ESA’s contribution to NASA’s Orion spacecraft is the European Service Module, designed to provide the spacecraft’s propulsion, electrical power, water and thermal control. The model, designed by Airbus Defence and Space, was assembled by OHB Sweden.

Made from steel and containing propellant and helium tanks, among various electronics and command systems, the Propulsion Qualification Model allows engineers to determine how well systems are working together.

The model was built in January in Stockholm, Sweden and has since been shipped to the White Sands Test Facility in New Mexico (USA), where it will undergo more extensive testing by NASA, ESA and main contractor Airbus DS.

Credits: Airbus

Small auxiliary electronic modules from passenger aircraft, saved from scrapyard.

Lunar module on display at the Science Museum London

GXR M module with Carl Zeiss Biogon 25mm 2.8 ZM

I expect this will be Guessed Where SF immediately, but I had to post it anyway because it's just so weird.

This is another very easy module which I am sure other folders have already discovered. The Module is simply a Preliminary Base with 2 opposite corners folded in to the centre. 8 modules are joined with simple folds to form a ring of triangles. 7.5cm squares of Wood Grain patterned papers and Kami are used to fold the modules. Diagrams later.

UPC CI+ module inclusief smartcard

This is another very easy module which I am sure other folders have already discovered. The Module is simply a Preliminary Base with 2 opposite corners folded in to the centre. 8 modules are joined with simple folds to form a ring of triangles. 7.5cm squares of Wood Grain patterned papers and Kami are used to fold the modules. Diagrams later.

Grumman Lunar Module 13 (LM-13) at the Cradle of Aviation Museum in Mitchel Field. Lunar Module 13 was intended to land at Copernicus Crater during the canceled Apollo 18 mission. LM-13 also starred in the HBO miniseries "From The Earth To The Moon".

Lunar Module 2 was the second spacecraft built by Grumman Aerospace for use in the Apollo program. Originally, it was supposed to have flown in space, but the flight of Lunar Module 1 during the Apollo 5 mission was so successful that a second unmanned flight was considered unnecessary. Instead, Lunar Module 2 was used in drop tests to evaluate the performance of the landing gear. This craft is very similar to Eagle (Lunar Module 5), which carried Apollo 11 astronauts Armstrong and Aldrin to the surface of the Moon in 1969.

Edited Apollo 11 image of the Lunar Module Eagle from a distance. (I hesitate to guess the distance given the lack of atmosphere.)

The piping module rests 56 feet above the ground. Pre-assembling it outside the facility was safer because it provided workers with better accessibility and enabled them to work at much lower heights.

Stackable modules for my Soropolis project.

Facade with red window - ice cream parlor - school - roof with round window - entrance with round window - roof with dormer window - appartment with large bay window - purple and red entrance - green roof appartment - dance studio

N scale town module -- various kits

The terraced level at the back with the theatre.

developer: Kodak T-Max 1+7 9' (18c)

Lunar Module 2 was the second spacecraft built by Grumman Aerospace for use in the Apollo program. Originally, it was supposed to have flown in space, but the flight of Lunar Module 1 during the Apollo 5 mission was so successful that a second unmanned flight was considered unnecessary. Instead, Lunar Module 2 was used in drop tests to evaluate the performance of the landing gear. This craft is very similar to Eagle (Lunar Module 5), which carried Apollo 11 astronauts Armstrong and Aldrin to the surface of the Moon in 1969.

Installing the Crew Module Adapter that will be the interface between the Crew Module and the European Service Module for NASA's Artemis II Moon mission. The second European Service Module arrived from Airbus in Bremen and was integrated at NASA's Kennedy Space Center.

Credits: NASA–Radislav Sinyak

Development Module for PhD Scholars

Road Map workshop at Cumberland Lodge, Windsor

RGB Panorama Pro LED Module

Dial In The Wow

Your favorite color spectrum is now just a click away – introducing the new RGB Panorama Pro LED module. With touch button remote control, fade features and adjustable intensity, you can dial in the perfect blend of light for every aquatic mood.

Using the same sleek design as our Panorama Pro Module, the RGB Pro delivers amazing color and intensity without sacrificing energy efficiency. Choose one of 16 different color spectrums with the simple touch of a button. Whether you want to add a little fuchsia purple to your reef tank, create an aquablue angelfish tank, or gently fade through all the color spectrums over your jellyfish exhibit, the RGB Panorama Pro completely changes what you can do with aquarium lighting.

Control the color spectrum of your aquarium lighting with just one click. That’s the big advantage of RGB LED technology. You can instantly change the color, vary intensity and brightness, turn your lights on or off, or set your light on fade mode to slowly rotate through the entire color spectrum. The handheld remote works from up to 30 ft. away and is super simple to install. You can even add more punch by snapping on a polished reflector, effectively doubling the amount of light focused into your tank.

Each RGB Panorama Pro LED Module includes mounting hardware, each controller includes a control box and remote with connection wires (transformer sold separately.)

more than just blink. I added bits for a connector and regulating the power from 5v for the Atmega168 to 3.3v for LCD, accelerometer, etc.

I messed up the 3.3v voltage regulator and took a few tries bending the pins different ways before getting to work.

Basically, this module is the same as the previous module, the Pentagon Module [#1]. The difference is that the angles radiate from the middle of the bottom edge towards the left and right edges of the square paper. The assembly is very loose and I had to use paper clips to temporary hold on to the modules. The assembled model will also have a large pentagonal hole in the centre. I reduced the hole by folding in part of the top edge,

The Zeplina Power Module was created to power the worlds largest zeppelin, this piece was destined for stardom as an epic event in history. However, its extreme weight and the fact it was mounted at the front of the zeppelin meant that the nose couldn't get of the ground, even with the excessive amount of power it produced. The zeppelin cruised along, bum in the air, nose to the ground like a dog sniffing out the trail of dragged sausages. The zeppelin company refused to pay for the item, so I turned it into a lamp and this (almost) piece of history is for sale!

for Talisman's Claymore platform.

