1/18 scale Bölkow Bö-102 Helitrainer scratchbuilt model

[Nick_Karatzides]

1/18 scale Bolkow Bo-102 Helitrainer scratchbuilt model

The Bölkow Bö-102 Helitrainer was an unusual ground-based helicopter training aid that was developed and built by Bölkow of Germany in the late 1950ies. It embodied all essential elements of a conventional helicopter, but was mounted on an articulated gantry to allow a student controlled experience of helicopter systems. Designed to be mounted on a swivelling captive rig the Bölkow Bö-102 Helitrainer allowed trainee pilots to practice procedures such as engine starting, rotor engagement and manipulation of the flight controls. Many of the Bö-102's components, including the single bladed fiberglass main rotor were used in the company's next design, the Bölkow Bö-103.

 

 

Looks like a kiddie heliride, a toy for big boys huh?

 

 

Rolled out in 1957, this Helitrainer was powered by a Hirth 3-cylinder / 2-stroke 40hp ILO L3X375 piston engine rated at 30 kW, driving a simple 21 foot one-bladed fiberglass rotor with a counterweight. In all 18 of these Helitrainers were built operating throughout Europe, training military helicopter pilots. Although unable to fly, they were ideal for the teaching of hovering techniques and were replaced by dual trainer helicopters.

 

 

The Bölkow Bö-102 Helitrainer offered a variety of advantages for a safe helicopter training and was developed in land and water based versions, both of which were semi-captive. The first training section was conducted on this model mounted on a boogie. It facilitated the training of starting, tuning the rotary speed, taking off, hovering, turning, and landing. Simple exercising device for beginners’ training. Safety risk minimized by captivation, yet limited flight maneuvers possible. This feature allowed the helicopter to rise to a height of 2m (6ft), turn around a vertical axis and dip at up to 6° but prevented it from flying outside these limits.

 

Edited August 28, 2018 by Nick_Karatzides

[Nick_Karatzides]

Unfortunately, the Bölkow Bö-102 Helitrainer did not gain general approval because of its costs being nearly as high as a small helicopter. Luckily, very few of them, are still surviving as public display exhibit at the Hubschraubermuseum Bückeburg Germany, the helicopter museum Weston and in Rota museum Spain. Parts of Bö-102B were found at a freight forwarding company in Vlotho and donated to the helicopter museum in Bückeburg. The workshop team, managed to restore few of these experimental helicopter training devices.

 

 

Technical data & general characteristics

• Type designation: Bö-102B Helitrainer
• Usage: Single seated captive helicopter trainer for basic helicopter training
• Year of construction: 1958
• Manufacturer: Bölkow Entwicklungen KG
• Country: Germany
• Length: 5.68m
• Main rotor area: 34.8m² (374feet²)
• Main rotor diameter: 6.58 m (21ft 8in)
• Powerplant: 1 x Hirth 3-cylinder / 2-stroke 40hp ILO L3X375 piston engine rated at 30kW
• Power: 40shp
• Gross weight: 770kg (1697lb)
• Take off weight without a platform: 325kg
• Crew: 1 student pilot & 1 trainer (on additional seat)
• Speed: Handcuffed on the ground
• Range: Stationary base coach

Edited August 8, 2018 by Nick_Karatzides

[Nick_Karatzides]

CHAPTER I - Cabin & bubble canopy construction

 

To produce a thin-skinned, right-to-scale cabin, a solid rock one-piece "image cast" of the bubble typed cabin should be made of modeling clay & epoxy first and then try to reproduce a copy by vacuum forming the image cast. Using the following modeling clay item, found in my local supermarket. It's an air-drying modeling clay ideal for scale modeling and shaping. According to the instructions, it can be easily formed into shape, become solid rock withing few hours, re-filled or sanded if necessary and painted or lacquered. That sound quite good to me and similar to the well known Milliput epoxy putty, with the only difference that the 500g air-drying modeling clay pack cost only 1£, instead of 100g Milliput epoxy putty which cost 5£. That makes the new found air-drying modeling clay, about 25 times cheaper than Milliput epoxy putty and that's a good reason for me to give it a chance.

 

 

I formed the basic shape of the bubble typed cabin, by picking small quantities of this modeling clay with a metal spatula and applying the air-drying modeling clay. It felt too soft and very easy to spread the material nicely. I didn't want to care too much and try forming and shaping the clay, because I was planning to add epoxy putty and sand to make a nice shinny finish. After all, I had no idea how much available time I had, before the material start becoming hard and difficult to handle.
 

