RESCO glider kit 1990mm - Instruction manual

Introduction[edit | edit source]

Precautions[edit | edit source]

This RC model is not a toy. Use it with care and strictly follow the instructions in this manual.

Assemble this model following strictly these instructions. DO NOT modify or alter the model. Failure to do so, the warranty will lapse automatically. Follow the instructions to obtain a safe and solid model at the end of the assembly.

Children under the age of 14 must operate the model under the supervision of an adult.

Assure that the model is in perfect condition before every flight, taking care that all the equipment works correctly and that the model is undamaged in its structure.

Fly only on days with a light breeze and in a safe place away from any obstacles.

The model you build and fly is not a toy! Although it may seem light and slow in flight, it is capable of causing injury or other damage if mistreated. It is up to you whether you build the model properly, fly properly and continue to fly in accordance with common practice and rules (and common sense). If you are just getting started with aircraft models, ask for advice from your model shop or an experienced modeller at your local modelling club to find a good instructor.

You must build the model according to the instructions. Do not alter or modify the model, as doing so may result in an unsafe of unflyable model. Take time to build straight, true and strong. Use proper radio and other equipment that is in first class condition, properly install all the components and test their correct operation before first and any further flight. Fly the model only with competent help from a well experienced modeller if you are not already an experienced RC pilot.

Specification[edit | edit source]

Recommended RC equipment[edit | edit source]

• Rudder and elevator servo: Hitec HS-53 2×
• Spoiler servo: Hitec HS-65MG, Dymond D47
• Receiver battery: Panasonic Eneloop AAA 800mAh 4.8 V pack

Recommended glues[edit | edit source]

Unless stated otherwise, use medium thick cyanoacrylate (CA) glue. D-box sheeting and wing ribs are better to be glued using a water-resistant white aliphatic resin (alternatively, you can use this sort of glue for most of wood-to-wood joints). The highly loaded parts (wing roots, wing main spars, firewall etc.) should be glued together using 30 minute (or slower) epoxy offering high strength and enough time for the correct positioning.

Tools and accessories[edit | edit source]

• Very sharp modeller's knife (e.g. Excel 16001 with no. 11 blades)
• Scissors
• Electric drill with drill bits
• Wire cutter
• Long nose pliers
• Screwdrivers
• Razor saw
• Sandpaper no. 80, 100, 180, 360–400
• Needle files
• Clothing pegs
• Modeller's pins
• Epoxy mixing stick and vessel
• Masking tape, clear sticky tape
• Rubbing alcohol (for cleaning up excessive epoxy)
• Paper tissue or soft cloth (for cleaning up excessive epoxy)
• Straightedge with scale
• Square edge
• Thin clear plastic film (for protecting the building plan)
• Permanent marker
• Modeller's sealing iron, heat gun (for covering)
• Lightweight balsa filler

Model assembly[edit | edit source]

Tail surfaces[edit | edit source]

• Trial fit the parts of the horizontal stabilizer, elevator, fin and rudder – no glue yet! Sand as necessary to obtain perfect fit. (Fig. 1)
• Roughen the surface of the 3×0.5mm carbon spar using no. 150 sandpaper and glue it with medium CA to the trailing edge of the fin. (Fig. 2)
• Glue together all the parts using medium CA or aliphatic resin. (Fig. 3+4)

Fuselage (glider version)[edit | edit source]

