wakayama city, wakayama report - sodick€¦ · machining center, 5-axis processing machine, etc....
TRANSCRIPT
High precision components for horizontal knitting machines supporting clothing from around the world“Whole garments” are woven three-dimensionally directly from whole garment knitting machines. The cutting and sewing processes are greatly shortened.
*V-LINE® is a registered trademark of Sodick Co., Ltd. *The export of Sodick’s products and its related technologies (including software applications) is regulated under Japan’s Foreign Exchange and Foreign Trade Control Law. In addition, because some of these products may be subject to re-export controls under the Export Administration Regulations (EAR) of the United States; please contact Sodick before offering or exporting these products overseas. *Photos include images created from 3D model. Options may be included. *The external appearances and specifications are subject to change without prior notice due to ongoing research. *The content is current as of January, 2019.
The parent company, Shima Fine Press’ knitting machine is a proprietary technology capable of seamlessly knitting “whole garments” of even complex one-
piece shapes, holding 60% of the worldwide market share. It has gained worldwide recognition for both its functionality and for not breaking even when used
for long periods of time; Shima Fine Press provides the high-precision parts necessary for this horizontal knitting machine. Outside the realm of horizontal
knitting machines, the company continuously supports the global garment industry with blanking (FB) and ultra precise injection molding technology.
Sodick User Report We hear the voice of customers who use Sodick products.
Shima Fine Press Co., Ltd.Wakayama City, Wakayama
Head office 357 Kozaki, Wakayama City, WakayamaRepresentative Sadao Nishimura, Managing DirectorNumber of employees
110 people
Possessed equipment
Large number of Fine blanking press machine, Injection molding machine, Wire-cut EDM, Die-sinker EDM,Machining center, 5-axis processing machine, etc.
Business activities
Uses techniques such as fine blanking and injection molding to manufacture horizontal knitting machine parts such as needle plates
S9118800.2019.01<01>©Sodick Co.,Ltd.2018 Printed in Japan
3121, Nakamachidai, Tsuzuki-ku, Yokohama,
Kanagawa 224-8522 Japan
TEL: (045) 9423111
Sodick Co., Ltd.https://www.sodick.co.jp/en/
2019 W I N T E RREPORT
SodickNew Technology
Information Overview
New Product
High-speed BuildingMetal 3D Printer
LPM325
New Product
Linear motor driveHigh speed, ultra precisionDie-sinker EDM
AP30L
New Product
Linear motor driveNano Machining Center
AZ275nano
New Product
Linear motor driveHigh speed, ultra precisionLarge wire-cut EDM
AL800P
Users who offer the latest machining examples
Togo Engineering Corporation
Niigata Precision Co., Ltd.
Mutoh Seimitsu Co., Ltd.
M.I.C. Co., Ltd.
Sanko Kasei Co., Ltd.
Shibata-Gosei Co., Ltd.
Supports clothing from around the worldHigh-precision components for horizon-tal knitting machines
Shima Fine Press Co., Ltd.Sodick User Report
Japan: Tokyo
Using machines to their utmost limitsThe company was founded in 1980. Not satisfied with European parts that were adopted at the time, the company aspired to make these parts in-house. President Sadao Nishimura, transferred from Shima Seiki at age 29, said “I had zero mold and molding know-how. What I knew was that we needed to make high-precision parts and that we need high-precision machines to make them”. So he was very particular with the equipment. The theory is, “you can't make a 1000-part machine by lining up a bunch of 100-part machines”.
Use only the best machinesAccording to this policy, we have collected all of the finest machines. However, as President Nishimura said, “What is most important is not just the machine, but mastery of the machine”. “Considering the safety factor, it is common to use machines in ranges that are slightly lower than the champion data from the manufacturer's catalog. But we do things differently. We master our machines so that we can use them at the utmost limit levels defined in the manufacturer's catalog. That’s know-how”. To ensure that the engineers are aware of this, they choose their own machines themselves.The highest grade machines, and the ambition to master them. This posture was probably the reason. The reason why we produced the FB mold only half a year from our establishment. Eight years later we began injection molding, thinking “there are machines that make molds, so we can make plastic molds.” Although we started this way, the parts we handle now are more sophisticated. For example, the main needle plate component that is indispensable for knitting machine control is composed of a hardened material with a thickness of 1 - 2 mm and a length of 200 - 250 mm. This part which uses thousands of pins will produce 80,000 of these per day. We also manufacture special parts with resin. There is a part that cuts the film of new material such as cloth and carbon fiber according to certain dimensions; place the film on this part and it will adhere to and cut it. In order to cut cleanly, we needed to place 8,100 pins in a square of about 100 mm and it took several months to produce this mold.
