CN104463950A - Two-dimension code information identification method of furnace kiln refractory 3D model - Google Patents

Two-dimension code information identification method of furnace kiln refractory 3D model Download PDF

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CN104463950A
CN104463950A CN 201410598424 CN201410598424A CN104463950A CN 104463950 A CN104463950 A CN 104463950A CN 201410598424 CN201410598424 CN 201410598424 CN 201410598424 A CN201410598424 A CN 201410598424A CN 104463950 A CN104463950 A CN 104463950A
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model
dimensional code
refractory
information
key
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CN 201410598424
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Chinese (zh)
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贾立军
刘佳
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中冶天工集团有限公司
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    • GPHYSICS
    • G06COMPUTING; CALCULATING; COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F17/00Digital computing or data processing equipment or methods, specially adapted for specific functions
    • G06F17/50Computer-aided design
    • G06F17/5009Computer-aided design using simulation
    • G06F17/5036Computer-aided design using simulation for analog modelling, e.g. for circuits, spice programme, direct methods, relaxation methods
    • GPHYSICS
    • G06COMPUTING; CALCULATING; COUNTING
    • G06KRECOGNITION OF DATA; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
    • G06K19/00Record carriers for use with machines and with at least a part designed to carry digital markings
    • G06K19/06Record carriers for use with machines and with at least a part designed to carry digital markings characterised by the kind of the digital marking, e.g. shape, nature, code
    • G06K19/06009Record carriers for use with machines and with at least a part designed to carry digital markings characterised by the kind of the digital marking, e.g. shape, nature, code with optically detectable marking
    • G06K19/06046Constructional details
    • G06K19/06103Constructional details the marking being embedded in a human recognizable image, e.g. a company logo with an embedded two-dimensional code

Abstract

The invention provides a two-dimension code information identification method of a furnace kiln refractory 3D model. Firstly, the furnace kiln refractory 3D model is created, a large amount of information related to the 3D model is compiled to QR CODE two-dimension code electronic tags according to the design and construction needs, and the electronic tags are attached to the appointed portions of the furnace kiln refractory 3D model, wherein the information comprises the name, the material, weight, the storage location, time of putting in storage, time of delivery from storage, masonry requirements, construction procedure explanatory notes, related pictures, video connection and other content. In the construction process of refractory materials, the two-dimension codes can be scanned at any time through an intelligent terminal device (a smart phone or an IPAD), corresponding information is obtained, information sharing and interaction are achieved, and the information is updated in time. The identification method facilitates exchanging and popularization of the construction technology, the utilization rate of the 3D refractory model information is greatly improved, and the method becomes the link for efficiently connecting the refractory 3D information bank and people. The method has a good promotion function for application and popularization of the BIM technology in large-scale furnace building projects.

Description

一种炉窑耐材3D模型二维码信息标识方法 One kind of furnace refractories 3D model identification method QR code

技术领域 FIELD

[0001] 本发明属于建筑施工技术领域,尤其是涉及一种炉窑耐材3D模型二维码信息标识方法。 [0001] The present invention belongs to the technical field of building construction, particularly to a 3D model of the kiln refractory QR code identification method.

背景技术 Background technique

[0002] 大型炉体构造复杂,砌筑耐材型号种类繁多。 [0002] large furnace complex structure, masonry Refractories large variety of models. 由于计算机硬件及作息技术的快速发展,应用BIM技术进行炉窑工程进行3D模拟砌筑,与过去照图直接砌筑相比,不仅可以在工程策划阶段直观地反应工程重点难点,而且可对材料进行统计生成报表,这为施工管理提供很大便利。 Due to the rapid development of computer hardware and the rest of the technology, the application of BIM technology for 3D simulation furnace works masonry, compared with the past to FIG direct masonry, not only can intuitively reflect the key and difficult engineering project in the planning stage, but also on the material statistical reporting, which provides great convenience for the construction management. 基于此,3D模拟砌筑已越来越多地得到企业的认可。 Based on this, 3D simulation masonry has been increasingly recognized by businesses.