 

The specific polyester filler I used to apply over the clay, comes with the proper catalyst which provides a solid rock build and approximately 3 to 5 minutes time window to form it into shape. I prefer to use epoxy putty or polyester filler with fiberglass grains for special purposes, because:

 

• It becomes solid rock within only few minutes or seconds,
• it does not shrink and does not crack after months or years,
• you can pour to any shape that you want but you need to work fast because as soon as you mix it with catalyst cream approx 5%, you have limited time before becoming solid rock,
• you can also put additional layers of epoxy or polyester filler to build up,
• you can sand it, you can drill it, you can use any type of scale modeling glue, any type of primer or enamel / acrylic paint on it with no problem,
• can be purchased at any good crafts store into 250ml, 500ml, 1lt (comes with a tube of catalyst hardener) or bigger canisters and if you can't find it, fear not and try your local decent hardware store and finally...
• it is cheaper than dirt - estimated prices are £3 to £10 depending the canister size, the quality, if contains fiberglass grains for maximum strength etc.

 

Keep in mind that the chemical reaction after mixing the polyester filler with the catalyst hardener, produces some heat that possibly effect on thin plastic parts, so test it first before try it on your scale model. I don’t think that the produced heat is more than Fahrenheit 110, but better watchout. Remember that epoxy materials are dangerous when breath or shallow and could result skin, eyes or lungs problems or even cancer when used for long period with no precaution measures. Always keep in mind, that a powerful vacuum system to suck away the epoxy dust should be used all time to keep the workbench area clean while sanding or milling epoxy or resin materials. Using an issued breathing mask and a pair of surgery latex gloves to prevent dust contact with lungs and fingers while sanding or milling epoxy, is also an important matter that you should seriously take care of! My recommendation is to also wear an overall working suit (as I do) to keep your clothes dust free while sanding epoxy. Some people might find it too much, but I wouldn't like to bring epoxy dust & grains from my work bench into living room and my beloved.

 

As long as this subject relates to our physical health and the physical health of all family members and loved ones who may come into contact with the materials we use in scale modeling, we need to be very careful and suspicious. We all need to be informed on whether it is safe or not about the materials used in scale modeling and what can we do to avoid or minimize the risks of everyday contact. Some of you may wonder if the epoxy putty or dust from the epoxy sanding is actually hazardous to health or if it really causes harm to human body. Some might say that all these are just an urban legend and a pseudo story based on Goebbels theory that has finally become accepted as an illusionary reality. Some might even support the view that these products had passed controls and been inspected by independent and non-controlled health organizations and committees and that if these products were truly dangerous, the companies would not be allowed to produce and would never be free sold in usual drugstore, where ordinary Joe might buy it. Well, should we sleep quietly at night, knowing that anything surrounds us, are truly inspected by independent and non-controlled health organizations and committees? Should we or not? Because as far as I know, the same organizations and committees are those that allow the free sale and use of other products such as cigarettes, asbestos sheets, hazardous petrochemicals etc to millions ordinary Joes daily! Should, I assume that this situation might happens, because nobody has informed them that such products, do kill slowly and painfully? On the other hand, there are thousands of publications in medical conferences and seminars to warn of the dangers that may cause the powdered epoxy resin and the dust produced from the epoxy resin sanding. There are thousands of studies showing a direct relationship of lacquer solvents, toluene thinner, thixotropic agents etc, with serious damage to the human body - including cancer. Is it a well organized theory by Goebbels himself? Surely no! Should we ignore all these warnings? Should we believe that the good companies who only care about consumer’s health and not bothered about the ephemeral economic gain at the expense of our health, check everything thoroughly and would never allow dangerous products in the open market?

 

Some of you may consider an exaggeration to suggest the use of breathing mask, latex gloves and special clothing during the epoxy materials processing, but let me explain my point of view, within only few words.

 

• Having survived by the 1986 radioactive fallout of Chernobyl, which dramatically increased the incidence of deaths due leychamia in Northern part of Greece where I grew up and having lost 2 of my classmates from school because this reason,
• Having suddenly acquired (me and tens of thousands of fellow citizens in my town, at the exact same time) some strange allergies occurred in the late 90ies, just after the Allied uranium shells bombing in Serbia, which is just few kms away from the city I live,
• Having lost at the age of 46yo, my mentor in scale modeling and good friend who (coincidentally?) worked continuously in an environment saturated with epoxy resin powder & lacquer thinner fumes,
• Having lost a second very good friend and highly skilful figure and miniature builder (perhaps the best in Greece at that time) for similar reason...

