robbe Boo Slope Glider 800mm Instruction Manual

June 1, 2024
robbe

robbe Boo Slope Glider 800mm

robbe-Boo-Slope-Glider-800mm-PRODUCT

Technical Data

  • Motor: Robbe RO-POWER ULTRA HP 320MAH 7.4 VOLT 2S 25(50)C
  • Battery: Robbe RO-POWER ULTRA HP 240MAH 7.4 VOLT 2S 25(50)C

Servos:

  • HR Servo: 1 x FS 135 X DIGITAL HV Servo
  • ELE Servo: 1 x FS 135 X DIGITAL HV Servo
  • QR Servo: 2 x FS 135 X DIGITAL HV Servo
  • WK Servo: Not specified

Adhesives

  • Klebstoff (Glue): SPEED Sekundenkleber Set 3-teilig
  • Epoxy resin: 5min ro-POXY 100g Kleber
  • Spannweite (Wingspan): 800 mm
  • Gewicht (Weight): Approximately 150 g (dry)
  • Profil (Airfoil): 39 mm von der Nasenleiste (from the leading edge)
  • Flugerfahrung (Flight Skill): Intermediate level required

Assembly
Follow the detailed step-by-step instructions provided in the manual to assemble the model accurately.

Flight Preparation
Ensure all components are securely attached and the battery is fully charged before flight. Perform pre-flight checks as per the manual.

Flight Operation
Operate the model in an open, clear area away from obstacles or people. Follow recommended flying techniques for optimal performance.

Battery Safety
Handle rechargeable batteries with care, follow charging instructions, and do not overcharge. Dispose of batteries properly as per safety guidelines.

FAQ
Q: What insurance coverage do I need for ground-based models?
A: Ground-based models are usually covered by personal liability insurance. Additional insurance or extension is required for aircraft models. Check your insurance policy (private liability) and take out suitable insurance if necessary.

INSTRUCTIONS AND USER MANUAL

PREFACE

BOO – Tiny little fun slope glider
Congratulations and thank you for choosing the BOO. With a span of 800 mm and 3-axis control the BOO is ideal for flying from the slope, sand dune or embankment. Small in size, yet designed for great fun. With its transport- friendly dimensions BOO fits easily on the parcel shelf of a car or, when dismantled, in the hand luggage on an airplane. The model promises the greatest fun in the smallest of spaces. The laser cut wooden parts are assembled and glued in just a few simple steps using the slot together and add glue principle. Please read these instructions carefully, even if you have already built many RC models. We have given a lot of thought to detailed solutions
in order to keep the construction effort as simple and low as possible without neglecting functionality. The model was developed with modern 3D CAD technology and the kit is manufactured with modern CNC technology. As a result you can be sure that the components fit together properly and there will be no nasty surprises during the assembly!
We wish you a lot of fun building your new BOO and especially afterwards when flying.

PLEASE READ THIS MANUAL CAREFULLY BEFORE YOU START ASSEMBLING THE MODEL.

FLIGHT INSTRUCTIONS

  • Before the first flight, observe the instructions in the „Safety Instructions“ section.
  • When flying the model, you should choose a day with as little wind as possible
  • A large, flat area without obstacles (trees, fences power lines etc.) is suitable for the first flights.
  • Please carry out a functional test of the drive train / power set and remote control.
  • After assembling the model on the airfield, check once again that all model components such as wing, tail units, wing mounts, engine, linkages, etc. are firmly and properly fastened.
  • For a hand start a helper should be present, who can throw the model with enough thrust into the air.
  •  The start usually takes place against the wind.
  • Do not stall the model near the ground
  • Do not initiate tight turns in the immediate vicinity of the ground.
  • Check the reactions of the model to the rudder deflections. If necessary, adjust after landing to increase or decrease the deflections accordingly.
  • The minimum flight speed must be at an adequate safety altitude.
  • Initiate the landing with sufficient speed

