder.cfg">sample-multi-extruder.cfg</a> for an example configuration.</p>
<p>多挤出机参考示例<a href="https://github.com/Klipper3d/klipper/blob/master/config/sample-multi-extruder.cfg">sample-multi-extruder.cfg</a></p>
<div class="highlight"><pre><span></span><code>[extruder1]
#step_pin:
#dir_pin:
@ -4875,7 +4880,7 @@ control_pin:
<h3 id="dual_carriage">[dual_carriage]<a class="headerlink" href="#dual_carriage" title="Permanent link">&para;</a></h3>
<p>Support for cartesian printers with dual carriages on a single axis. The active carriage is set via the SET_DUAL_CARRIAGE extended g-code command. The "SET_DUAL_CARRIAGE CARRIAGE=1" command will activate the carriage defined in this section (CARRIAGE=0 will return activation to the primary carriage). Dual carriage support is typically combined with extra extruders - the SET_DUAL_CARRIAGE command is often called at the same time as the ACTIVATE_EXTRUDER command. Be sure to park the carriages during deactivation.</p>
<p>See <a href="https://github.com/Klipper3d/klipper/blob/master/config/sample-idex.cfg">sample-idex.cfg</a> for an example configuration.</p>
<p>Idex参考示例<a href="https://github.com/Klipper3d/klipper/blob/master/config/sample-idex.cfg">sample-idex.cfg</a></p>
<div class="highlight"><pre><span></span><code>[dual_carriage]
axis:
# 额外滑车所在的轴x或者y
@ -5092,7 +5097,7 @@ sensor_pin:
# The ADC voltage offset (in Volts). The default is 0.
</code></pre></div>
<h3 id="pt1000">直接连接PT1000 传感器<a class="headerlink" href="#pt1000" title="Permanent link">&para;</a></h3>
<h3 id="pt1000">直接连接PT1000 传感器<a class="headerlink" href="#pt1000" title="Permanent link">&para;</a></h3>
<p>直接连接到控制板的 PT1000 传感器。以下参数可用于使用这些传感器之一的加热器分段。</p>
<div class="highlight"><pre><span></span><code>sensor_type: PT1000
sensor_pin:
@ -5175,7 +5180,7 @@ sensor_pin:
</code></pre></div>
<h3 id="lm75">LM75 温度传感器<a class="headerlink" href="#lm75" title="Permanent link">&para;</a></h3>
<p>LM75/LM75A two wire (I2C) connected temperature sensors. These sensors have a range of -55~125 C, so are usable for e.g. chamber temperature monitoring. They can also function as simple fan/heater controllers.</p>
<p>LM75/LM75A两线I2C连接的温度传感器。这些传感器的温度范围为-55~125 C因此可用于例如试验室温度监测。它们还可以作为简单的风扇/加热器控制器使用。</p>
<div class="highlight"><pre><span></span><code>sensor_type: LM75
#i2c_address:
# Default is 72 (0x48). Normal range is 72-79 (0x48-0x4F) and the 3
@ -5490,7 +5495,7 @@ clock_pin:
</code></pre></div>
<h3 id="pca9533">[pca9533]<a class="headerlink" href="#pca9533" title="Permanent link">&para;</a></h3>
<p>PCA9533 LED支持。PCA9533 在 mightyboard上出现</p>
<p>PCA9533 LED支持。PCA9533 在mightyboard上使用</p>
<div class="highlight"><pre><span></span><code>[pca9533 my_pca9533]
#i2c_address: 98
# The i2c address that the chip is using on the i2c bus. Use 98 for
@ -5508,7 +5513,7 @@ clock_pin:
</code></pre></div>
<h3 id="pca9632">[pca9632]<a class="headerlink" href="#pca9632" title="Permanent link">&para;</a></h3>
<p>PCA9632 LED support. The PCA9632 is used on the FlashForge Dreamer.</p>
<p>PCA9632 LED支持。PCA9632在FlashForge Dreamer上使用。</p>