• Trial fit the parts of the fuselage – no glue yet! Sand as necessary to obtain perfect fit. (Fig. 5)
• Glue the ply reinforcement and balsa triangle stocks to the fuselage sides. Glue together the canopy. Glue the canopy magnets before final sanding. Please do not forget to check and mark the polarity of magnets first – they must attract each other. (Fig. 6+7)
• Glue together the front part of the fuselage. Do not forget to sand the edges of the formers to the shape. (Fig. 8)
• Epoxy the wing nut plate with nuts already glued and the tail boom holding formers in place. (Fig. 7+8)
• Glue the nose cone parts in place and sand them to the required shape using the supplied template. (Fig. 8+9)
• Partially cut (ca 1 mm deep) and crack the fuselage sides along the rear edge of the rear fuselage former in order to create a conical transition between the fuselage and the tail boom (the cut line is to be soaked with thin CA before the final sanding). Slide the tail boom fairing ring and the rear fuselage ring onto the tail boom tube (on the end without notches). Insert the tail boom into the fuselage (no glue yet – it will be glued only after the final sanding and covering of the fuselage). Trial fit all the parts and sand carefully to obtain a tight fit; the fairing matching the rear edge of the fuselage. The rear fuselage ring tack glue to the fuselage (do not glue it to the tail boom) and the fairing ring glue to the tail boom. (Fig. 10+11)
• Glue the upper and lower sheeting of the fuselage; do not forget to epoxy the tow hook plate. (Fig. 9+10+11)
• Attach the canopy to the fuselage and sand everything smooth. (Fig. 9+10+11)
• Locate the towhook. Cut the opening for it in the lower part of the fuselage and drill the holes for the fixing screws. (Fig. 12)
• Assemble (no glue yet) the horizontal tailplane pylon consisting of the Lite Ply core with tailplane fixing nuts (M4 front, M3 rear), 4 mm balsa sides and Lite Ply tailplane seat. Insert the pylon into the corresponding notch in the fuselage. Trim if necessary, open up the elevator push rod tunnel. Once satisfied, epoxy together the Lite Ply core with the balsa sides and sand to shape using the supplied Lite ply jig. Epoxy the tailplane seat in place. (Fig. 47A+47B+47C)

Fuselage (electric version)[edit | edit source]

• The building sequence of the electric version fuselage is basically the same as with the glider version except for the firewall and nose. Epoxy the firewall in place and sand the nose to the desired shape matching your spinner. (Fig. 13-15)
• Before you epoxy the firewall in, make sure the openings and holes in the firewall match your motor – make any changes as necessary or cut a new firewall to match your motor perfectly. (Fig. 13)

Wing centre section[edit | edit source]

• Epoxy together the wing central ribs. Insert 3 mm beech dowels into the holes in order to obtain correct match. (Fig. 16+17)
  
  Note: Make a left and right pair of ribs.
• Epoxy the wing fixing bolt plate between the central ribs. (Fig. 18)
• Epoxy together the parts of the main spar shear webbing. The short 0.8 mm ply joiner (with a hole in the centre) to the front side, the long joiner to the rear side. Make bays for the wing carbon joiner. Epoxy together front (shorter) 0.8 mm ply plate, 5 mm ply central plate and rear 0.8 mm ply (longer, slanted edge) plate. Prevent the epoxy hardening inside the bays – put the parts together with the carbon joiner inserted, then immediately remove the joiner (do not forget cleaning the joiner using a paper tissue and rubbing alcohol before the glue sets). (Fig. 19–22)
• Slide all ribs onto the mains spar shear webbing (no glue yet!). Bind the joiner bays with the provided Kevlar thread and soak with medium CA. (Fig. 23+24)
• Insert the rear spar, trial fit the leading and trailing edges. Sand to fit if necessary. Once satisfied with the fit, glue all the parts of the wing centre section with medium cyano over the building plan protected with a sheet of thin clear plastic film (you might find better gluing ribs to the main spar shear webbing with an aliphatic resin). (Fig. 25–27)
• Glue the lower 8×2 mm spruce stick main spar in place.
• Edge glue together the upper D-box sheeting (1.5 mm balsa) and the upper 8×2 mm spruce stick main spar. Once cured glue it to the wing using aliphatic resin. (Fig. 28–29)
• Bevel both two end ribs of the wing centre section using the supplied 7° dihedral jig. Then glue the 3 mm Lite Ply end ribs with magnets. (Fig. 30)
• Glue the air brake frame to the upper side of the wing and sheet the space between the central ribs with 1.5 mm balsa. Cut the openings for the wing fixing bolts. (Fig. 31)
• Epoxy the central half rib with the wing alignment pin and sheet the space between the central ribs with 1.5 mm balsa. Cut the openings for the wing fixing bolts. (Fig. 32)
• Glue the reinforcements square to the 2.5 mm balsa air brake. (Fig. 33)
• Fine sand the entire wing centre section (including the air brake).