GENERAL INFORMATION

  • The model is designed for the components specified by us. Unless otherwise stated, servos and other electronic components are designed for standard supply voltage. Recommended cell count for Lipo batteries also refers to standard Lipos voltage of 3.7V per cell. If you use other servos, a different motor and controller, batteries, or propellers, please make sure they fit first. In the event of deviations, corrections and adjustments must be made by yourself.
  • Before starting construction, always put the servos into neutral. To do this, switch on the remote control and move the joysticks and trim buttons (save the one for the throttle) to the middle position. Connect the servos to the corresponding outputs of the receiver and supply them with a suitable power source. Please observe the connection diagram and the operating instructions of the remote control system manufacturer.
  • Do not leave your model in the blazing sun or in your vehicle for long periods of time. Too high temperatures can lead to deformation/distortion of plastic parts or blistering of covering foils.
  • Before the first flight, check the wing symmetry, tail unit and fuselage. All parts of the model should have the same spacing from the left and right wing or tailplane to the centre of the fuselage or the same angle.
  • If necessary, rebalance the propellers if vibrations are noticeable when the motor is running up.
  • Bubble formation in the covering foils normal to a certain extent due to temperature and humidity differences and can be easily eliminated with a foil iron or hairdryer.
  • For models in shell construction („full GFRP/CFRP“), burrs may occur at the seams due to the production process. Carefully remove them with fine sandpaper or a file.

GENERAL SAFETY INFORMATION

  • Be sure to read the safety instructions carefully before operating your model.
  • Always follow the procedures and settings recommended in the instructions.
  • If you are using remote-controlled model aircraft, helicopters, cars or ships for the first time, we recommend that you ask an experienced model pilot for help.
  • Remote-controlled models are not toys in the usual sense and may only be used and operated by young peo-ple under 14 years of age under the supervision of adults.
  • Their construction and operation requires technical understanding, careful craftsmanship and safety-conscious behaviour.
  • Mistakes or negligence during construction, flying or driving can result in considerable damage to property or personal injury.
  • Since the manufacturer and seller have no influence on the proper construction/assembly and operation of the models, these risks are expressly pointed out and any liability is excluded.
  • Propellers on aircraft and all moving parts in general pose a constant risk of injury. Avoid touching such parts at all costs.
  • Note that motors and controllers can reach high temperatures during operation. Avoid touching such parts at all costs.
  • Never stay in the danger area of rotating parts with electric motors with connected drive battery.
  • Overcharging or incorrect charging can cause the batteries to explode. Make sure the polarity is correct.
  • Protect your equipment and Models from dust, dirt and moisture. Do not expose the equipment to excessive heat, cold or vibration.
  • Use only recommended chargers and charge your batteries only up to the specified charging time. Always check your equipment for damage and replace defects with original spare parts.
  • Do not use equipment that has been damaged or got wet due to a fall, even if it is dry again! Either have it checked by your specialist dealer or in the Robbe Service or have it replaced. Hidden faults can occur due to wetness or a crash, which lead to a functional failure after a short operating time.
  • Only the components and accessories recommended by us may be used.
  • Do not make any changes to the remote control which are not described in these instructions.

SAFETY NOTE FOR MODEL OPERATION

Attention, danger of injury!

  • Always keep a safe distance from your model aircraft.
  • Never fly over spectators, other pilots or yourself.
  • Always perform flight figures in a direction away from the pilot or spectators.
  • Never endanger people or animals.
  • Never fly near power lines or residential areas.
  • Do not operate your model near locks or public shipping.
  • Do not operate your model on public roads, motorways, paths and squares, etc., but only in approved locations.
  • Do not operate the model in thunderstorms.
  • Before each flight, check your remote control system for sufficient function and range.
  • After flying, remove all batteries from the model.

Do not „aim“ the transmitter antenna at the model during operation. In this direction, the transmitter has the lowest radiation. The best position of the antenna is to the side of the model.
Use of devices with image and/or sound recording function:

If you equip your model with a video or image recording device (e.g. FPV cameras, action scams etc.) or the model is already equipped with such a device at the factory, please note that you could violate the privacy of one or more persons by using the recording function. An overflight or driving on private ground without the appropriate permission of the owner or approaching private ground can also be regarded as an invasion of privacy. You, as the operator of the model, are solely and fully responsible for your actions.
In particular, all applicable legal requirements must be observed, which can be found in the roof associations or the relevant authorities. Failure to comply can result in substantial penalties.