[0003]目前,由于砌筑三维建模软件专业针对性不是很强,在创建耐材3D砌筑模型时,具体图元只能携带模型名称、尺寸、材质、数量等基本信息。 [0003] At present, due to the masonry of professional 3D modeling software targeted not very strong, when you create a refractory masonry 3D model, specific elements can only carry the model name, size, material, quantity and other basic information. 而对于工程施工的特殊节点,关键部位、特殊技术要求等,不能与3D模型绑定,或绑定不完整、不系统。 As for the construction of a particular node, key parts, special technical requirements, not with the 3D model binding, binding or incomplete, the system. 这就使得投入很大精力完成的3D模型信息携带量小,与其它文字资料,图片资料,视频资料不能快速有效连接,造成连接操作复杂,连接成本增加,不能整体反应施工体的综合信息。 This makes a lot of energy into complete 3D model information to carry small amounts, and other text data, images, data, video data can not be connected quickly and efficiently, resulting in complex connection operations, increase the connection cost, comprehensive information construction overall body can not react. 另外,3D模型本身无法用其它智能设备读取,信息共享范围狭窄。 Further, 3D models itself can not read with other intelligent devices, information sharing narrow range. 由于以上两点原因,3D模型信息利用率低。 For these two reasons, 3D models utilization rate information.

[0004] 炉窑砌筑施工所需要的3D模型,除了模拟预砌直观反应工程实际和材料统计外,还需要反应耐火材料在运输、仓储、砌筑等环节的可追溯性和特殊节点特殊部位的技术要求。 [0004] 3D model of the desired kiln masonry construction, in addition to pre-assemble intuitive reaction engineering simulation and actual statistical materials, but also need the reaction refractories transportation, storage, masonry and other aspects of special parts and special node traceability technical requirements.

[0005] 读取炉窑砌筑施工的3D模型信息手段越便捷,信息可传递的范围越大,才能更大限度地发挥3D模型的作用。 [0005] read furnace masonry construction 3D model information means more convenience, greater range of information can be transmitted to a greater extent play the role of a 3D model.

[0006] 二维码具有如下优点:1.信息容量大,可以把图片、声音、文字、指纹等可以数字化的信息进行编码并表示出来,其容量可以是一维码的数十倍。 [0006] The two-dimensional code has the following advantages: a large information capacity, it can be the digitized image information, sound, text, such as a fingerprint is encoded and represented, which may be several times the capacity of a one-dimensional code. 2.保密性强、抗损和纠错能力强,可有效记录大量信息,作为产品流通等信息的有效载体。 2. confidentiality, resistance to damage and the error correction capability, a large amount of information can be effectively recorded, information such as product flow effective carrier. 通过引入加密措施,具有保密性、防伪性好。 By introducing encryption, confidential, security is good. 3.成本低廉,通过二维码读写终端可简单方便的将二维码打印到产品外包装或者销售单上。 3. Low cost, simple and convenient two-dimensional code printed on the product packaging or sold by a single two-dimensional code reader terminal. 4.可靠性高。 4. high reliability. 它比普通条码译码错误率百万分之二要低得多,误码率不超过千万分之一。 It is much lower than the average rate millionths bar code decoding error, the error rate of no more than one in ten million.

