KR20220034985A - 3D printer station equipped with hazardous substance discharge device and remote control system - Google Patents

Abstract

The present invention provides a 3D printer station equipped with a hazardous substance discharge device and a remote control system in which hazardous substances generated by melting filament materials during operation of 3D printer are directly discharged from the 3D printer station to the outside while not being discharged to the indoor space where the 3D printer is installed, so that the indoor space where the 3D printer is installed can maintain a safe environment from harmful substances harmful to the human body.

Description

3D printer station equipped with hazardous substance discharge device and remote control system

The present invention relates to a 3D printer station, and more particularly, to an indoor space in which a 3D printer is installed by directly discharging harmful substances generated while the filament material is melted during operation of the 3D printer not to be discharged into the indoor space in which the 3D printer is installed. To maintain this safe environment, it relates to a 3D printer station equipped with a hazardous substance discharge device and a remote control system.

A traditional printer prints a 2D image (character or picture) by jetting ink onto a two-dimensional plane when a digitized file is sent, whereas a three-dimensional printer is a device that creates a three-dimensional object in a three-dimensional space. Therefore, a traditional 2D printer uses document data composed of text or images to print on a flat surface while moving only in the forward and backward (X-axis) and left-right (Y-axis) directions, but a 3D printer uses three-dimensional drawing data to print on a flat surface. A three-dimensional object is created based on the input 3D drawing while moving in the X-axis), left-right (Y-axis) and up-down (Z-axis) directions.

In order to produce a three-dimensional object through a 3D printer, a 3D drawing is first completed using a CAD or 3D modeling program, and then the corresponding data is transmitted to the printer through a predetermined data interface. The 3D printer is based on the transmitted 3D drawing data. to carry out the process of making the corresponding three-dimensional object. In other words, 3D printers use filament materials such as plastic (synthetic resin) or metal instead of ink, and output based on 3D modeling drawings instead of document data composed of text or images. After dispensing, the filament material is melted and continuously stacked and fused while discharging through the nozzle to produce the corresponding three-dimensional object.

In the process of melting filament materials such as plastic (synthetic resin) or metal, when producing a three-dimensional object with a 3D printer, harmful substances such as carcinogens and fine dust are inevitably generated. Although the causal relationship between the disease and the disease has not been fully elucidated, carcinogens and endocrine disruptors such as benzene, toluene, formaldehyde, and phthalate have been detected in the dust and gases generated by 3D printers, and users who have used 3D printers a lot (teacher The reality is that there have been many cases of sarcoma, a rare cancer, and a number of papers and reports warning about the dangers of the 3D printer environment have been published at the Occupational Safety and Health Institute of the Korea Occupational Safety and Health Agency.

In relation to the removal of harmful substances generated by 3D printers, patent registration No. 2130370 “Booth structure for 3D printer equipped with a function to measure and reduce harmful substances”, Patent registration No. 2022244 “Hazardous gas removal device for 3D printer”, etc. technology has appeared, but all of these technologies are technologies that either install a filter in the booth where the 3D printer is installed to filter out harmful substances, or install a sensor to prevent the door from being opened when the concentration of hazardous substances in the booth is higher than the standard value. .

However, since 3D printers that produce a variety of products in small quantities use filaments of various materials, hazardous substances generated depending on the materials are inevitably different, and accordingly, the filters used to remove hazardous substances must also be different. There is a problem that harmful substances cannot be filtered properly because the filter is used, and when the concentration of harmful substances in the booth is higher than the standard value, even if the door of the booth cannot be opened, the harmful substances do not disappear, so the indoor space where the 3D printer is installed is always There is a problem of being in a state of defenseless exposure to harmful substances.

The present invention has been devised to solve the above problems, and an object of the present invention is to prevent harmful substances generated by melting the filament material during operation of the 3D printer from being discharged directly from the 3D printer station to the indoor space where the 3D printer is installed. It is to provide a 3D printer station equipped with a hazardous material discharge device and a remote control system so that the indoor space in which the 3D printer is installed can maintain a safe environment from harmful materials harmful to the human body by discharging to the outside.

Another object of the present invention is to minimize the installation space by intensively loading a plurality of 3D printers in one station, and to install a remote control device so that a plurality of 3D printers can be controlled from one PC installed outside the station, An object of the present invention is to provide a 3D printer station equipped with a hazardous substance discharge device and a remote control system.

A 3D printer station having a hazardous substance discharge device and a remote control system according to the present invention has a cabinet shape with an open front, and a booth in which a 3D printer is installed; a door installed to open and close the open side of the booth; an exhaust fan installed on the wall of the booth to suck in air inside the booth and exhaust it to the outside; It is characterized in that it comprises a duct installed to connect the exhaust fan and the outdoors in order to discharge the air sucked from the interior space of the booth to the outside outside the indoor space where the booth is installed.

Preferably, the booth has an internal space divided into a plurality of spaces, a 3D printer can be installed in each partitioned space, and a door that can open and close an open surface is installed in each partitioned space.

Preferably, a router and a server are installed outside the booth, and the 3D printer installed inside the booth is connected to the server, respectively, so that one PC can control the 3D printer installed in each partitioned space.

3D printers inevitably generate toxic substances that are very harmful to the human body generated as the filament material melts when operating, and many problems occur due to toxic substances because the generated toxic substances are left indoors as they are. In the 3D printer station, a number of 3D printers are installed in a closed internal space within the booth, and an exhaust fan and duct are installed in the station to directly discharge harmful substances generated during 3D printer operation from the station to the outside. The space is fundamentally blocked from harmful substances, and even if the door installed in the station's booth is opened for filament material supply and output recovery, the indoor air outside the station flows into the station's booth by the suction pressure of the exhaust fan. Air inside the booth of the station containing the substance does not leak out to the outside of the station, so the indoor air can be kept safe as it does not mix with harmful substances and is blocked.