SAFETY INSTRUCTIONS FOR CONTROLLERS

  • Observe the technical data of the controller.
  • Observe the polarity of all connection cables.
  • Avoid short circuits at all costs.
  • Install or package the regulator so that it cannot come into contact with grease, oil or water.
  • Effective interference suppression measures on the electric motor with, for example, interference suppression capacitors
  • Ensure adequate air circulation.
  • Never reach into the turning circle of the propeller during start-up Risk of injury

Dealing with model aircraft and vehicles requires technical understanding and a high level of safety awareness. Incorrect assembly, incorrect adjustment, improper use or the like can lead to personal injury or damage to pro-perty. Sudden starting of connected motors can lead to injuries due to rotating parts such as propellers. Always stay away from these rotating parts when the power source is connected. All drive components should be safely and securely mounted during a function test. Use is only permitted within the scope of the technical specification and only for RC hobby applications. Before use, check that the speed controller is compatible with your drive motor or power source. Never operate the speed controller (correct speed controller) with external power supply units. Speed controllers should always be protected from dust, moisture, vibration and other mechanical stresses. Even splash-proof or waterproof equipment should not be permanently exposed to moisture or moisture. High operating temperatures or poor cooling should be avoided. The recommended temperature range should be approximately between -5°C and +50°C. Ensure proper connection and do not cause reverse polarity which would permanently damage the speed controller. Never disconnect the device from the motor or battery during operation. Use high-quality plug systems with sufficient load capacity. Avoid strong bending or tensile stress on the connecting cables. After termination of flight or driving operation, disconnect the battery to prevent deep discharge of the battery. This would cause permanent damage. For the BEC version of the controller, check that the BEC power of the device is sufficient for the servos used. Speed controllers should be installed as far away as possible from other remote control components. We recommend carrying out a range test before operation. We recommend regular checking of the controller for function and externally visible damage. Do not continue operating the controller if you notice any damage. The connection cables must not be extended. This can lead to unwanted malfunctions. Despite existing safety and protective devices of the device, damage may occur which is not covered by warranty. The warranty also expires if changes are made to the device.

Important information
The receiver system is powered by the built-in BEC system of the controller.
For commissioning, always move the throttle stick to the „Motor off“ position and switch on the transmitter. Only then connect the battery. To switch off always disconnect the connection battery motor controller, first then turn off the transmitter. During the functional test, move the servos of the rudders to neutral position with the remote control (stick and trimming lever on the transmitter to the middle position). Please make sure to leave the throttle stick in the lowest position so that the engine does not start. For all work on to the parts of the remote control, motor or controller, follow the instructions supplied with the units. Also read the instructions of the battery and the charger carefully before commissioning. Check the engine mounting bolts in the fuselage regularly for tightness.

SAFETY INSTRUCTIONS FOR RECHARGEABLE BATTERIES

  • Do not immerse the battery in water or other liquids.
  • Do not heat, throw into fire or microwave.
  • Do not short-circuit or charge with reversed polarity
  • Do not expose, deform or throw the battery
  • Do not solder directly on the battery
  • Do not change or open the battery
  • Only charge the battery with suitable chargers, never connect it directly to a power supply unit.
  • Never charge or discharge the battery or charger on a flammable surface.
  • Never leave the battery unattended during charging or discharging processes.
  • Never charge or discharge the battery in direct sunlight or near heaters or fire.
  • Do not use the battery in places subject to high static discharge.

All this can cause the battery to be damaged, explode or even catch fire!

  • Keep the battery away from children
  • Keep leaked electrolyte away from fire, as it is highly flammable and may ignite.
  • The electrolyte liquid should not get into the eyes, if it does, rinse immediately with plenty of clear water and then see a doctor.
  • The electrolyte liquid can also escape from clothes and other objects with a lot of water or washed off.
  • Observe the safety instructions of the battery manufacturer and the charger manufacturer.

WARRANTY

Our articles are equipped with the legally required 24 months warranty. Should you wish to assert a justified warranty claim, always contact your dealer, who is responsible for the warranty and the processing. During this time, any functional defects that may occur, as well as manufacturing or other problems, will be rectified.
Material defects corrected by us free of charge. Further claims, e.g. for consequential damages, are excluded. The transport to us must be free, the return transport to you is also free. Freight collect shipments cannot be accepted. We cannot accept liability for transport damage and loss of your consignment. We recommend appropriate insurance.

To process your warranty claims, the following requirements must be met:

  • Attach the proof of purchase (receipt) to your shipment.
  • The units have been operated in accordance with the operating instructions.
  • Only recommended power sources and original robbe accessories have been used.
  • There is no moisture damage, external interference, reverse polarity, overloading or mechanical damage.
  • Attach relevant information for finding the fault or defect.

DISCLAIMER

Robbe Modellsport cannot monitor compliance with the assembly and operating instructions or the conditions and methods for installation, operation, use and maintenance of the model components.Therefore, we accept no liability for losses, damage or costs arising from or in any way connected with incorrect use and operation.To the extent permitted by law, the obligation to pay damages, irrespective of the legal grounds, shall be limited directly to the invoice value of the claims arising from the event causing the damage.