[0007] 3D模型与二维码技术结合使用,通过QR CODE 二维码标签标识耐材3D模型的重点、难点及特殊部位。 [0007] 3D model of the two-dimensional code technology combination, by focusing on two-dimensional code tag identification QR CODE refractory 3D model, difficulties and special parts. 编码内容不仅涵盖模型基本信息,还能体现耐材的存储、运输、施工部位以及施工特殊技术要求等信息,将相关各施工信息点根据需要连接在一起,可大大增加3D模型的信息量与完整性。 Not only covers the basic information of the encoded content model, also reflect the information storage Refractories, transport, construction sites, and construction of special technical requirements, the relevant connection points of the construction according to the information required together, can greatly increase the amount of information and a complete 3D model sex. 且由于手机等智能终端设备的普及,现场施工人员可通过读取二维码标识信息的方式,抛开图和纸,迅速获取耐材进场、运输、存储和施工的全过程信息与追溯,完成信息互动与远程共享。 As the popularity of mobile phones and other intelligent terminal devices, site construction workers two-dimensional code by reading the identification information of the way, and put aside FIGS paper, refractory rapid access approach, the entire process of traceability information transport, storage and construction, complete with a remote interactive information sharing. 且信息更新可即时更新及时发布。 And information updates can be instantly updated timely release.

发明内容 SUMMARY

[0008] 本发明要解决的问题是提供一种炉窑耐材3D模型二维码信息标识方法,解决了现有BIM技术在耐材施工应用中存在信息分散,利用率低及沟通不畅等实际问题。 [0008] The problem to be solved according to the present invention is to provide a 3D model of the kiln refractory QR code identification method, to solve the low utilization rate and poor BIM prior art construction Refractories dispersed in the presence information communication and other applications Practical problems.

[0009] 为解决上述技术问题,本发明采用的技术方案是:一种炉窑耐材3D模型二维码信息标识方法,包括如下步骤: [0009] To solve the above problems, the present invention adopts the technical solution is: A 3D model of refractory kiln QR code identification method, comprising the steps of:

[0010] ①创建3D耐材模型结构体系; [0010] ① refractory to create a 3D model architecture;

[0011] ②确定步骤①3D耐材模型结构中的若干关键点模型,编辑这些关键点模型信息; [0011] ② the step of determining the number of key points ①3D refractory model in the model structure, model information edit key;

[0012] ③将②中各个关键点模型的信息分别生成对应的二维码; [0012] ③ ② information in the key points of the model corresponding to generate two-dimensional code;

[0013] ④将步骤③生成的二维码图形载入到对应的关键点模型的指定位置; [0013] ④ the step of generating a two-dimensional code pattern ③ loaded to the specified position corresponding to the critical point of the model;

[0014] ⑤将步骤④中带有二维码的关键点模型上传至互联网云端或共享数据库平台; [0014] ⑤ ④ the key steps in the model with two-dimensional code sharing or uploaded to the Internet cloud database platform;

[0015] ⑥现场施工人员利用智能终端设备读取关键点模型信息,实现信息共享与互动。 [0015] ⑥ site construction workers use smart terminal device to read the key point model information, information sharing and interaction.

[0016] 进一步,步骤②中的关键点模型信息包括名称、材质、重量、库位、入库时间、出库时间、砌筑要求、施工工序文字说明,以及相关图片、模拟施工动画或现场视频的链接。 [0016] Further, the key point in the model step ② information including name, material, weight, location, storage time, leaving time, masonry requirements, the construction process text and picture, animation or live video simulation construction the link to.

[0017] 进一步,所述相关图片、模拟施工动画或现场视频的链接对应的的图片资料或视频资料预先存储到互联网云端或共享数据库平台。 [0017] Further, the picture, animation or construction site link analog video data corresponding to a picture or video data previously stored or shared to the Internet cloud database platform.

[0018] 进一步,步骤③中所述二维码的尺寸可以是2x2mm、4x4mm、6x6_或8x8_中的一种。 [0018] Further, in the step ③ said two-dimensional code may be a size 2x2mm, 4x4mm, one kind or 8x8_ the 6x6_.

[0019] 进一步,步骤③中所述二维码为QR CODE 二维码。 [0019] Further, the step ③ said two-dimensional code is QR CODE two-dimensional code.