 

…I think it’s not so good idea to keep pushing my luck and I decided to follow some protection rules. Under no circumstances I propose to live the rest of our lives locked in a sterile glass - this would not be life. I would strongly suggest to live our life as intensely as possible. But keep in mind, that the wise parachutist, always checks thoroughly his main & reserve gear before each jump and does not behave casually leaving his life to luck factor, just because he was lucky so far and didn’t happen to face an emergency. "SAFETY FIRST " became my personal logo and whoever wants, is free to follow.

 

When the cast used as an "image" of the bubble typed cabin, was filled with a layer of polyester filler and had enough time to polymerize and get solid rock, it was sanded carefully to get the right shape. Finally, the cast was sprayed with white shiny finish to help me spot any scratches or defects.

 

Edited August 8, 2018 by Nick_Karatzides

[Nick_Karatzides]

In my previous WIP article about the 1/18 scale Jukka Tervamäki Engineering JT-9T autogyro project, I explain in a very detailed manner, how to build a  vacuum forming device, starting from scratch and using materials that can be found in your local super market. If you are not aware how to build a scratchbuilt vacuum form, please feel free to read it as I described and it might be useful for you.

 

Edited August 8, 2018 by Nick_Karatzides

[Nick_Karatzides]

Heat your electric oven to some predetermined level, whatever works and start heating the plastic sheet. I have never tried this with a gas one, so use caution if you do! Once the plastic gets warm, you’ll notice it will droop down. When you think the plastic is soft enough, fire up the vacuum cleaner, take the plastic from the oven and thrown the sheet on the vacuum former. The plastic will nicely form around the moulds. This will take some practice and sometimes a mould tips over or the plastic won’t form properly over the mould (folding around edges). This is also the part where I should warn you that you can burn your fingers - I highly recommend Nomex Aramid flame resistant MilSpec gloves, which I personally use for the job. I buy large plastic styrene 50x30cm sheets for 0.5€ to 1.5€ each (depending width), not the more expensive styrene by Evergreen. When an attempt fails, I usually throw the sheet back in the oven and start again. Once you have the machine, you can make all kinds of things. You can make a lot of aircraft wings, airframe, panels etc out of a sheet like that. You can make the master molds from basswood, epoxy, polyester etc and the parts you make depend on how accurate the master molds are. The molds must be as accurate and detailed as necessary to achieve the results you are after. As you see in the following pictures, I tried white and clear styrene sheets too, in order to build the cabin by white styrene and the bubble canopy by clear.

 

I placed the frame into the preheated electric oven and I wait few critical seconds watching the plastic start heating. As soon as I noticed that it started drooping down, I removed the frame while wearingNomex Aramid flame resistant MilSpec gloves, to prevent finger burns. While the vacuum cleaner was already switched on, I placed the wooden frame with the pined plastic sheet on the vacuum former plate. The plastic nicely formed around the “virtual†airframe mould... and voila!
 

Using my X-acto knife, I removed the formed cabin pieces from the styrene white or clear sheets and tried some test fitting on the cast.
 

Edited August 8, 2018 by Nick_Karatzides

[Nick_Karatzides]

CHAPTER II - Instrument panel & cockpit construction

 

As written before, the Bölkow Bö-102 Helitrainer was a helicopter training aid that was developed and built to allow a student pilot controlled experience of helicopter systems. That's why the cockpit panel was so simple, that a 5yo child could operate. Three gauges on the instruments panel, few switches, a cyclic control stick and a collective. That's all! After all, it was not designed to fly, but only give a helicopter hover & flight feeling.

 

 

I started by cutting the cockpit’s floor shape in styrene and shape it as required to fit into the cabin.

 

 

Once I tried test fitting, I discovered that there was some tiny gaps between the cockpit's floor and the cabin. These gaps, should be filled. So, "mind the gap"!

 

Edited August 8, 2018 by Nick_Karatzides

[Nick_Karatzides]

To do so, some quantities of liquid modeling putty, filled between the gaping surfaces. In order to make the putty liquid and let it spread naturally and fill the tiny gaps, I mixed Humbrol putty with lacquer thinner. Because the lacquer thinner is volatile, the liquid putty mixture took about 45 minutes to get fully dry and be safe to sand - carefully of course. If you follow this method, be sure that you mix the lacquer thinner and the modeling putty into a metal or glass plate / canister, because the most plastic materials cannot stand it and melt. For this reason, keep in mind to use just the essential lacquer thinner quantity, in order to remain the mixture in liquid form, as it is presented at the following pictures.