INSURANCE
Ground-based models are usually covered by personal liability insurance. Additional insurance or extension is required for aircraft models. Check your insurance policy (private liability) and take out suitable insurance if neces- sary.

CONFORMITY
Robbe Modellsport hereby declares that this device complies with the essential requirements and other relevant regulations of the corresponding CE directives. The original declaration of conformity can be found on the Internet at www.robbe.com in the detailed product view of the respective device description or on request. This product can be operated in all EU countries.

DISPOSAL
The sign of a crossed-out dustbin means that the product is not allowed to be disposed of with normal household waste due to certain ingredients. Dispose of the device at your local municipal collection point or recycling centre. This applies to all countries of the European Union and other European countries with a separate collection system.

BOX CONTENT

| | Nr./ .|  Accessories needed /| : KIT|
---|---|---|---|---|---
Motor| –| –| –|
Regler /| –| –| –|
Battery| 73177313|   ULTRA HP 240MAH 7,4 VOLT 2S 25(50)C| –|
 Servo| 9128| 1 x FS 135 X DIGITAL HV Servo| |
Servo RUD| 9128| 1 x FS 135 X DIGITAL HV Servo| –|
Servos QR| 9128| 2 x FS 135 X DIGITAL HV Servo| –|
Servos WK| –| –| –|
 cableRallonges servos| –| –| –|
Klebstoff| 5019| SPEED Sekundenkleber Set 3-| –|
| 50600| 5min ro-POXY 100g Kleber / adhesive /|

|
Sonstiges Other Autres| –| Wood glue /| –|
Autres| –| 1x / Covering material /| –|
Spinner /| –| –| –|
/ Propeller| –| –| –|
Fernsteuerung / TX / Emetteur| –| min. 4 / /| –|
EN|
/ RX| –| min. 5 /| –|
Box content|

|

TECHNICAL DATA

robbe-Boo-Slope-Glider-800mm- \(1\)

Span 800 mm
Length
Gewicht (leer) ca.
Gewicht (flug) ca. ab 150 g
7,8 dm²
Wing loading from Charge 19 g/dm²
Niveau requis pour le vol Advanced
Schwerpunkt C.G. 39 mmvon der from the leading edge du bord
Elevator yes
--- ---
Rudder yes
Ailerons  yes

Flaps

| no
Motor

| no

Caution :
High-resolution images of the construction steps (PDF: „High-resolution images of the construction steps“) are available for download on the product page at: www.robbe.com

GENERAL ABOUT THE MODEL

The construction of the BOO can be built quickly and easily thanks to CNC- laser cut parts. With the help of these building instructions, the BOO is as- sembled without the need of a plan. The construction is quick and easy and can be carried out over a few evenings. The two halves of the wing and the V-tail are assembled directly on the building board. The final assembly takes place on a building jig which is included in the kit. This ensures all compon-ents are precisely aligned with one another. When finished the 2-piece wing and the V-tail can easily be removed. This creates a very transport-friendly model.

Recommended R/C equipment

  • 4-channel transmitter, with dual rates and expo
  • Micro receiver with normal range (e.g. JETI R5L / Futaba R2106GF)
  • Sub-Micro Servos, 4x 9128 FS 135 X DIGITAL HV servo
  • Battery, LiPo 2S, 200 – 400 mAh, 7.4V (e.g. Robbe Ro-Power # 7317 / 7313)

Materials needed

  • Film for covering, approx. 60 cm (e.g. ORALIGHT ® iron-on film)
  • Lead approx. 10 g (for CG adjustment)

required

  • Building board
  • Sharp knife
  • Side cutters
  • 100 and 240 grit sandpaper
  • Sanding block
  • White glue
  • Robbe Super Glue „Speed“ (thin and medium # 5062 / 5063)
  • Aktivatorspray # 5017
  • Glueholder # 50610
  • Epoxy adhesive, RO-Poxy 5 minutes # 50600
  • Files (square file 3mm, fine flat file)
  • Clamps and weights to weigh down
  • Set square, 90° angle
  • Drill: 2mm, 2.5mm, 3mm, 6mm
  • Ruder deflection indicator „ROBBE“ „M“
  • M3 Tap
  • Soldering iron, solder
  • Thin double-sided adhesive tape
  • Masking tape
  • Phillips screwdriver
  • Film iron
  • Hot-melt adhesive

robbe-Boo-Slope-Glider-800mm- \(2\)

robbe-Boo-Slope-Glider-800mm- \(3\)