[0020] 步骤②中确定3D耐材模型关键点的方法是,先分析图纸和三维模型,找出结构复杂、施工工序繁琐、需要要重点控制的节点作为BIM建模的关键点。 The method of determining the 3D model key points refractory [0020] In step ②, the drawings and three-dimensional model to analyze, identify complex structure, construction complicated process, it is necessary to focus on the point as a key control node BIM modeling.

[0021] 进一步,所述关键点模型包括水梁、人孔以及钢带运行线处的模型。 [0021] Further, the model includes a critical point of the water beam, a manhole and a model line of the steel strip.

[0022] 步骤④中将二维码图形载入到对应的关键点模型方法是: [0022] Step ④ in the two-dimensional code is loaded into graphical key method corresponding to the model is:

[0023] 第一步,将携有关键点模型信息的二维码制作成二维码截图; [0023] The first step, will carry a two-dimensional model code key information made into two-dimensional code shots;

[0024] 第二步,在BIM软件中选取炉窑耐材3D模型的关键点,进入关键点模型所在存储位置; [0024] The second step, select the key points in the 3D model kiln refractory BIM software, the key into the storage locations where the model;

[0025] 第三步,将已生成的关键点模型信息所对应的二维码截图粘附于代表该关键点模型表面的适当位置,重新在BIM软件中加载更新炉窑耐材3D模型,显示出二维码图形。 [0025] The third step, the generated key information corresponding to the model of two-dimensional code is adhered to the representative screenshot model of the surface position of the critical point, reload updated 3D models in the refractory furnace BIM software, the display a two-dimensional code graphics.

[0026] 进一步,二维码图形粘附于关键点模型具有较大截面积且易于观测部位的外表面。 [0026] Further, two-dimensional code pattern model having adhered to the key cross-sectional area and a large outer surface of the easy observation point.

[0027] 本发明具有的优点和积极效果是:本发明编码简单、易操作、易查询、易管理。 [0027] The present invention has advantages and positive effects: An encoder according to the present invention is simple, easy to operate, easy to query and easy to manage. 充分完善了耐材3D模型信息的完整性,可追溯性强,共享范围广。 Fully improve the integrity of the refractory 3D model information, strong traceability, share wide range. 信息利用率大大提高。 Information utilization is increased. 对于耐材砌筑施工技术的发展起到了辅助与推进作用。 Construction technology for the development of refractory masonry and has played a secondary role in the promotion.

附图说明 BRIEF DESCRIPTION

[0028] 图1是炉窑耐材3D模型结构体系示意图; [0028] FIG. 1 is a schematic view of the 3D structure of refractory kiln system;

[0029] 图2是关键点模型彳目息标识不意图。 [0029] FIG. 2 is a critical point of the model identification information is not intended to mesh left foot.

[0030] 图中:I一关键点模型;2—二维码。 [0030] FIG Where: I a Key model; 2- dimensional code.

具体实施方式 Detailed ways

[0031] 下面结合附图对本发明的具体实施例做详细说明。 [0031] The following description of the drawings in detail specific embodiments of the present invention binds.

[0032] 一种炉窑耐材3D模型二维码信息标识方法,包括如下步骤: [0032] A 3D model of the kiln refractory QR code identification method, comprising the steps of:

[0033] ①如图1所示,创建3D耐材模型结构体系; [0033] ① 1, create a 3D model of refractory structure system;

[0034] ②如图2所示,确定步骤①3D耐材模型结构中的若干关键点模型I,编辑这些关键点模型信息; [0034] ② shown in Figure 2, the model number of key points I ①3D refractory model structure is determined in step, edit keys model information;

[0035] ③将②中各个关键点模型的信息分别生成对应的二维码2 ; [0035] ③ ② The information model key points generates two-dimensional code corresponding to 2;

[0036] ④将步骤③生成的二维码图形载入到对应的关键点模型I的适当位置; [0036] ④ the step of generating a two-dimensional code pattern ③ loaded into the appropriate location corresponding to the model key points I;

[0037] ⑤将步骤④中带有二维码2的关键点模型I上传至互联网云端或共享数据库平台; [0037] ⑤ ④ The key step in the model with 2-dimensional code is uploaded to the Internet cloud I or shared database platform;

[0038] ⑥现场施工人员利用智能终端设备读取关键点模型信息,实现信息共享与互动。 [0038] ⑥ site construction workers use smart terminal device to read the key point model information, information sharing and interaction.