<div class="highlight"><pre><span></span><code>[pca9632 my_pca9632]
#i2c_address: 98
# The i2c address that the chip is using on the i2c bus. This may be
@ -5647,7 +5652,7 @@ pins:
</code></pre></div>
<h2 id="tmc-stepper-driver-configuration">TMC stepper driver configuration<a class="headerlink" href="#tmc-stepper-driver-configuration" title="Permanent link">&para;</a></h2>
<p>Configuration of Trinamic stepper motor drivers in UART/SPI mode. Additional information is in the <a href="TMC_Drivers.html">TMC Drivers guide</a> and in the <a href="G-Codes.html#tmcxxxx">command reference</a>.</p>
<p>在UART/SPI模式下配置Trinamic步进电机驱动器。其他信息在<a href="TMC_Drivers.html">TMC驱动程序指南</a><a href="G-Code.md#tmcxxxx">命令参考</a>中。</p>
<h3 id="tmc2130">[tmc2130]<a class="headerlink" href="#tmc2130" title="Permanent link">&para;</a></h3>
<p>通过 SPI 总线配置 TMC2130 步进电机驱动。要使用此功能请定义一个带有“tmc2130”前缀并后跟步进驱动配置分段相应名称的配置分段例如“[tmc2130 stepper_x]”)。</p>
<div class="highlight"><pre><span></span><code>[tmc2130 stepper_x]
@ -5964,7 +5969,7 @@ run_current:
# sensorless homing.
</code></pre></div>
<h2 id="run-time-stepper-motor-current-configuration">Run-time stepper motor current configuration<a class="headerlink" href="#run-time-stepper-motor-current-configuration" title="Permanent link">&para;</a></h2>
<h2 id="_23">运行时步进电机电流配置<a class="headerlink" href="#_23" title="Permanent link">&para;</a></h2>
<h3 id="ad5206">[ad5206]<a class="headerlink" href="#ad5206" title="Permanent link">&para;</a></h3>
<p>Statically configured AD5206 digipots connected via SPI bus (one may define any number of sections with an "ad5206" prefix).</p>
<div class="highlight"><pre><span></span><code>[ad5206 my_digipot]
@ -6085,7 +6090,7 @@ wiper:
# scale the &#39;wiper&#39; parameter.
</code></pre></div>
<h2 id="_23">显示屏支持<a class="headerlink" href="#_23" title="Permanent link">&para;</a></h2>
<h2 id="_24">显示屏支持<a class="headerlink" href="#_24" title="Permanent link">&para;</a></h2>
<h3 id="display">[display]<a class="headerlink" href="#display" title="Permanent link">&para;</a></h3>
<p>Support for a display attached to the micro-controller.</p>
<div class="highlight"><pre><span></span><code>[display]
@ -6308,7 +6313,7 @@ text:
</code></pre></div>
<h3 id="display_template">[display_template]<a class="headerlink" href="#display_template" title="Permanent link">&para;</a></h3>
<p>Display data text "macros" (one may define any number of sections with a display_template prefix). See the <a href="Command_Templates.html">command templates</a> document for information on template evaluation.</p>
<p>显示数据文本"macros"可以定义任意数量的带有display_template前缀的部分。有关模板评估的信息请参阅<a href="Command_Templates.html">命令模板</a>文件。</p>
<p>This feature allows one to reduce repetitive definitions in display_data sections. One may use the builtin <code>render()</code> function in display_data sections to evaluate a template. For example, if one were to define <code>[display_template my_template]</code> then one could use <code>{ render('my_template') }</code> in a display_data section.</p>
