A file with the .crz extension is most commonly used by Poser, the 3D figure modeling and animation program originally developed by Smith Micro and later maintained by Bondware, where it saves a compressed version of a Poser character or figure file. Within a typical .crz file holds the same kind of data you would find in a .cr2 character file—such as figure structure, bones, rigging information, and parameter settings—but wrapped in a compressed form to reduce disk space and improve loading efficiency. Because it is a program-specific 3D figure format and not a general interchange file like OBJ or FBX, most other 3D tools and the operating system will not open or preview .crz files directly, and they are usually intended to be used only inside a Poser-based workflow. If you come across a .crz file and are not sure what it is, you can use FileMagic to confirm it as a compressed Poser character file and, where supported, open or inspect it before deciding whether to load it in Poser, decompress it to a .cr2 file, or request an export in a more common 3D format.

A 3D image file is a digital file that describes a three-dimensional object or scene so that software can display it, rotate it, render it, or even animate it. This makes it very different from ordinary image files like JPG or PNG, which only contain flat pixel data. A normal image says, “this spot is red, this one is blue.” A 3D file says, “there is a point here in 3D space, it connects to this other point to form a surface, that surface should look metallic, and it should be lit from this direction.” Because of that extra structure, 3D image files are used in many professional and technical fields, from game development and animation to product visualization, engineering, training content, and modern AR/VR experiences.

Inside a 3D image file, there is usually a description of the object’s shape, called geometry or mesh. This is made of points in 3D space and the faces that connect them, which together form the model. On top of the shape, many 3D files also store the appearance of the object, such as materials and textures, so software knows whether a surface should look like wood, plastic, glass, or painted metal. Some formats go further and store information about the scene itself, including camera positions, lights, and sometimes animation data such as skeletons, keyframes, or motion paths. That is why opening a 3D file can sometimes recreate not only the object but the way the original creator intended it to be seen.

There are so many different 3D formats because 3D did not grow out of a single standard. Different industries invented formats that matched their work. Traditional 3D modeling and animation programs created project-style files that could save everything about a scene. Game engines and older games created leaner formats so assets would load quickly during gameplay. Engineering and architecture favored precise, structured data. Later, CRZ file reader and mobile world needed lightweight 3D for online product viewers and AR. Over the years this produced a long tail of 3D-related file extensions, including many that are used only by a specific program, a specific engine, or even a specific version of a tool. These files still circulate today in shared folders, archived projects, course materials, and client handoffs, even if the original software is gone.

In real-world workflows, 3D image files often sit in the middle of something important. A studio may have built a character or prop in a small or older 3D tool and exported it years ago. A game modder may have extracted assets from a title that used a custom animation format. A training company may have stored lightweight models inside e-learning packages. A design group may have kept models for client presentations that were never converted to a more common format. When people return to those folders later, what they see is just a list of unfamiliar extensions that Windows cannot preview. At that point the main question is no longer “how do I edit this,” but “what even is this.”

That is where a general opener like FileMagic becomes useful. When a user receives or discovers a 3D file that the operating system does not recognize, the first step is simply to identify it. FileMagic can recognize a wide range of 3D image files, including those that are not mainstream, so the user can confirm that the file is in fact a 3D model or 3D animation file. For formats it supports, it can open or preview the contents, which lets the user verify that the file is valid and see what it contains before committing to a full 3D or CAD application. This reduces guesswork, and it also reduces the need to install several heavy programs just to find out which one can read a single file.

Working with 3D files also brings a few predictable problems. Sometimes the file opens but appears gray because the textures were in a separate folder that got moved. Sometimes the file was saved in an old version of a tool and the new version does not like it. Sometimes a file extension was used by a game or application to bundle several kinds of data, so it is not obvious from the name alone that 3D data is inside. And often there is no thumbnail or preview at all, which makes the file look broken even when it is perfectly fine. A tool that can identify and, when possible, view the file helps rule out corruption and tells the user what to do next.

It is also common for 3D files to be part of a larger structure. A model may reference external texture images; a scene may reference other models; an animation file may be intended to be used together with a base character file. This is another reason people get confused when they see only one mysterious file in a download: they are looking at one piece of a 3D workflow. Being able to open it and read what kind of file it is makes it much easier to request the missing parts or convert it to a simpler, more portable format.

For teams that handle assets from multiple sources, or for users who work with old projects, the safest pattern is to identify first, convert second. If the file opens now, it is smart to export or save it into a more common 3D format for long-term use, because obscure formats tend to get harder to open over time. But that first identification step still has to happen, and that is the gap FileMagic is meant to close.

In short, a 3D image file is a structured container for 3D information—shape, appearance, and sometimes animation—created by many different tools over many years. Because of that diversity, users often encounter 3D files that their system does not immediately understand. A multi-format opener that recognizes a broad range of 3D-related extensions makes it possible to see what those files are, confirm that they are valid, and decide which specialized software to use next, without having to break the workflow or guess blindly.