[0039] 需要说明的是,确定炉窑耐材3D模型中关键点的方法一般是工程技术人员在应用BIM软件模拟砌筑时,软件分析得出的关键位置,或者是工程技术人员经过实践或经验得出的关键点位置。 [0039] Incidentally, the method determines kiln refractory key points in the 3D model is generally applied engineering skill in masonry BIM software simulation, software analysis based on key position, or of being practiced or engineering skill through empirically derived key point.

[0040] 其中,步骤②中的关键点模型I信息包括名称、材质、重量、库位、入库时间、出库时间、砌筑要求、施工工序文字说明,以及相关图片、模拟施工动画或现场视频的链接。 [0040] wherein, in the step ② of the key points of the model I information includes the name, material, weight, location, storage time, leaving time, requires masonry, construction process text, and picture, animation or simulation construction site link to the video.

[0041] 其中,所述相关图片、模拟施工动画或现场视频的链接对应的的图片资料或视频资料预先存储到互联网云端或共享数据库平台。 [0041] wherein the picture, animation or construction site link analog video data corresponding to a picture or video data previously stored or shared to the Internet cloud database platform. 需要说明的是,关键点模型I所信息可随时更新和发布,方便相关技术人员信息的远程共享和互动。 It should be noted that the key point of the model I can update and publish information, facilitating remote sharing and interactive information relevant technical staff.

[0042] 其中,步骤③中所述二维码2的尺寸可以优选2x2mm、4x4mm、6x6mm或8x8mm中的一种。 2x2mm, 4x4mm, 6x6mm 8x8mm of one or [0042] wherein, in the step ③ 2-dimensional code size can be preferable.

[0043] 其中,步骤③中所述二维码优选QR CODE 二维码。 [0043] wherein, in the step ③ dimensional code QR CODE preferably two-dimensional code.

[0044] 其中,步骤②中确定3D耐材模型关键点的方法是,先分析图纸和三维模型,找出结构复杂、施工工序繁琐、需要要重点控制的节点作为BIM建模的关键点。 [0044] wherein the method for determining the 3D model of refractory key step ② is, drawings and three-dimensional model to analyze, identify complex structure, construction complicated process, it is necessary to focus on the point as a key control node BIM modeling.

[0045] 其中,所述关键点模型包括水梁、人孔以及钢带运行线处的模型。 [0045] wherein the key comprises a water beam model, and a model manway of the steel strip line.

[0046] 其中,步骤④中将二维码图形载入到对应的关键点模型方法是: [0046] wherein, in the step ④ the two-dimensional code is loaded into graphical key method corresponding to the model is:

[0047] 第一步,将携有关键点模型信息的二维码2制作成二维码截图; [0047] The first step, carrying the key pattern information made into a 2-dimensional code screenshot dimensional code;

[0048] 第二步,在BIM软件中选取炉窑耐材3D模型的关键点,进入关键点模型I所在存储位置; [0048] The second step, select the key points in the 3D model kiln refractory BIM software, into the key storage location model I;

[0049] 第三步,将已生成的关键点模型信息所对应的二维码截图粘附于代表该关键点模型I表面的适当位置,重新在BIM软件中加载更新炉窑耐材3D模型,显示出二维码图形。 [0049] The third step, the generated key information corresponding to the model of two-dimensional code in place adhered screenshot representing the critical point of the surface model I reload updated 3D models in the refractory furnace BIM software, graphic shows the two-dimensional code.