<p>This feature can also be used for continuous LED updates using the <a href="G-Codes.html#set_led_template">SET_LED_TEMPLATE</a> command.</p>
<div class="highlight"><pre><span></span><code>[display_template my_template_name]
@ -6329,7 +6334,7 @@ text:
<h3 id="display_glyph">[display_glyph]<a class="headerlink" href="#display_glyph" title="Permanent link">&para;</a></h3>
<p>在支持自定义字形的显示器上显示一个自定义字形。给定的名称将被分配给给定的显示数据,然后可以在显示模板中通过用“波浪形(~)”符号包围的名称来引用,即 <code>~my_display_glyph~</code></p>
<p>See <a href="https://github.com/Klipper3d/klipper/blob/master/config/sample-glyphs.cfg">sample-glyphs.cfg</a> for some examples.</p>
<p>更多示例 <a href="https://github.com/Klipper3d/klipper/blob/master/config/sample-glyphs.cfg">sample-glyphs.cfg</a></p>
<div class="highlight"><pre><span></span><code>[display_glyph my_display_glyph]
#data:
# 被存储为16 行,每行 16 位1位代表1个像素的显示数据。“.”是一个
@ -6420,7 +6425,7 @@ text:
# 被视为模板。点击按钮会进入或退出修改模式。
</code></pre></div>
<h2 id="_24">耗材传感器<a class="headerlink" href="#_24" title="Permanent link">&para;</a></h2>
<h2 id="_25">耗材传感器<a class="headerlink" href="#_25" title="Permanent link">&para;</a></h2>
<h3 id="filament_switch_sensor">[filament_switch_sensor]<a class="headerlink" href="#filament_switch_sensor" title="Permanent link">&para;</a></h3>
<p>耗材开关传感器。支持使用开关传感器(如限位开关)进行耗材插入和耗尽检测。</p>
<p>See the <a href="G-Codes.html#filament_switch_sensor">command reference</a> for more information.</p>
@ -6536,7 +6541,7 @@ adc2:
# 关于上述参数的描述请参见&quot;filament_switch_sensor&quot;章节。
</code></pre></div>
<h2 id="_25">控制板特定硬件支持<a class="headerlink" href="#_25" title="Permanent link">&para;</a></h2>
<h2 id="_26">控制板特定硬件支持<a class="headerlink" href="#_26" title="Permanent link">&para;</a></h2>
<h3 id="sx1509">[sx1509]<a class="headerlink" href="#sx1509" title="Permanent link">&para;</a></h3>
<p>将一个 SX1509 I2C 配置为 GPIO 扩展器。由于 I2C 通信本身的延迟,不应将 SX1509 引脚用作步进电机的 enable (启用)、step步进或 dir (方向)引脚或任何其他需要快速 bit-banging位拆裂的引脚。它们最适合用作静态或G代码控制的数字输出或硬件 pwm 引脚例如风扇。可以使用“sx1509”前缀定义任意数量的分段。每个扩展器提供可用于打印机配置的一组 16 个引脚sx1509_my_sx1509:PIN_0 到 sx1509_my_sx1509:PIN_15</p>
<p>See the <a href="https://github.com/Klipper3d/klipper/blob/master/config/generic-duet2-duex.cfg">generic-duet2-duex.cfg</a> file for an example.</p>
@ -6592,7 +6597,7 @@ vssa_pin:
</code></pre></div>
<h3 id="replicape">[replicape]<a class="headerlink" href="#replicape" title="Permanent link">&para;</a></h3>
<p>Replicape support - see the <a href="Beaglebone.html">beaglebone guide</a> and the <a href="https://github.com/Klipper3d/klipper/blob/master/config/generic-replicape.cfg">generic-replicape.cfg</a> file for an example.</p>
<p>Replicape支持 - 参考<a href="Beaglebone.html">beaglebone guide</a><a href="./config/generic-replicape.cfg">generic-replicape.cfg</a></p>
<div class="highlight"><pre><span></span><code># The &quot;replicape&quot; config section adds &quot;replicape:stepper_x_enable&quot;
# virtual stepper enable pins (for steppers X, Y, Z, E, and H) and
# &quot;replicape:power_x&quot; PWM output pins (for hotbed, e, h, fan0, fan1,
@ -6652,7 +6657,7 @@ host_mcu:
# (True sets CFG5 high, False sets it low). The default is True.
</code></pre></div>
<h2 id="_26">其他自定义模块<a class="headerlink" href="#_26" title="Permanent link">&para;</a></h2>
<h2 id="_27">其他自定义模块<a class="headerlink" href="#_27" title="Permanent link">&para;</a></h2>
<h3 id="palette2">[palette2]<a class="headerlink" href="#palette2" title="Permanent link">&para;</a></h3>
<p>Palette 2 多材料支持 - 提供更紧密的集成,支持处于连接模式的 Palette 2 设备。</p>
<p>This modules also requires <code>[virtual_sdcard]</code> and <code>[pause_resume]</code> for full functionality.</p>
@ -6680,30 +6685,28 @@ serial:
<p>Magnetic hall angle sensor support for reading stepper motor angle shaft measurements using a1333, as5047d, or tle5012b SPI chips. The measurements are available via the <a href="API_Server.html">API Server</a> and <a href="Debugging.html#motion-analysis-and-data-logging">motion analysis tool</a>. See the <a href="G-Codes.html#angle">G-Code reference</a> for available commands.</p>
<div class="highlight"><pre><span></span><code>[angle my_angle_sensor]
sensor_type:
# The type of the magnetic hall sensor chip. Available choices are
# &quot;a1333&quot;, &quot;as5047d&quot;, and &quot;tle5012b&quot;. This parameter must be
# specified.
# 磁性霍尔传感器芯片的类型。
# 可用的选择是 &quot;a1333&quot; &quot;as5047d &quot;&quot;tle5012b&quot;
# 这个参数必须被指定。
#sample_period: 0.000400
# The query period (in seconds) to use during measurements. The
# default is 0.000400 (which is 2500 samples per second).
# 测量时使用的查询周期(以秒为单位)。
# 默认值是 0.000400 每秒钟2500个样本
#stepper:
# The name of the stepper that the angle sensor is attached to (eg,
# &quot;stepper_x&quot;). Setting this value enables an angle calibration
# tool. To use this feature, the Python &quot;numpy&quot; package must be
# installed. The default is to not enable angle calibration for the
# angle sensor.
# 角度传感器连接的步进电机名称(例如,&quot;stepper_x&quot;)。
# 设置这个值可以启用一个角度校准工具
# 要使用这个功能需要安装Python &quot;numpy &quot;包。
# 默认是不启用角度传感器的角度校准。
cs_pin:
# The SPI enable pin for the sensor. This parameter must be provided.
# 传感器的SPI引脚。必须提供此参数。
#spi_speed:
#spi_bus:
#spi_software_sclk_pin:
#spi_software_mosi_pin:
#spi_software_miso_pin:
# See the &quot;common SPI settings&quot; section for a description of the
# above parameters.
# 有关上述参数的描述,参考 &quot;common SPI settings &quot;
</code></pre></div>
<h2 id="_27">通用总线参数<a class="headerlink" href="#_27" title="Permanent link">&para;</a></h2>
<h2 id="_28">常见的总线参数<a class="headerlink" href="#_28" title="Permanent link">&para;</a></h2>
<h3 id="spi">常见 SPI 设置<a class="headerlink" href="#spi" title="Permanent link">&para;</a></h3>
<p>The following parameters are generally available for devices using an SPI bus.</p>
<div class="highlight"><pre><span></span><code>#spi_speed:
@ -6722,7 +6725,7 @@ cs_pin:
# &quot;software spi&quot;.
</code></pre></div>
<h3 id="i2c">通用 I2C 设置<a class="headerlink" href="#i2c" title="Permanent link">&para;</a></h3>
<h3 id="i2c">常见的I2C 设置<a class="headerlink" href="#i2c" title="Permanent link">&para;</a></h3>
<p>The following parameters are generally available for devices using an I2C bus.</p>
<div class="highlight"><pre><span></span><code>#i2c_address:
# 设备的 I2C 地址。必须是一个十进制数字(而不是十六进制)。