INTRODUCTION

Wooden components

1 # 1 building jig 3 mm plywood
1 # 2 building jig 3 mm plywood
1 # 3 building jig baseplate 3 mm plywood
1 # 4 V-tail 2 mm liteply
1 # 5 ribs, servo mount 2 mm plywood
1 # 6 ruddervators 2 mm balsa
1 # 7 wing tips 6 mm balsa
2 # 8 Aileron planking 0.5 mm plywood
1 # 9 Casting ailerons 0.5 mm plywood
1 # 11 ribs 0.5 mm plywood
1 # 12 ribs 0.5 mm plywood
1 # 13 ribs 0.5 mm plywood
1 # 14 ribs 0.5 mm plywood
  • FLZ – aircraft plywood

Individual parts

1| GRP fuselage with carbon fibre canopy|
---|---|---
4| Carbon fibre rectangular profile spars 0.6 x 5 mm| 420 mm
3| Carbon fibre rod 1 mm| 460 mm
2| Bowden cable outer| 400 mm
2| Spring steel 0.6 mm| 500 mm
1| Carbon fibre tube 6mm OD| 200 mm
1| Carbon fibre tube 5mm OD| 55 mm
1| GRP wing joiner|
2| HPL V-tail mounting (outside)|
3| HPL V-tail mounting (inside)|
1| Carbon fibre tail skid 1.5 mm|
2| GRP Y-connector for V-tail 2 mm|
4| GRP joiner box webs (2 per wing) 1mm|
4| GRP parts for wing fixing/mounting (2 parts per wing) 1 mm|
1| Spring steel for canopy attachment 1 mm| 100 mm
2| Aluminium ruddervator control horns|
2| Ball joint and ball head clevis|
2| Solder connectors|
1| Shrink tubing| 30 mm
2| Socket head cap screws| M3x8
2| Socket head cap screws| M2x6
2| Nuts| M2
1| Pine strip| 2x5x300 mm
1| Square tube (wing joiner)| 5x5x0,5 mm

WING JOINER BOX
Cover the building board with film or packing tape so that the components of the BOO do not stick to it with the superglue.

ROOT RIB
For each wing separate the root ribs R0 to R2 and the 0.5mm ply tabs from the laser cut ply sheet. Remove the four GRP fillets from the GRP boards. Sand off the retaining bars around the edges and remove the surface finish left after manufacture. Note that ribs R1 and R2 each consist of a front and rear part.
Check without glue whether the GRP or wooden knots can be pushed into the individual slots without any problems. If necessary, rework carefully.

robbe-Boo-Slope-Glider-800mm- \(4\)

ROOT RIB

GEODETIC RIBS AND LEADING EDGE

  • Glue the root ribs R0, R1 and R2 to each other with white glue. Glue in the plywood tab (long tongue) at the rear of the assembly to align the parts. Use pliers to tuck the wooden knot into the ribs. Ali-gn the ribs at the leading edge with a small scrap of plywood. The two GRP fillets are also glued into the ribs with superglue. Clamp the three ribs together while they dry. Be sure you are building a left and right root rib!!
  • Separate the lower aileron sheeting from the plywood and sand off the retaining bars. Place the root rib on the sheeting. There is a shoulder at the back of the root rib, the front edge of the sheeting must lie against this shoulder. Align the two components exactly at right angles to each other and glue them with thin superglue.
  • Sand a carbon fibre spar to remove release agent left from pro-duction. Stick the spar to the building board with a few pieces of thin double-sided adhesive tape. Position the tie bar in the recess of the root rib! The spar should fit up against R0 and between the R1 and R2 sections. The root rib must be at right angles to the spar. Check the distance between the spar and sheeting at the root rib and at the wing tip. The spar and planking must be parallel. When everything is exactly aligned, tape the lower sheeting to the building board with several small pieces of masking tape along the trailing edge. Separate the ribs R3 to R27 and the two aileron sub ribs R28 from the laser cut sheets and sand the retaining bars flush.

robbe-Boo-Slope-Glider-800mm- \(4\)

  • Separate out the upper and lower ribs. You can recognize the upper ribs by the semi-circular bulges at the trailing edge. Now sort each set into number order.
    • Slot the first ribs R3 to R10 together. The upper ribs are put on the lower ones.
    • Now slide these ribs onto the GRP fillets and the ply tab in the root rib. Working along the wing to the tip slot the rest of the ribs together, alternating between an upper and a lower rib. No glue is added yet!