[0050] 其中,二维码图形粘附于关键点模型I具有较大截面积且易于观测部位的外表面。 [0050] wherein, adhered to the two-dimensional code pattern model key points I having a larger cross-sectional area and an outer surface of the easy observation point.

[0051] 本标识方法在施工技术人员进行耐材3D模型创建过程中,应用于耐材砌筑工程重点、难点部位或特殊施工部位的节点处。 [0051] The present identification method Refractories 3D model creation process, used in refractory masonry engineering major and difficult construction sites or special parts of the nodes in the construction and technical personnel. 根据设计施工需要,把大量有关3D模型的信息(名称、材质、重量、库位、入库时间、出库时间、砌筑要求甚至施工工序文字说明及相关图片和视频连接等内容)编制成QRCODE 二维码电子标签,附于3D耐材模型指定部位。 According to the design and construction needs, a large amount of information on the 3D model (name, material, weight, location, storage time, leaving time, even masonry construction process required text and picture and video connections etc.) compiled QRCODE two-dimensional code tag, attached to the prescribed site Refractories 3D model. 充分完善耐材3D模型信息的完整性实与可追溯性。 Full traceability and improve the integrity of the real 3D model information Refractories. 在耐材施工的过程中可随时通过智能终端设备(智能手机或IPAD等)扫描二维码,获得相应信息,实现信息的共享与互动,及时更新。 During the construction of the refractory at any time through a smart terminal device (smartphone or IPAD, etc.) to scan two-dimensional code, obtain the appropriate information, and interactive sharing of information, up to date. 便于施工技术的交流推广,大大提高了3D耐材模型信息的利用率,使之成为高效连接耐材料3D信息库与人之间的纽带。 To facilitate the exchange of technology to promote the construction, greatly improving the utilization of refractory 3D model information, making the link between the material and human 3D repository efficient connection resistance. 为BIM技术在大型炉体砌筑工程当中的应用与推广起到良好的推进作用。 BIM technology to play a good role in promoting the application and promotion of large-scale furnace masonry engineering among.

[0052] 以上对本发明的一个实施例进行了详细说明,但所述内容仅为本发明的较佳实施例,不能被认为用于限定本发明的实施范围。 [0052] one or more embodiments of the present invention will be described in detail, but only for the preferred embodiments of the present invention, not to be considered to define the scope of the present invention. 凡依本发明申请范围所作的均等变化与改进等,均应仍归属于本发明的专利涵盖范围之内。 Where alterations of improvement under this scope of application of the invention made by the patent shall yet fall within the scope of the present invention.

Claims (9)