Automate things well as soon as possibleSome may think that because we are a subsidiary, it is easier for us to make high quality products, but it is actually the opposite. Because we are a subsidiary, the demands are more severe. For this reason, we are making things less expensively through automation. For example, it used to take two hours to polish the tip portion in the needle plate but in collaboration with specialist manufacturers, we were able to develop a breakthrough method to polish it in around 10 seconds. Also, we have been working on automation measures to process any debris stuck inside the molds.
Without challenge, there is no growthThere are endless challenges to develop devices and new technology. Recently, considering that “including post-processing, lasers are faster for most parts,” we have begun to make parts using laser processing. Also, we are bringing in a 650t class molding machine this year, and construction of large size parts is in progress. In addition, while we have not taken any definite action, we are considering using injection molding machine developed by Sodick for aluminum.
“Even if you are productive and profitable, without attempting new challenges, you cannot grow,” says President Nishimura, who serves as a source of company growth.
Linear motor driven wire-cut EDM, die-sinker EDM
A needle plate, indispensable for the control of knitting machine. An important part that we constantly manufacture.
A part that cuts fabric film according to dimensions. Highly difficult parts lined with thousands of pins are handled from die manufac-turing to resin molding.
* WHOLE GARMENT is a registered trademark of Shima Seiki Manufacturing, Ltd.
Linear motor drive Nano Machining Center
High-speed BuildingMetal 3D Printer
AZ275nanoLPM325 NEWNEW
Active Vibration-free System "Counter Table Mechanism"
Suppresses vibrations to the maximum during the cutting process by the cancel axis which is driven in the opposite phase from the machining table
Newly developed and manufactured in-house Built-in high performance amplifier
Higher acceleration machining is possible which reduces the machining time
Ultra High-speed Spindle
Maximum rotation speed 120,000 min-1
Realized highly precise and highly efficient high-speed milling excellence at the nano level
New NC unit developed and manufactured in-houseLN4AZ
Improved machining accuracy by superfine subdivisions of the control unit
Main Specifications
Maximum molded object dimensions (width x depth x height) 250 x 250 x 250 mm
Maximum load weight 120kg
Maximum laser output 500 W
Machine dimensions (width x length x height) 1630 x 2525 x 2020 mm (Including peripherals)
Main Specifications
Each axis stroke (X x Y x Z) 300 x 250 x 100mm
Machining area (width x depth) 275 x 170mm
Main spindle rotation speed 20,000 ~ 120,000 min-1
Maximum quantity of machining material 5kg
New High-Speed Air Spindle Machining Bio-related mold parts 49 consecutive concave R2 hemispheresHemispherical Mirror Finish
This is a Nano Machining Center of a unique structure which demonstrates the superiority of high-speed milling machining to the fullest by a built-in cancel axis
which is driven in the opposite phase from the machining table and a high-speed spindle with a maximum rotation speed of 120,000 min-1.
This is a high-speed building Metal 3D Printer equipped with a 3D building function that has a greatly improved building
speed which is required for the entry model of a Metal 3D Printer, and a reference surface machining function for secondary
machining.
Equipped with a 500 W Fiber Laser
Implements high-speed, high-quality metal 3D printing
High-speed Metal 3D Building Function
Improved fume recovery efficiency with an ideal building chamber layout
Reference surface machining function for secondary machining
New NC unit developed and
manufactured in-house
RM4RP
Space-saving Design
Machine, power supply and peripheral devices Integrated structure
High-speed layered modeling in parallel mode Fluid pump impeller
MRS: Optional
*The machining results are based on environment specified by us.