robbe-Boo-Slope-Glider-800mm- \(5\)

  • The final rib is R23 has two wooden tabs glued in. The wooden knots are reinserted with flat-nose pliers. The slit is in the back knot. Make sure you have a left and a right!
  • Insert the leading edge into the ribs. The kit contains a template to help slide the leading edge completely into the ribs and align the components ready for gluing. When the leading edge and all of the ribs are properly slotted together, align rib R23 with the sloping end of the lower aileron sheeting. This brings the wing to the exact length. Check that all ribs are completely in contact with the buil-ding board and that the spar is properly seated. When happy glue the ribs to the lower aileron sheeting, the leading edge, the ply and GRP webs and at the crossing points. Use superglue for this.
  • Glue the two sub ribs R28 to the lower aileron sheeting with a small gap between. Orientate yourself on the laser cut line. You need to adjust the front of the two ribs to fit against ribs R23 and R27. robbe-Boo-Slope-Glider-800mm- \(7\)
  1. Using side cutters snip off the bulges at the trailing edges of the upper ribs and sand the remaining protrusions flat with a sanding block.
  2. Fill in the first rib field on the root rib trailing edge above the lower aileron sheeting with the triangular piece of balsa and glue it in place with white glue. As soon as the glue has dried, you can sand the block flush.
  3. Glue the upper aileron sheeting onto the surface with white glue. Weigh down the sheeting while the glue dries and make sure that the trailing edge of the aileron is exactly straight.

robbe-Boo-Slope-Glider-800mm- \(8\)

WING TIP

Separate a wing tip from the balsa sheet and sand the edges smooth. Hold the edge bow on the wing (the flattened part of the edge bow points to the rear, towards the trailing edge) and mark where the recess for the CKF spar must be filed on the underside. The wooden knots are slightly above the rib R23 and should enga-ge in the edge arch. Therefore, note that the edge curve not only comes closer to the surface, but that the position also changes due to the inclined last rib. Sand a channel for the spar with a flat file or sanding block. Cut slots in the edge of the wing tip to correspond with the ply tabs which are sticking out of R23. Glue the tip to R23 and weigh down on the building board to ensure the tip stays level with the wing. When dry the lower spar can be glued with thin superglue.

Second wing
Now build up the second wing following the same procedure.

UPPER WING SPAR

  1. If you wish, you can adjust the two root ribs to accommodate the dihedral of the wing. This would close a small gap on the underside of the wings where the roots meet. Sanding machines where the angle of half the dihedral can be set are ideal but a sanding block could also be used. Only the top of the root ribs should be sanded. The bottom edge must remain unchanged.

    • If you are not confident enough, we recommend skipping this step as the gap is quite small.
      Adjust the lengths of the joiner boxes to fit snugly between R0 and the sloping face of R8. The joiner box lies flat on the bottom spar between R1/R2 and R8.

    • In the next four rib fields, fill in the area between the two spar chor-ds with the spar web HS-R. The point on the spar web marks the side with the root rib. The bridge is vertical and must be divided into four parts. The individual pieces are sanded at a 45 ° angle and glued to the lower spar with superglue.
      Shorten the wing joiner to suit.
      robbe-Boo-Slope-Glider-800mm- \(5\)
      robbe-Boo-Slope-Glider-800mm- \(6\)

  2. Before you glue the joiner box, check whether the joiner can be pushed into the sleeve at right angle and whether the upper wing spar can be placed over the joiner box. If in doubt, work on something.
    Glue in the joiner boxes one after the other if possible. Lay one wing panel flat on the board and weigh it down. Apply epoxy glue to the bottom wing spar and the contact points to the ribs R1 and R2. Place the joiner box into the wing and push the wing joiner through the root rib into the joiner box. Make sure that no glue gets on the joiner. Slide the second wing panel including the joiner box onto the wing joiner and prop the second wing tip up so the tip is approx. 35mm above the board. To do this, cut out a 35 mm wide piece from the template for the leading edge. Clamp the two root ribs together while the epoxy dries. Check whether the upper wing spar can rest on the ribs at all points. Particular attention must be paid to the area of the plug-in and the spar. If necessary, rework this area carefully.
    robbe-Boo-Slope-Glider-800mm- \(7\)

  3. The recess for the spar must now be made at the edge arch. Glue the upper wing spar with epoxy glue. Make sure that the spar comes to rest in the recess of all ribs. Weigh down the spar evenly until the adhesive hardens. Fill in the gap between the plug-in box and the stile with a little epoxy resin or an epoxy resin pump.