 

 

The last liquid putty layer was applied using the Squadron MMD green putty instead of the general purpose Humbrol, because I personally find it better for final smooth details.

 

Edited August 8, 2018 by Nick_Karatzides

[LSP_Kevin]

Nick, yet another fantastic, ambitious and instructive scratch-build! And my heartfelt thanks for changing image hosts too - I can finally see them again!

 

In my previous WIP article about the /18 scale Jukka Tervamäki Engineering JT-9T autogyro project, I explain in very detailed manner, how to build a vacuum forming device, starting from scratch and using materials that can be found in your local super market. If you are not aware how to build a scratchbuilt vacuum form, please feel free to read it as I described and it might be useful for you.

 

Unfortunately, due to not being able to see your images from where they were previously hosted, I can't do that.

 

Kev

[Pfuf]

This is going to be fun really enjoyed the last build and great to see you make the effort to share your craftsmanship.

 

Real funny subject.

 

Johan

[Nick_Karatzides]

 

 

In my previous WIP article about the /18 scale Jukka Tervamäki Engineering JT-9T autogyro project, I explain in very detailed manner, how to build a vacuum forming device, starting from scratch and using materials that can be found in your local super market. If you are not aware how to build a scratchbuilt vacuum form, please feel free to read it as I described and it might be useful for you.

Nick, yet another fantastic, ambitious and instructive scratch-build! And my heartfelt thanks for changing image hosts too - I can finally see them again! Unfortunately, due to not being able to see your images from where they were previously hosted, I can't do that.

Kev

Kevin,

I've got good news for you and all the friends from Australia who could not see the uploaded pictures untill today. I did upload ALL the pictures in imageshack which as far as I know IS compatible with Australian internet providers. That means that all the pictures in the previous WIP article about the 1/18 scale Jukka Tervamäki Engineering JT-9T autogyro project (click HERE), SHOULD be now visible for you. The how-to topic about building a vacuum form device SHOULD be vissible too.

Please feel free to have a look by clicking HERE and give me a notice if something still is not right. Edited January 30, 2016 by Nick_Karatzides

[LSP_Kevin]

Please feel free to have a look by clicking HERE and give me a notice if something still is not right.

 

 

Kev

[Christian]

Hi Nick,

 

I am in Australia and can see your images now.

 

Looks great and interesting.

 

I learning so much about build scratching and vac forming.

 

Keep up the great working.

 

Kind Regards,

 

Christian

[Nick_Karatzides]

The Squadron MMD green putty, also used to create some minor details on the cabin’s back side, where the tail boom frame (tail boom construction will be explained later) joints will be later fitted. At last, I tried many test fit attempts with the tail boob, to ensure that I’ll not face any unpleasant surprises later.

 

 

An additional green putty layer applied and the cockpit surfaces carefully sanded to look as smooth as possible, before sprayed with Mr. Surfacer 1200 as a final touch.

 

Edited August 8, 2018 by Nick_Karatzides

[Nick_Karatzides]

The instrument panel is made of standard Milliput epoxy putty, which is popular among modelers and also useful in countless household & restoration applications. Switch board, tail rotor control pedals, cyclic control stick and collective lever are made of drilled & cut styrene plastic card. Wiring is made of 0.20mm diameter fishing line.

 

Edited August 8, 2018 by Nick_Karatzides

[Nick_Karatzides]

Using styrene plastic card, I cut the basic lines to form into the student pilot’s seat. The dimensions and the shape are based on actual Bö-102 pictures. Standard Milliput epoxy putty was used to simulate the pillow. Finally, the cabin sprayed with Humbrol light grey acrylic primer to show up any possible scratches that I did not spot so far.

 

 

Please keep in mind, that despite the fact that only 18 Bö-102s were produced, the available pictures show that there were many and obvious differences between them in several places. Different seats (some of them were not even seat), different cockpit and cabin colour, different fuel tank canisters, different tail boom frame construction, different landing pad and some of the Bö-102s, were not even equipped with landing skids. So, don’t be surprised if you witness differences.

Edited August 8, 2018 by Nick_Karatzides