Maintains stable run-out accuracy and exhibits excellent rotational quality, in a wide rotational speed range of 20,000 ~ 120,000 min-1
Convex shape Concave shape
Producing convex and concave shape with cemented carbide
1st 22nd 49thMax valley depth Pv
71 nm 61 nm 97 nm
Surface roughness Ra
9.9 nm 10.0 nm 17.7 nm
Laser sintering Base surface machining Total
32 hr 56 min 1 hr 28 min 34 hr 24 min
Machining Tools UsedBall end mill R0.1 Guide holeDrill φ0.2 x L2.0 DrillingBall end mill R0.1 De-burringRadius end mill φ2.0 x R0.1 x L6 Pilot holeM threaded mill M3 Screw
To meet a wide range of machining needsAvailable rotational speeds: 20,000 ~ 120,000 min-1
A large range of tool types and sizes are available
Base surface
Base surface
Base surface Base surface
Material STAVAX (50HRC)Machining time 38 sec/hole, 100 holes total
Hole depth 2.0 mm (blind hole)Spindle rotation speed 30000 min-1
Feed speed 20 mm/minStep amount 0.016 mm
Material Fine particle cemented carbide
Machining shape
Convex width 10 μmConvex height 40 μm
Tools PCD toolφ0.1 mm
Material STAVAX (54HRC)Machining
shape49 concave R2 hemispheres
Material OPM-ULTRA1Molded object size φ175 x 80 mm
Material Fine particle cemented carbide
Machining shape
Concave width 30 μm Height 20 μm Slope 20°
Tools PCD toolφ0.03 mm
30mm
: Base surface
1 2Sodick Report 2019 WINTER
-5
-3
-10
1
35(µm)
1 2 3 4 5 6 7 8 9 10 11 12 13
Reference point
0.0
X-axis
Y-axis
Measuring instrument: 3D measuring machine
Machining position number
Linear motor driveHigh-speed and High Precision Large Wire-Cut EDM
Linear motor drive High-speed and High Precision Die-Sinker EDM
AL800PNEWNEW AP30L
Full cover (optional) / ATC specification(optional)
X-axis Stroke 800 mm
Wide and ultra-high precision full cover model
Ultra-Precision Machining
Adopted ceramic for machine structure
Thermal commit system (TH-COM)
Automation of High Precision Machining
High-speed automatic wire threading unit “FJ-AWT”
New core processing unit “S3CORE (Score)” (optional)
Pitch Machining Accuracy
±1.5 µm at the Long Plate
High Speed and High Responsiveness
High speed and dynamic responsiveness by linear motor and motion controller "K-SMC" developed and manufactured in-house
Lightweight and Highly Rigid Symmetry Head
Lightweight and high rigidity by adoption of our new CFRP and ceramics developed and manufactured in-house
AI technology
Equipped with the latest applications which uses AI (artificial intelligence) technology
Ark-less 4
Greatly improved machining speeds in all rough, medium and finished machining
New NC unit developed and manufactured in-house
LP4 Power Supply
Main Specifications
Each axis stroke (X x Y x Z) 800 x 600 x 250 mm
U x V axis stroke 150 x 150mm
Maximum quantity of machining material 1500kg
Wire electrode diameter φ0.1 ~ φ0.3 mm
Main Specifications
Each axis stroke (X x Y x Z) 300 x 250 x 200mm
Table dimensions (width x length) 500 x 350mm
Maximum electrode suspended mass 5kg
Maximum quantity of machining material 200kg
This is a high-precision large Wire-cut EDM equipped with a new structure and new system that minimizes thermal displacement,
which further realizes high-speed and high accuracy in large components related to energy and aircraft, and large molds
related to automobiles and electricity.
With the further evolved electric discharge stable machining system “Arc-less 4,” this is a 3-axis (XYZ) linear motor drive high-
precision Die-Sinker EDM which realizes various surface finishing at high-speed and highly efficient machining in the fine and
precision areas.
Pitch Machining Accuracy ±1.5 µmGreatly improved in all areas of Pitch, Shape, Position and Speed
250m
m 125m
m
75m
m
50mm 50mm
75m
m50
0mm
250m
m
650m
m
350mm350mm
175mm
700mm
800mm
5
7
4
1
8
2
9
6
3
10
12
11
13
Head casting
Arm casting
Linear motor
In machining tankTable
Work piece
Electrode
Table liquid leveling
CR axis(optional)
Bed casting
Head structure
Overall temperature control
Developed to allow circulation of
to control the overall temperature.
*The machining results are based on environment specified by us.