    • The joiner box, the HS rail and the wing spar are installed accordingly in the second half of the surface.
    • Check whether the four wing spars have been glued well to the ribs at every point. If in doubt, re-glue.
      robbe-Boo-Slope-Glider-800mm- \(8\)

Caution : Leftover spar material can be used to fill the gap bet-ween the two spars and the plug-in box.

CARBON FIBRE LEADING EDGE

  1. Glue the 1 mm carbon fibre rod to the leading edge and around the wing tip. Starting at rib R1.
    • To do this, press the carbon fibre rod, starting at the root rib, into the recess of the rib tips. Clamp the rod in place and bend the rod around the edge arch. The carbon fibre rod should extend to the end of the edge curve and come out at the level of the trailing edge. Mark the course on the edge curve and remove the carbon fibre rod again.
    • Using a square file form a small indentation (approx. 0.5 mm) around the edge of the tip. This ensures that the carbon fibre rod is correctly located and slightly recessed into the tip.
    • You may have to rework the transition from the last rib to the edge arch a little if the edge arch is too far forward.
    • Start at the root and glue the rod in place using the recesses in the rib leading edges as a guide. Use superglue and when you get to the tip tape the rod in place and bend the rod around the tip to the trailing edge. When dry remove the tape and cut off any excess rod.
      robbe-Boo-Slope-Glider-800mm- \(9\)

CHECK AND SAND EACH WING PANEL

  1. Check the entire surface to see if there are any high spots or any glue residue and sand smooth.
    • Carefully sand the leading edge where some of the ribs slightly protrude in front of the carbon fibre leading edge rod.
    • Check the wing tip and carefully sand it over until it has a nice shape which blends in with the rest of the wing.
      robbe-Boo-Slope-Glider-800mm- \(10\)

AILERONS

  1. Mark the top of each aileron with a sticker so it can be identified later when re-uniting with the correct wing panel.
    robbe-Boo-Slope-Glider-800mm- \(11\)

  2. On the underside of the wing draw two parallel lines on the aileron, 1 mm either side of the lasered line.
    Using a scroll saw or fretsaw, cut the aileron off along the lasered line with a vertical cut through both sheets and the ribs. Keep che-cking above and below to make sure the cut is straight.
    Proceed carefully here to prevent parts from breaking!
    TIP: Pre-score the cut edge with a sharp knife and ruler.
    robbe-Boo-Slope-Glider-800mm- \(12\)

  3. Sand the separated aileron and the wing panel back to the line you have drawn. Make sure that the hinge line is exactly straight on the top and that both sides of the wing are exactly the same. Place the top of the aileron and wing on a hard surface with a sharp edge along the edge. Sand the V shape into the aileron and wing. Use a sanding block for this. The hinge line is on the upper sur-face and the aileron deflection needs to be approx. 30 ° i.e. sand a 15 ° angle on the wing trailing edge and the aileron leading edge. Stick the aileron to the wing with a few strips of tape and check the aileron deflection and the gap between the wing and the aileron. Adjust if necessary.
    robbe-Boo-Slope-Glider-800mm- \(13\)

  4. Now you can glue the closing strips to the trailing edge of the wing and leading edge of the aileron. These are made of 0.6 mm. Use wood glue and weigh down each part while the glue dries. After the glue has hardened, sand the protrusions flush.
    To prevent the rudder from warping, let it protrude from the buil-ding board, weigh it down and then glue on the rudder locking

  5. A small amount of clearance is required between the ailerons at the root. Each aileron is sanded at the root by 2mm to create the V-shaped gap seen in the photo.

robbe-Boo-Slope-Glider-800mm- \(10\)

WING CONNECTORS

  1. Assemble both wing panels onto the wing joiner and align the root ribs. Clamp the root ribs together so they cannot slide apart.

    • Drill a 3mm hole completely through the two root ribs at the markings.
    • Then drill the upper part of the two holes with a 6 mm drill. Be careful not to drill right through, the hole in the lower part of the root rib should remain at 3mm.
  2. Separate the four GRP tabs and the four GRP stops. Lightly sand the surface and glue them together with thin superglue. To do this, place a tab and a stop on top of each other and align the two parts exactly with one another. To prevent slipping you can gently press the two parts together against the building board with a small screwdriver or other tool. Put a drop of thin superglue in each of the two holes of the stop. The superglue is then sucked between the two parts and glues them together. Enlarge the fixing holes with a 3mm drill.

