摘要：【中文】本发明提供一种玻璃窑炉烟气混合装置及混合方法，结构简单，设计合理，确保了高温烟气不偏移，放置烟气混合不匀，有效保证设备安全运行。所述玻璃窑炉烟气混合装置包括环形结构装置；所述环形结构装置呈环形圆管设置，环形圆管的环形中心形成高温烟气通道，环形圆管的外侧设置低温空气入口，内侧沿环形圆周方向呈阵列设置有若干低温空气出口；所述低温空气入口与环形圆管的外侧通过平滑过渡结构连接成一体。利用环形圆管同轴线嵌套固定在烟气管道内，与高温烟气管道呈一体，提高了工作效率。环形圆管的外侧设置低温空气入口，方便低温空气的进入；内侧沿环形圆周方向呈阵列设置有若干低温空气出口，方便低温空气的排除，并与高温烟气有效混合。 【EN】The invention provides a glass kiln flue gas mixing device and a mixing method, which have the advantages of simple structure and reasonable design, ensure that high-temperature flue gas is not deviated, the placed flue gas is not uniformly mixed, and effectively ensure the safe operation of equipment. The glass kiln flue gas mixing device comprises an annular structure device; the annular structure device is arranged in an annular round pipe, a high-temperature flue gas channel is formed in the annular center of the annular round pipe, a low-temperature air inlet is formed in the outer side of the annular round pipe, and a plurality of low-temperature air outlets are formed in the inner side of the annular round pipe in an array manner along the annular circumferential direction; the low-temperature air inlet is connected with the outer side of the annular circular tube into a whole through a smooth transition structure. The annular circular tube is coaxially nested and fixed in the flue gas pipeline and is integrated with the high-temperature flue gas pipeline, so that the working efficiency is improved. A low-temperature air inlet is formed in the outer side of the annular circular tube, so that low-temperature air can conveniently enter the annular circular tube; the inner side is provided with a plurality of low-temperature air outlets in an array along the annular circumferential direction, so that the low-temperature air is conveniently discharged and is effectively mixed with high-temperature flue gas.

摘要：【中文】本发明提供一种用于测试电子玻璃表面硬度的装置，操作简单，测试装置通过滑块移动装置，连续在不同压力下测试，提高测量精度，减少人为误差。所述用于测试电子玻璃表面硬度的装置包括测试杆、测试头和承重平台；所述测试杆呈圆柱状，底端连接测试头的连接端；所述测试头的测试端呈圆弧形笔头设置；所述测试头的测试端与电子玻璃表面为圆弧形点接触；所述称重台垂直设置在测试杆上，与测试杆呈一体状；所述还包括固定架、连接杆、滑块、手柄、轨道、机架和竖杆；所述固定架呈长方体状，固定架套入测试杆，固定架通过连接杆与滑块连接；所述轨道水平穿过滑块，轨道的两端通过竖杆固定在机架上；所述手柄设置在滑块上。 【EN】The invention provides a device for testing the surface hardness of electronic glass, which is simple to operate, and the testing device continuously tests under different pressures through a sliding block moving device, thereby improving the measuring precision and reducing the human error. The device for testing the surface hardness of the electronic glass comprises a testing rod, a testing head and a bearing platform; the testing rod is cylindrical, and the bottom end of the testing rod is connected with the connecting end of the testing head; the testing end of the testing head is arranged in an arc-shaped pen point; the testing end of the testing head is in contact with the arc-shaped point on the surface of the electronic glass; the weighing platform is vertically arranged on the test rod and is integrated with the test rod; the device also comprises a fixed frame, a connecting rod, a sliding block, a handle, a track, a rack and a vertical rod; the fixed frame is in a cuboid shape, the test rod is sleeved in the fixed frame, and the fixed frame is connected with the sliding block through the connecting rod; the rail horizontally penetrates through the sliding block, and two ends of the rail are fixed on the rack through vertical rods; the handle is arranged on the sliding block.