Machining precisionShape precision +0.0030 ~ +0.0040 (Range 1.0 μm)Position accuracy −0.0010 ~ +0.0008 (Range 1.8 μm)Pitch accuracy −0.0011 ~ −0.0005 (Range 0.6 μm)Depth accuracy −0.0046 ~ −0.0036 (Range 1.0 μm)
Material SLDWorkpiece size 800 x 650 x 20 mm
Wire φ0.25 mm Tsubame Wire PlusMaximum pitch distance X direction 700 mm Y direction 500 mm
Material STAVAXElectrode material CuSurface roughness Ra 0.14 μm Rz 1.07 μm
Machining depth 1.5mmWorkpiece dimensions 100 x 100mmMaximum pitch distance 80mm
Material S-STARElectrode material CuW
Electrode reduction dimension
0.03 mm/side
Surface roughness Rz 0.34μmMachining depth 0.05 mm
Workpiece dimensions 0.3×0.1 mmMachining liquid OIL Vitol-2
Corner R 3 μm (machined bottom)BSN4 circuit use 30% higher machining speed
Ultra-fine connector machining
3 4Sodick Report 2019 WINTER
Linear motor drive High-Speed and High Performance Wire-Cut EDM
Linear motor driveUltra High Speed Milling Center
ALN600G + Erowa Robot Compact 80 UH430L
Developed and manufactured in-house
XYZ 3 Linear Motor Drive
High accuracy and high quality at high speeds
SEPTune
SEPT (high-speed, high-precision contour control function) configuration support mode
Sped up control cycles for each axis
High-quality finish machining in fine precision areas
Lightweight head using CFRP
Lightweight, highly rigid, high vibrational dampening (HSK-E25 type)
New software usingAI (artificial intelligence)
Main Specifications
Each axis stroke (X x Y x Z) 600 x 400 x 350mm
U x V axis stroke 150 x 150mm
Maximum quantity of machining material 1000kg
Wire electrode diameter φ0.05 ~ φ0.3 mm*
Main Specifications
Table dimensions (width x length) 600 x 400mm
Each axis stroke (X x Y x Z) 420 x 350 x 200mm
Maximum quantity of machining material 100kg
Main spindle rotation speed 1500 ~ 60000 min-1(HSK-E25IK)
All of the underlying technology is developed and manufactured in-house, including linear motors mounted on the XYUV4 axes.
Demonstrates excellent affinity for automated system construction and with Advanced Smart Pulse and Advanced Smart Linear,
it is a high-speed, high-performance wire-cut EDM with a top class linear motor drive.
This is a an ultra-high speed milling center with linear motor drives developed and manufactured in-house mounted on the XYZ3 axes,
supports increased speed of direct engraving by using diamond tools and high quality mirror surface machining of optical lenses, etc.
Large wire-cut EDM control technology
Drum-less control II
TMP control II
Digital-PIKA-W Plus
Developed and manufactured in-house
XYUV4 Linear Motor Drive
Maintains semi-permanent precise axis movements without backlash
Automation of High Precision Machining
High-speed automatic wire threading unit “FJ-AWT”
New core processing unit “S3CORE (Score)” (optional)
Developed and manufactured in-house
Uses ceramics
Insulation structure of the wire running system and workpiece securing part
Increased operating rate by robots for automatic work pallet exchange New core processing unit “S3CORE” Machinable Ceramic Drilling Stair-shaped optical forms
*The machining results are based on environment specified by us.
Material 20 x 20 x 5mmMachining conditions
Spindle rotation speed 14,000 min-1 Feed speed 40 mm/min
Tools Used Center drill φ0.08 mm (for positioning/drilling)Features Can machine large numbers of holes in high-hardness workpieces such as
ceramics and super engineering plastics, with high precision and accurate pitch.
Material STAVAX (52HRC)Machining conditions
Spindle rotation speed 22,000 ~ 40,000 min-1 Feed speed 350 ~ 3,000 mm/min
Tools Used Ball end mill R1.5-R0.05 Finished CBN ball end mill R0.05Features High precision, high definition surface finishing (Ra0.1μm or less)
We designed a mold shape for creating small diameter (R0.05)automobile headlights.
(Optional)
*Less than φ0.1 mm is optional.
5 6Sodick Report 2019 WINTER
eV-LINE Electric Injection Molding Machine
Connect, Master, Sodick-IoT
MS50
Ultra-narrow pitch
Enlarged view
Enlarged view
Enlarged view
Lead frame100µm narrow pitchSaves 50µm
Ultra-fine engraving
Precision bending
15 µm depth for plume machiningMicro forming engraving
Bending machining on the plume part
MODEL Kagoshima Prefecture, Sakurajima Mt. SAKURAJIMA*The mold shape uses the “Sakurajima” motif.