Wing outer panels[edit | edit source]

• The wing outer panels are to be constructed in the same manner as the wing centre section; the main difference is that the inner part and the outer winglet are built as one part on a flat surface. Once the structure is finished, you will cut it between the end/root ribs, bevel to obtain the correct dihedral and glue together. (Fig. 34+35)
• Glue together both two wing outer panels over the building plan protected with a sheet of thin clear plastic film (remember – you are building left and right wing panels!). Please note, the inner spars are made of spruce sticks, whilst the winglet spars are made of balsa sticks.
• Glue the wing tips. Bevel the ends of the main spar sticks and glue them to the wing tips. (Fig. 36+37)
• Glue 2.5 mm balsa triangular wing gussets. (Fig. 38+39)
• Fine sand the entire wing outer panels.
• Cut off the outer winglets between the end ribs. Bevel the end ribs using the supplied 8° dihedral jig. (Fig. 40)
• Epoxy the wing panels and winglets together. (Fig. 41)
• • Bevel the root ribs of the wing outer panels using the supplied 7° dihedral jig. Trial fit the carbon wing joiner into the respective bays. There should be a tight fit, no play. If there is a significant play, put some epoxy to the appropriate area of the joiner and sand as necessary once the glue hardens. (Fig. 42+43)
• Glue the 3 mm liteply root ribs with 3 mm beech alignment pins. (Fig. 44+45)
• Prepare everything for the airbrake servo installation. Glue the fibreglass plate to the lower surface of the airbrake and the liteply magnet holder to the rear of the servo bay. (Fig. 46)
• The spoiler servo is to be installed using a balsa spacer (not supplied in the kit) - depending on the dimensions of your servo. The spacer + servo must not be higher than the wing ribs. It may not obstruct the spoiler when closed (do not forget to take in account the double sided foam tape you will use to secure the servo!). Apply epoxy or medium cyano to the servo spacer (if used) and the entire balsa lower sheeting of the servo bay in order to be sure the double sided foam tape will stick.

Covering[edit | edit source]

• Thoroughly sand the surface of all parts with no. 360–400 sandpaper and carefully vacuum all the dust (the iron-on film does not stick well to a dusty surface. The dust also contains hard grains released off the sandpaper capable to ruin the smooth coating of your sealing iron quickly).
• Use as light iron-on film as you can get (transparent Oracover, Oralite etc. – not supplied in the kit). Follow the instruction manual supplied with the covering film of your choice please.

Hinging the control surfaces[edit | edit source]

Use strips of a high quality hinging tape (available in hobby shops) or strips of the same iron-on film you used for the covering. Remember to apply the tape with the control surface deflected to the limit in order to get free movement of the particular control surface.

Tail surfaces and tail boom installation[edit | edit source]

• Attach the wing centre section to the fuselage and the horizontal tailplane to the tailplane pylon. Secure them with nylon bolts. Insert the tail boom with attached horizontal tailplane into the fuselage (no glue yet). Check again that the fuselage is straight. Align the wing and the tailplane with their trailing edges parallel. Once satisfied, epoxy the tail boom and the tailplane pylon in place. Before the glue hardens double check the correct alignment of the wing, fuselage and tailplane.
• Carefully cut the end of the tail boom in order to open the notch for the fin (trim as necessary – beware of cracking the tube). Use medium CA to glue the fin into the tail boom; be sure it is square to the horizontal tailplane.

Pushrod installation (Fig. 47D)[edit | edit source]

• Tack glue the pushrod tubes to the 1.5 mm balsa pushrod tube holder.
• Tack thick cyano to the balsa and insert the pushrod tubes into the carbon fuselage tube (with a little help of pushrod strings).
• Insert the pushrod strings into the respective tubes from the tail end.

Servo installation[edit | edit source]

Rudder and elevator servos installation (Fig. 48)[edit | edit source]

• Make a "Z" bend on the end of the pushrod and fit it to the servo horn.
• Alternatively you can use a closed loop of a Kevlar thread (not supplied in the kit) to hook the rudder – it might save some weight. In that case you will need to install just one pushrod for the elevator.

Spoiler servo installation (Fig. 49)[edit | edit source]

• The spoiler servo is to be installed using a balsa spacer (not supplied in the kit). The thickness of the spacer depends on the dimensions of your servo. The spacer + servo must not be higher than the wing ribs (in may not obstruct the spoiler when closed).
• Glue the fibreglass plate to the spoiler.
• Glue the magnets to the spoiler and wing using the supplied liteply holder.
• Please check the polarity of magnets first – they must attract each other.

Pushrods and towhook (Fig. 50)[edit | edit source]

• The pushrod tubes are to be located over the liteply plate.
• Thread them through the holes in the former next to servos.
• Install the towhook to the pre-drilled holes.

Wing root rib (Fig. 51)[edit | edit source]

• Glue the magnets using 5 min epoxy.