1.一种炉窑耐材3D模型二维码信息标识方法,其特征在于,包括如下步骤: ①用BIM软件创建3D耐材模型结构体系; ②确定步骤①3D耐材模型结构中的若干关键点模型,编辑这些关键点模型信息; ③将②中各个关键点模型的信息分别生成对应的二维码; ④将步骤③生成的二维码图形载入到对应的关键点模型的指定位置; ⑤将步骤④中带有二维码的关键点模型上传至互联网云端或共享数据库平台; ⑥现场施工人员利用智能终端设备读取关键点模型信息,实现信息共享与互动。 A refractory furnace 3D models two-dimensional code information identifying method, characterized by comprising the following: ① From refractory create 3D models with BIM software architecture; number of key points ② refractory model structure is determined in step ①3D model, model information edit key; ③ ② information key points in the model corresponding to generate two-dimensional code; ④ the step of generating a two-dimensional code pattern ③ loaded to the specified position corresponding to the critical point of the model; ⑤ the key point model with two-dimensional code in step ④ uploaded to the internet cloud or shared database platform; ⑥ site construction workers use smart terminal device to read the key point model information, information sharing and interaction.
2.根据权利要求1所述的一种炉窑耐材3D模型二维码信息标识方法,其特征在于:步骤②中的关键点模型信息包括名称、材质、重量、库位、入库时间、出库时间、砌筑要求、施工工序文字说明,以及相关图片、模拟施工动画或现场视频的链接。 A two-dimensional code information identifying the refractory furnace method according to claim 1 3D model, wherein: the step ② key points in the model information includes the name, material, weight, location, storage time, leaving time, masonry requirements, the construction process text and related images, links simulation of construction animation or live video.
3.根据权利要求2所述的一种炉窑耐材3D模型二维码信息标识方法,其特征在于:所述相关图片、模拟施工动画或现场视频的链接对应的的图片资料或视频资料预先存储到互联网云端或共享数据库平台。 3. According to a two-dimensional code information identifying the refractory furnace method according to claim 2 3D model, wherein: said picture, animation or construction site links analog video data corresponding to the images or videos in advance cloud storage to the internet or a shared database platform.
4.根据权利要求1所述的一种炉窑耐材3D模型二维码信息标识方法,其特征在于:步骤③中所述二维码的尺寸可以是2x2mm、4x4mm、6x6mm或8x8mm中的一种。 The two-dimensional code information identifying the 3D model A method for refractory kiln according to claim 1, wherein: the size of the step ③ said two-dimensional code may be a 2x2mm, 4x4mm, 6x6mm or in a 8x8mm species.
5.根据权利要求1所述的一种炉窑耐材3D模型二维码信息标识方法,其特征在于:步骤③中所述二维码为QR CODE 二维码。 5. According to a two-dimensional code information identifying the refractory furnace method according to claim 1 3D model, wherein: the step ③ said two-dimensional code is QR CODE two-dimensional code.
6.根据权利要求1所述的一种炉窑耐材3D模型二维码信息标识方法,其特征在于:步骤②中确定3D耐材模型关键点的方法是,先分析图纸和三维模型,找出结构复杂、施工工序繁琐、需要要重点控制的节点作为BIM建模的关键点。 6. A refractory furnace according to one two-dimensional code information identifying method according to Claim. 1 3D model, wherein: a method of determining 3D model of refractory key step ② is, drawings and three-dimensional model to analyze, to find a complex structure, the construction process cumbersome, need to focus on control node BIM modeling as a key point.
7.根据权利要求1所述的一种炉窑耐材3D模型二维码信息标识方法,其特征在于:所述关键点模型包括水梁、人孔以及钢带运行线处的模型。 7. According to a two-dimensional code information identifying the refractory furnace method according to claim 1 3D model, wherein: the key comprises a model, and a model water manhole beam line of steel strip.
8.根据权利要求1所述的一种炉窑耐材3D模型二维码信息标识方法,其特征在于:步骤④中将二维码图形载入到对应的关键点模型方法是, 第一步,将携有关键点模型信息的二维码制作成二维码截图; 第二步,在BIM软件中选取炉窑耐材3D模型的关键点,进入关键点模型所在存储位置; 第三步,将已生成的关键点模型信息所对应的二维码截图粘附于代表该关键点模型表面的适当位置,重新在BIM软件中加载更新炉窑耐材3D模型,显示出二维码图形。 8. According to a two-dimensional code information identifying the refractory furnace method according to claim 1 3D model, wherein: the step ④ in the two-dimensional code is loaded into the key pattern corresponding to the model point method is the first step , the two-dimensional code carrying key information model shots made into two-dimensional code; the second step, select the key point in the kiln refractory BIM 3D software model, where the model into the key storage location; a third step, the model generated key information corresponding to the two-dimensional code in place screenshot adhered surface of the model of the representative point of the key, re-loading an updated software in the BIM kiln refractory 3D model, showing a two-dimensional code pattern.
9.根据权利要求8所述的一种炉窑耐材3D模型二维码信息标识方法,其特征在于:二维码图形粘附于关键点模型具有较大截面积且易于观测部位的外表面。 A two-dimensional code information identifying the refractory furnace method according to claim 8 3D model, wherein: the two-dimensional code pattern to adhere to the model key points having a large cross-sectional area and an outer surface of the easy observation point .
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