Kagoshima Satellite
Launched as a small satellite, joined to the HIIA rocket No. 17 which is carried by the Venus probe “Akatsuki”. (Image source: JAXA)
Small on-board satellite photographs
Size: 10 cm x 10 cm x 10 cm approx.Weight: 1.4 kg approx.
This project has succeeded in using high processing technology to become lightweight and highly rigid.
[Satellite Objective]Intended to study and predict severe storms and tornadoesVideo recording from space
Togo Engineering Corporation
Ultra-narrow pitch
Enlarged view
Enlarged view
Enlarged view
Lead frame100µm narrow pitchSaves 50µm
Ultra-fine engraving
Precision bending
15 µm depth for plume machiningMicro forming engraving
Bending machining on the plume part
MODEL Kagoshima Prefecture, Sakurajima Mt. SAKURAJIMA*The mold shape uses the “Sakurajima” motif.
Kagoshima Satellite
Launched as a small satellite, joined to the HIIA rocket No. 17 which is carried by the Venus probe “Akatsuki”. (Image source: JAXA)
Small on-board satellite photographs
Size: 10 cm x 10 cm x 10 cm approx.Weight: 1.4 kg approx.
This project has succeeded in using high processing technology to become lightweight and highly rigid.
[Satellite Objective]Intended to study and predict severe storms and tornadoesVideo recording from space
Togo Engineering Corporation
Ultra-narrow pitch
Enlarged view
Enlarged view
Enlarged view
Lead frame100µm narrow pitchSaves 50µm
Ultra-fine engraving
Precision bending
15 µm depth for plume machiningMicro forming engraving
Bending machining on the plume part
MODEL Kagoshima Prefecture, Sakurajima Mt. SAKURAJIMA*The mold shape uses the “Sakurajima” motif.
Kagoshima Satellite
Launched as a small satellite, joined to the HIIA rocket No. 17 which is carried by the Venus probe “Akatsuki”. (Image source: JAXA)
Small on-board satellite photographs
Size: 10 cm x 10 cm x 10 cm approx.Weight: 1.4 kg approx.
This project has succeeded in using high processing technology to become lightweight and highly rigid.
[Satellite Objective]Intended to study and predict severe storms and tornadoesVideo recording from space
Togo Engineering Corporation
株式会社 新潟プレシジョン
“Uesugi's clan 35 chosen swords”
Takasenagamitsu
Sword Inscription Nagafune Nagamitsu
Users who offer the latest machining examples
Client PC Client PC Client PCClient PC Client PC
Browsing client PCunlimited connections
ETDL4 �le server
Collect!Collects molding data for quality control
Up to
20machines
Clearly displayed!Molding Site Quality & Production Control System
MS Series GL Series EH3 SeriesVRE Series EHV Series
ETDL4 Option
Application Dedicated for Sodick's Injection Molding Machines
The ETDL4 is installed in the file server, and is connected to the molding machines online. Various data of the molding machines is displayed on the PC terminals. What's happening on site can be clearly understood, which contributes to improvement in the production efficiency and quality.
Netw
ork configuration
IoT supported Displays molding data in tabular or graph formatDisplays the history of errors, operation and condition changes of the molding machine
Access from anywhere with a smartphone or PC
Operating stateCollective management
Detailed informationCan be viewed
Maintainabilityimprovements
Insulator
Developed and manufactured in-houseLinear motor
Based on “V-LINE®” which has excellent performance, high precision and repetition stability,
we developed this energy saving eV-LINE all-electric injection mounding machine
with motorized responsiveness, a new mold clamping mechanism and improved productivity through high cycle.
Main Specifications
Maximum mold clamping force 490 kN
Tie bar interval (W x L) 360 x 360mm
Minimum/maximum mold thickness 150/350 mm
Machine body dimensions (L x W x H) 3725 x 1155 x 1970mm
Built-in 3D cooling pipingHigh-cycle insulator molding with ametal 3D printer mold
Corresponds to telecommunications standards MTConnect, OPC-UA
Production controlSupport
Simplescreen layout
S-ViewerNEW S-HARMNY
Togo Engineering Corporation Niigata Precision Co., Ltd.