摘要：【中文】本发明公开了一种控制短辊角速度的方法及系统，能够实时控制辊子的角速度，从而保证辊子间的线速度相同，保证玻璃的品质。包括以下步骤；1.检测固定辊的起始半径R1和浮动辊的起始半径R2；2.玻璃带拉伸过程中，检测玻璃带的偏移量d1，和浮动辊的偏移量d2；玻璃带的偏移量d1为固定辊的磨损量，浮动辊的偏移量d2与玻璃带的偏移量d1的差值为浮动辊磨损量；3.计算固定辊磨损后的半径为R1‑d1，浮动辊磨损后的半径为R2‑；4.根据公式ω＝V/R，计算出目标角速度值ω；其中V为辊子需要的线速度；R为辊子的半径，即固定辊或浮动辊磨损后的半径；5.将固定辊或浮动辊的角速度调整到步骤四中计算得到的目标角速度值ω。 【EN】The invention discloses a method and a system for controlling the angular speed of a short roller, which can control the angular speed of the roller in real time, thereby ensuring the same linear speed among the rollers and ensuring the quality of glass. Comprises the following steps; 1. detecting the starting radius R1 of the fixed roller and the starting radius R2 of the floating roller; 2. detecting the offset d1 of the glass ribbon and the offset d2 of the floating roller during the stretching process of the glass ribbon; the offset d1 of the glass ribbon is the abrasion loss of the fixed roller, and the difference value between the offset d2 of the floating roller and the offset d1 of the glass ribbon is the abrasion loss of the floating roller; 3. calculating the worn radius of the fixed roller to be R1-d1 and the worn radius of the floating roller to be R2-; 4. calculating a target angular velocity value omega according to a formula omega-V/R; wherein V is the linear velocity required by the roller; r is the radius of the roller, namely the radius of the fixed roller or the floating roller after being worn; 5. and adjusting the angular speed of the fixed roller or the floating roller to the target angular speed value omega obtained by calculation in the fourth step.

摘要：【中文】一种检测平板玻璃板工作面微粒子的方法，包括以下步骤：步骤1：将平板玻璃板工作面朝上放置在检测台传输机上；步骤2：检测台传输机移动平板玻璃板朝线扫面相机方向传输；步骤3：光源发出的激光照射在平板玻璃板上，平板玻璃板上的工作面微粒子对激光发生漫反射，形成漫反射光，线扫面相机接受漫反射光，进行暗场成像，检测工作面微粒子的数量和大小；所述激光的入射角α不小于88°。所述步骤3中，线扫面相机接受中心线反射角θ范围为45°～48°的漫反射光。所述步骤3中，采用集光反射镜对漫反射光进行焦集，线扫面相机接受焦集后的漫反射光。该方法检测精度高，速度快，不受平板玻璃板厚度、翘曲和传输倾斜影响。 【EN】A method for detecting micro-particles on a working surface of a flat glass plate comprises the following steps of 1, placing the working surface of the flat glass plate on a detection table conveyor upwards, 2, moving the flat glass plate by the detection table conveyor to be conveyed towards a line scanning camera, 3, irradiating laser emitted by a light source on the flat glass plate, enabling the micro-particles on the working surface of the flat glass plate to diffuse and reflect the laser to form diffuse reflection light, enabling the line scanning camera to receive the diffuse reflection light to perform dark-field imaging, and detecting the quantity and the size of the micro-particles on the working surface, wherein the incident angle α of the laser is not smaller than 88 degrees, in the step 3, enabling the line scanning camera to receive the diffuse reflection light with a central line reflection angle theta range of 45-48 degrees, in the step 3, a light collecting reflector is adopted to focus the diffuse reflection light, and the line scanning camera receives the focused diffuse reflection light.

摘要：【中文】本发明一种溢流砖热变形载荷应力加载方法，包括如下步骤：1.对不同尺寸的溢流砖样品进行排序，排序分为最小尺寸溢流砖样品和若干大尺寸溢流砖样品；2.对最小尺寸溢流砖样品进行加热，以匀速升温至溢流砖工作温度后进行保温；在保温后的最小尺寸溢流砖样品上加入工作载荷应力，记录最小尺寸溢流砖样品在工作载荷应力作用下的标准弯曲变形量；3.对任一大尺寸溢流砖样品进行加热，在匀速升温至溢流砖工作温度后进行保温；在保温后的当前大尺寸溢流砖样品上以工作载荷应力为基准，逐步增加单位测试载荷应力，记录当前大尺寸溢流砖样品在载荷应力作用下的弯曲变形量；该方法在不同尺寸溢流砖上加入的应力，使不同尺寸溢流砖在不同应力下变形达到一致。 【EN】The invention relates to a thermal deformation load stress loading method for an overflow brick, which comprises the following steps: 1. sorting overflow brick samples of different sizes into a minimum size overflow brick sample and a plurality of large size overflow brick samples; 2. heating the overflow brick sample with the minimum size, raising the temperature to the working temperature of the overflow brick at a constant speed, and then preserving the heat; adding a working load stress on the minimum-size overflow brick sample after heat preservation, and recording the standard bending deformation of the minimum-size overflow brick sample under the action of the working load stress; 3. heating any large-size overflow brick sample, and preserving heat after uniformly heating to the working temperature of the overflow brick; gradually increasing unit test load stress on the heat-insulated current large-size overflow brick sample by taking the working load stress as a reference, and recording the bending deformation of the current large-size overflow brick sample under the action of the load stress; the method adds stress on the overflow bricks with different sizes, so that the overflow bricks with different sizes deform to be consistent under different stresses.