Pushrod installation – the tail end (Fig. 52)[edit | edit source]

• Trial fit the rudder and elevator horns (no glue yet), bend the ends of pushrod strings to the "L" shape and thread them through the hole in the horn. Once satisfied, cyano the horns into the rudder and elevator.
• Please note the servo arms have to be square to the pushrods in the neutral.
• Glue the end of the rudder pushrod tube to the fuselage.
• The end of the elevator pushrod tube remains free, no glue here.

Towhook (glider version) (Fig. 53)[edit | edit source]

• Keep the recommender CG position 78–82 mm behind the wing leading edge.
• Set the towhook 10 mm in front the CG for the first flight.
• You have to loose the front screw in order to move the towhook.

Power system installation (electric version) (Fig. 54–56)[edit | edit source]

• Fit your motor using appropriate screws to the firewall; secure the ESC and power pack using Velcro tape into the cockpit. With your RC set on test whether the motor rotates in the correct direction (counter clockwise when looking from the front) If it not the case, change the setting of your ESC or swap any two of the three cables between the motor and ESC. Fit 30 or 32 mm spinner with blades corresponding to your motor and battery set-up.

Spoiler (Fig. 57)[edit | edit source]

• The servo must be located as high as possible – as close to the spoiler as possible.
• Install the servo using double sided foam tape.

Recommended control surface throw, CG position (Fig. 58)[edit | edit source]

• CG Position: 78–82 mm
• Rudder: ±60 mm
• Elevator: ±10 mm
• Spoiler: -40 mm
• Brake → Elevator mix: -5 mm elevator at full spoiler

Flying[edit | edit source]

Be sure you are using fully charged batteries. Now (and before any further flight again) check correct function of whole radio equipment, motor and moving of control surfaces. Be sure any part of flight equipment cannot move during flight. We strongly recommend making a range check (see your radio instruction manual for details).

The first flight: Wait for a calm day. Fly only on a safe site as a RC club flying field. Glider will be very happy on your favourite slope on a calm day. The very light lift will allow perfect fine trimming out.

Glider: Switch your transmitter and then the receiver on and check all the working systems one more. Facing INTO the wind hold your transmitter in one hand; grip the model in the other hand near the centre of gravity. Hold it at head level and give the model a fairly powerful push exactly into wind; wings level, nose slightly down. Your model should now glide in a long, flat and straight path without needing any help from you. Use the controls gently if necessary, and adjust the trim tabs until your RESCO glides above described way. Now check the position of control surfaces. Set length of pushrods to bring back trim tabs on your transmitter to central position if necessary (we strongly recommend doing it in any way). Check again gliding of your RESCO. Now you are ready to make your first bungee launch. Always use a bungee set appropriate to the size (100–150 m) and weight of your model!

Electric version: Switch your transmitter and then the receiver on and check all the working systems once again. Launch your RESCO with throttle fully open INTO the wind. During climbing be gentle on the controls, try to keep the model flying into the wind until you have about 100–150 metres of altitude. Climb slowly - too steep climbing may cause the model will stall and fall to the ground. You are at 150 metres - this is time to trim out your RESCO at full power. After everything is OK - it means the model at approx. 50–60 % of full throttle flies straight without turning, descending or ascending (if your RESCO already tends to ascend you will have to increase motor down thrust), turn the motor off and test RESCO's gliding characteristics.

Keep your RESCO into the wind and observe its flight. If turns without power right (although under power it kept the straight direction) it will be necessary to increase motor right side thrust and vice versa. If descends too much without power (although under power it kept the level flight) you will have to increase motor down thrust (assuming the centre of gravity is correct! - check it after landing).

Final fine tuning[edit | edit source]

During next flights trim out your RESCO to find optimal setting - safe climbing and good gliding - it is a compromise, of course. You might find useful programming a spoiler → elevator mix (if your radio allows) that will eliminate the nose pitching when the spoiler is deployed. In general the CG position should be located between 78–82 mm behind the wing leading edge. By moving the CG back you get better gliding performance whilst reducing the stability. It makes your model more sensitive on controls and increases the model reaction on thermal. The back CG position makes the model more difficult to fly and requires more attention from you, while a nose heavy model is easier to fly but you will lack the performance. We recommend starting with the CG at 78 mm behind the leading edge. Beyond 82 mm the increasing lack of stability prevails over the gain of gliding performance.

Parts list[edit | edit source]