Striving for the best QCDS (quality, cost, delivery time and service),
we are the first and only one to achieve high customer satisfaction.
We introduce each measuring instrument used to evaluate the
precision. We work hard every day as experts of ultra-precision
machining to deliver more accurate and safe parts.
Mirror ball(Sphere diameter 30 mm)
We use cutting, grinding, wire EDM, and die-engraving EDM to
produce small quantities of various kinds of products. We offer the
best materials and machining methods to suit customer needs.
This is a sample of the results of serious, imaginative work.
We aim for “manufacturing without limits”.
Meticulous precision machining without compromise
Precision automatic machine components
Precision metal components
Cemented carbide components
Ceramic components
�Expressing technical
and engineering skill
Component production
Imaginative component production
7 8Sodick Report 2019 WINTER
Electrode machining sample Machining time Model HS150L
Machining time 0.25 Hrs.3Machining time 0.54 Hrs.1
Machining time 0.83 Hrs.5
Machining time 0.33 Hrs.4
Machining time 0.25 Hrs.Round hole electrode Model AQ35L
Machining time 0.32 Hrs.2
Electrode production
without deburring
Electrode production up to the minimum Ø0.09
The electrode shape is concentrated as much as possible, leading to reduced discharge setup time.
Improved insert nut suction nozzlesFor insert molding robots
Metal 3D PrinterPlastic models made with the “OPM250L”
Mold and printed withan inkjet printer
The nut is inserted into the hole during insert molding, but is too small
to be effectively inserted by hand. For a robotic insert molding, a section
nozzle to grab the insert nut is required. Suction nozzles created by
normal machining have weak suction and frequently cause problems.
�For normal machining, performance cannot be maximized due to
machining limitations!
Consider what can be improved by creatingwith a metal 3D printer.
* “Puripura” is a registered trademark of M.I.C. Co., Ltd. Comparison method [mold] We used two molds for mass
production. One incorporates a 3D cooling die. [Molding material]
PA+GF50 (CM3531G-50 B3), PA6 (CM3001N) PC (SD Polica 301-15
030030), POM (NW-02), PP (Novatec MH4) [Conditions] Uses PA
+ GF50 mass production conditions. Fixed conditions, except for
cooling time. [Evaluation] Measurement of each molded item in
the illustrated position. Compare the values and verify the effect.
Warp deformation improvements3D cooling effect verification
Results
3D cooling results
Improved process problems
Able to produce finer details than expected
Create new ideas by overcoming normal machining constraints
Fully integrated unitCombines normally machined partsIntegrated air hose and fittings
Study contents Differences in the amount of molded object deformation for each cooling system and cooling time
Air flow path optimizationMaximized suction hole areaFlow path homogenization
Ideal value...the value with no warm deformation at allSection force homogenizationVolume maximized sub tank
Can shorten freezing time by 1/3Warp
deformation is
Improved
ManufacturingManufacturing
Design and production of plastic precision dies (insert dies and mold dies)
Can manufacture molds of up to 50t specifications and machining
can handle a minimum 0.13 gate diameter
We earnestly strive for precision.
First, we try to challenge ourselves.
Because we don’t want to say “that’s impossible”.
“Is this right?”
we ask ourselves.
Designdesign
Inspectioninspection
Suction hole area
10X21 parts
Reduced to 3 parts
Unit weight
40%Down
eV-LINE Only for OPM molds Manufacturing cell system
MR30
Sanko Kasei Co., Ltd.M.I.C. Co., Ltd.Mutoh Seimitsu Co., Ltd. Shibata-Gosei Co., Ltd.
The closer to the ideal value,the smaller the warp deformation
Ideal value
3D cooling
Normal cooling
For normal cooling, even if the cooling
time is extended, there is hardly any
improvement in warp deformation.
For 3D cooling, even if the cooling
time is shortened, warp deformation
improves.
Resin name POM
Cooling time (seconds) 35 12
Mold temperature (°C) 30 30
Measurement results (mm) Normal cooling product 51.99 51.80
Measurement results (mm) 3D cooling product 52.81 52.56
Improved value (mm) 0.82 0.76
3D cooling position and product Normal cooling position and product Points to compare warp deformation
Digital modeling
CAD design
Mold
Molding
Printing
Building
Linear motor drive Precision metal 3D printer
OPM250L
Work flow
9 10Sodick Report 2019 WINTER