Installation by SSCV Saipem 7000

First module using the NELTC mainline standard. I really dig the wedge plate accent on the outside of the ballast. I am reasonably happy with the trees, but may tinker with the tops.

An Apollo Command Module on display at the Museum of Flight in Seattle

N scale town module -- various kits

An apartment building block and an open courtyard.

Technicians work on the Cygnus Service Module for the OA-4 ISS Cargo Resupply Mission in Orbital ATK's satellite manufacturing facility prior to shipping to the launch site.

This is my colab module of the Roguebricks Odyssey Colab at Bricking Bavaria in 2023. I build a part of the city of Athen in the ancient Greece with his typical white architecture, markets and live on the streets.

Apollo command module at the Kennedy Space Center in Florida. I believe it is Command Module "Kitty Hawk" from Apollo 14, but I may be mistaken. Technically an HDR picture, but without the "surreal" look that many get.

Basically, this module is the same as the previous module, the Pentagon Module [#1]. The difference is that the angles radiate from the middle of the bottom edge towards the left and right edges of the square paper. The assembly is very loose and I had to use paper clips to temporary hold on to the modules. The assembled model will also have a large pentagonal hole in the centre. I reduced the hole by folding in part of the top edge,

1.Each module joined and then twisted from same the point at the same angle making each piece vary in shape and orientation due to their position in 3 dimensional space.

2.Each module was then reconstructed with the "rebuilt" function of rhino with a 1 degree curve (i.e straight) in both u and v directions, thus making the module a developable surface.

3. each piece is unfolded into a flat sheet for printing using the UnrollSrf command. (explode=no, labels= yes) Layout and array of the unfolded surface is still manually performed. Labelling is necessary for assembly.

I wish i had more hands to cut out and assemble the entire twisted system but one can only stay up for that long before sleep takes over ( hint hint I WANT A LASER PRINTER at home)

Design for a stepper motor drive.

The stepper motor drive uses the TMC2100 modules from an old 3D printer (FlashForge Finder). I got this gift from a Fischertechnik forum member. The modules are controlled via a spi connection with my FPGA controller. The FPGA is connected to the Fischertechniek TXT Controller via an I2C line. The TMC2100 modules are in a fixed mode of the 3D printer, there is micro stepping used with 16 fine steps per step. Through the SPI connection I can send the ena, DIR, STEP, CFG0 and CFG4 pin. Because the modules are configured in 16 microsteps, the step pulses can be provided quite quickly. Therefore I controlled the SPI driver from a 4MHz clock so that only 13.5 usec is needed to scan all 24 inputs and outputs. This is much faster than the max step speed needed for the stepper.

The SPI goes to the FPGA chip. This is now programmed as a large I2C chip for the user. Besides this stepper driver there are also modules written for 16 motors, 72 inputs, 36 outputs, and 32 servo motors. All inputs can handle fairly fast pulses especially for quadrature encoders. The motors can run in 5 different modes and operate autonomously. The external I2C user only needs to send a few commands. Timing is no problem at all because the FPGA works much faster than the fastest micro controller. There are almost 1000 bytes of registers provided to support all functions. On the Fischertechnik side I have written a full lib to support all these functions. Through the Robopro software you can now write a program in a few minutes to the motors, servo steppers controls, reads inputs, status reads output line controls. I will give you more information about this later, but this data is so extensive that writing the manual takes a lot of time.

youtube video: youtu.be/0HRdaIm48Q0

Design for a stepper motor drive.

The stepper motor drive uses the TMC2100 modules from an old 3D printer (FlashForge Finder). I got this gift from a Fischertechnik forum member. The modules are controlled via a spi connection with my FPGA controller. The FPGA is connected to the Fischertechniek TXT Controller via an I2C line. The TMC2100 modules are in a fixed mode of the 3D printer, there is micro stepping used with 16 fine steps per step. Through the SPI connection I can send the ena, DIR, STEP, CFG0 and CFG4 pin. Because the modules are configured in 16 microsteps, the step pulses can be provided quite quickly. Therefore I controlled the SPI driver from a 4MHz clock so that only 13.5 usec is needed to scan all 24 inputs and outputs. This is much faster than the max step speed needed for the stepper.

The SPI goes to the FPGA chip. This is now programmed as a large I2C chip for the user. Besides this stepper driver there are also modules written for 16 motors, 72 inputs, 36 outputs, and 32 servo motors. All inputs can handle fairly fast pulses especially for quadrature encoders. The motors can run in 5 different modes and operate autonomously. The external I2C user only needs to send a few commands. Timing is no problem at all because the FPGA works much faster than the fastest micro controller. There are almost 1000 bytes of registers provided to support all functions. On the Fischertechnik side I have written a full lib to support all these functions. Through the Robopro software you can now write a program in a few minutes to the motors, servo steppers controls, reads inputs, status reads output line controls. I will give you more information about this later, but this data is so extensive that writing the manual takes a lot of time.

youtube video: youtu.be/0HRdaIm48Q0

Bluetooth Module!! This needs to be added to an OOPic R board

First module using the NELTC mainline standard. I really dig the wedge plate accent on the outside of the ballast. I am reasonably happy with the trees, but may tinker with the tops.

How to find information about built-in kernel modules on Linux

If you would like to use this photo, be sure to place a proper attribution linking to Ask Xmodulo