摘要：【中文】本发明提供一种平板玻璃瑕疵的抽检装置及方法，结构简单，操作方便，自动搬运玻璃并半自动用光学系统确认玻璃瑕疵，提高了玻璃瑕疵抽检工作效率和准确度。所述平板玻璃瑕疵的抽检装置，包括主机架，以及主机架上设置的光学检测装置和平板玻璃检测装置；主机架内从玻璃入口端依次设置工作机架检测区域和光学检测区域；光学检测装置位于光学检测区域，光学检测装置包括光学系统和滑动平台；光学系统固定在滑动平台的滑块上；平板玻璃检测装置位于工作机架检测区域，平板玻璃检测装置包括工作台、旋转驱动伺服电机、支撑滑块、旋转支架、升降移动驱动伺服电机和工作机架；工作机架两侧分别竖直设置有平行的轨道。 【EN】The invention provides a device and a method for spot inspection of plate glass, which have the advantages of simple structure and convenient operation, automatically carry glass, confirm the glass defects by a semi-automatic optical system and improve the working efficiency and accuracy of spot inspection of the glass defects. The spot inspection device for the sheet glass comprises a main frame, and an optical detection device and a sheet glass detection device which are arranged on the main frame; a working rack detection area and an optical detection area are sequentially arranged in the main rack from the glass inlet end; the optical detection device is positioned in the optical detection area and comprises an optical system and a sliding platform; the optical system is fixed on a sliding block of the sliding platform; the plate glass detection device is positioned in a detection area of the working rack and comprises a worktable, a rotary driving servo motor, a supporting slide block, a rotary bracket, a lifting movement driving servo motor and the working rack; parallel tracks are vertically arranged on two sides of the working rack respectively.

摘要：【中文】本发明公开了一种成型装置温度场的控制方法，1.设定两排加热器组中成对的两个加热器中心点为位置点，记为P1、P2…Pi，将成型装置中每个加热器功率固定，不同位置点的保温层厚度值L相同；2.选取多个位置点，逐渐增加所有加热器保温层厚度值L，检测在不同加热器的保温层厚度值L下，多个位置点处的不同温度值T；3.对同一位置点下逐渐增加的保温层厚度值L与对应的温度值T进行拟合，得到每个位置点下保温层厚度值L和温度值T的关系式A；4.将选取的每个位置点所需的目标温度值带入步骤三的关系式A中，得到选取的每个位置点对应的保温层厚度L`；5.将每个位置点设置为对应的保温层厚度值L`。 【EN】The invention discloses a control method of a temperature field of a forming device, which comprises the following steps of 1, setting central points of two paired heaters in two rows of heater groups as position points, marking as P1 and P2 … Pi, fixing the power of each heater in the forming device, and keeping the thickness values L of heat insulation layers at different position points to be the same; 2. selecting a plurality of position points, gradually increasing the thickness values L of the heat-insulating layers of all the heaters, and detecting different temperature values T at the plurality of position points under the thickness values L of the heat-insulating layers of different heaters; 3. fitting the gradually increased thickness value L of the insulating layer at the same position point with the corresponding temperature value T to obtain a relational expression A of the thickness value L of the insulating layer at each position point and the temperature value T; 4. bringing the target temperature value required by each selected position point into the relation A in the third step to obtain the thickness L' of the heat insulation layer corresponding to each selected position point; 5. and setting each position point as a corresponding thickness value L' of the heat preservation layer.