In addition, since a number of 3D printers are intensively loaded and installed inside the station, the printer installation space can be minimized. It will be possible to fundamentally block the contact with harmful substances inside the station.

1 is a perspective view in which a 3D printer station according to the present invention is installed.
2 is a view for explaining a state in which harmful substances inside the station are discharged.
3 is a diagram for explaining a state in which a PC is connected and controlled to a 3D printer installed inside a station.

The technical feature of the 3D printer station according to the present invention is that the 3D printer is installed in the station to directly discharge harmful substances generated when the filament material is melted to the outside, so that the indoor environment is safe from harmful substances harmful to the human body.

In the specification of the present invention, a 'station' refers to a type of housing in which one or more 3D printers are installed, that is, a housing in which a 3D printer is installed. A printer is installed, and the station is configured by installing a booth with an open front side like a cabinet, and an openable door for each partitioned space on the open side of the booth.

The 3D printer station 10 according to the present invention is a place where a plurality of 3D printers are installed and used in the same space, for example, a company using a plurality of 3D printers, as well as a school or academy for educating 3D printers, etc. It can be usefully used.

The 3D printer station 10 according to the present invention includes a booth 11 such as a housing in which an internal space is secured, a door 12 installed in the booth 11, and an exhaust fan 13 for discharging air inside the booth 11 ), a duct 14 for exhausting the air discharged through the exhaust fan 13 to the outside is provided as a basic configuration. Since the 3D printer itself is not a characteristic configuration of the present invention and is universally used in various fields, a description of the 3D printer will be omitted.

The booth 11 is manufactured in the same shape as a hexahedral cabinet with an open front surface, and the 3D printer 20 is installed therein, such as a housing in which the 3D printer 20 is installed in the internal space It is configured, and the door 12 is installed so as to open and close the open side of the booth 11 .

The booth 11 is preferably configured by partitioning the internal space into a plurality of spaces, and it is preferable to divide the partitioned space to be stacked vertically as well as horizontally to make the most of the internal space, and for each partitioned space The 3D printer 20 can be installed, and a door 12 capable of opening and closing an open surface is installed for each partitioned space (see FIG. 1 ). As described above, the booth 11 can be installed by intensively loading and installing a plurality of 3D printers by dividing the internal space, thereby minimizing the printer installation space by maximizing the internal space.

The exhaust fan 13 is installed on the wall of the booth 11, sucks the air inside the booth 11 and discharges it to the outside. One or more may be installed. The 3D printer inevitably generates harmful substances such as noxious gas or fine dust, which are very harmful to the human body, generated when the filament material is melted. The exhaust fan 13 operates to suck in harmful substances generated during the operation from the internal space of the booth 11 and discharge it to the outside (see FIG. 2 ).

Even if the door 12 installed in the booth is opened for the supply of filament material and recovery of the output, the air in the interior space of the booth 11 is not discharged to the interior space outside the booth 11 due to the suction pressure of the exhaust fan 13, Since the indoor air outside the booth 11 flows into the inside of the booth 11 due to the suction pressure, the air inside the booth 11 containing harmful substances does not flow out to the outside of the booth 11, which makes the indoor air harmful. The indoor air can be kept safe as it is blocked without mixing with the material.

The duct 14 is installed to connect the exhaust fan 13 and the outdoors in order to directly discharge the air sucked in from the internal space of the booth 11 to the outside outside the indoor space where the booth 11 is installed. In this way, since the harmful substances in the internal space of the booth 11 are directly discharged to the outside, the indoor space where the 3D printer is installed can be fundamentally blocked from the harmful substances.

On the other hand, it is preferable to install the router 31 and the server 30 outside the booth 11 in order to prevent the operator from contacting the 3D printer during the output operation of the 3D printer and control it by remote control. 11) A plurality of 3D printers 20 installed inside are connected to the server 30, respectively, and one PC connected to the Internet installed in an indoor space or a remote place can control the 3D printer installed in each partitioned space (FIG. 3). Reference). In addition, a booth can be managed not only by one booth, but also by remote control from a single PC connected to the Internet. Therefore, it is possible for the operator to block or minimize contact with harmful substances in the booth 11 .

The above description is illustrative of the present invention, and the embodiments published in the specification are for explanation rather than limiting the technical idea of the present invention, so those of ordinary skill in the art to which the present invention pertains Various modifications and variations will be possible without departing from the technical idea of Therefore, the protection scope of the present invention is to be interpreted by the matters described in the claims, and technical matters within the scope equivalent thereto should be construed as being included in the scope of the present invention.

10: Station 11: Booth
12: door 13: exhaust fan
14 : Duct
20: 3D Printer
30: server 31: router

Claims (3)

A booth in the shape of a cabinet with an open front and a 3D printer installed therein;
a door installed to open and close the open side of the booth;
an exhaust fan installed on the wall of the booth to suck in air inside the booth and exhaust it to the outside;
a duct installed to connect the exhaust fan and the outdoors in order to discharge the air sucked in the interior space of the booth to the outside outside the indoor space where the booth is installed;
3D printer station having a hazardous substance discharge device and a remote control system, characterized in that it comprises a.
The method of claim 1,
The booth is configured by dividing an internal space into a plurality of spaces, a 3D printer can be installed in each partitioned space, and a door that can open and close an open side in each partitioned space is installed and configured 3D printer station with material ejector and remote control system.
3. The method of claim 2,
A router and a server are further installed outside the booth, and the 3D printer installed inside the booth is respectively connected to the server so that one PC can control the 3D printer installed in each partitioned space. and a 3D printer station equipped with a remote control system.

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