    • Coat the mating surfaces of wing connectors with Vaseline or a good release agent. Glue the wing connectors into the slots in the wing roots with epoxy. These should be orientated so the connec-tors slide over each other as the wing roots a brought together. Carefully push the wing halves together onto the wing joiner making sure no glue gets in between. Clamp the connector halves together with a M3 screw and nut. Align the leading edges and the trailing edges and make sure the M3 screw heads are central in the root rib recesses and leave to dry.
      robbe-Boo-Slope-Glider-800mm- \(14\)
  3. Remove the nut and screw and the panels should slide apart. Check the glue joints and add a little more glue if necessary but be sure to keep the mating faces clear of glue.
    robbe-Boo-Slope-Glider-800mm- \(15\)

BUILDING JIG

  1. Fasten the baseboard of the building jig to the building board to prevent the building jig from warping.
  2. Slot the building jig together as shown in the adjacent photo. Make sure that all wooden parts are completely inserted into the base board and each other.
    robbe-Boo-Slope-Glider-800mm- \(11\)

ALIGNMENT OF THE FUSELAGE

  1. Slide the carbon fibre tail boom onto the fuselage pod and slot the assembly into the recesses in the building jig. Don’t glue anything yet – this is just a check. Lightly sand the sides of the carbon fibre stub at the rear of the fuselage pod if necessary to correct any slight misalignment.

CG BALANCE

  1. Assemble the centre of gravity balance from the four components shown and glue them together. The curved face of the vertical frame should point downwards.

TAIL UNIT

  1. Separate the three Liteply wooden parts from the board and sand off the protruding retaining bars. Saw a 117 mm long piece from the end of the pine strip. The three Liteply wooden parts and the pine bar are arranged on a flat surface and glued together. Carefully measure and cut the longitudinal bar from the pine strip. This needs to be a snug fit. Glue in place when happy.
    Cut four 1 mm carbon fibre rods to suit. Two 1 mm carbon fibre rods are glued on top of each other in each location using superglue. Round off the leading edge and tip and gently sand any high points on the surface flush. The second half of the tail unit is built up in a similar way.

  2. At the roots, sand the upper edge of the two tail unit halves with a 50 ° angle. The V-tail has an opening angle of 100 °. You can check the correct angle in the building jig.
    Glue the two tail unit halves together and leave the tail unit in the building jig until the glue has hardened. Make sure the slots for the dihedral braces are clear of glue and that the tail unit does not stick to the building jig.

RUDDERVATORS

  1. Detach the balsa ruddervators and sand the edges flush. The trailing edge of the ruddervators should be sanded to a thickness of approx. 1 mm. To do this more easily and precisely, you can glue a 1 mm steel wire to the rear edge with superglue. After sanding to shape, the wire can be easily cut with a knife.
    Bend the two aluminium ruddervator horns to 55 ° at the marking. Make sure you bend a left and right horn as they are handed.

  2. Take the ply leading edge former used to fit the wing leading edges and slot the little ply triangle into the slot. This is used to accurately align the ruddervator horns while gluing. Place the rudder-gators upside down on the former. Glue the aluminium horns into the ruddervators with epoxy resin. The ruddervator horn should be pressed firmly down to the building board and the remaining recess filled with glue. Weigh down and leave to fully dry.
    Carefully sand off any excess glue. Sand a small angle to the leading edge to allow the down movement of the ruddervators.
    Sand the rudder blade diagonally at the lower front edge so that the rudder can be moved downwards. The rudder will later be hinged to the top.
    robbe-Boo-Slope-Glider-800mm- \(16\)

WING FIXING

  1. Glue the two ply wing seat doublers for the wing fixing screws into the fuselage pylon using fast-curing epoxy adhesive. Note this pho-to shows the orientation of the ply pieces. They are glued inside!
    Caution: Make sure that the adhesive does not overflow so that the servo mount can be installed cleanly later.

  2. Measure 15mm from the rear of the pylon and mark for a hole exactly on the fuselage centre line. Drill a 2.5mm hole through the pylon and the doubler. This is the rear wing fixing position.

  3. You can use the slipway for alignment and drill the hole with a 2.5 mm drill bit.
    Make sure that the hole is drilled perpendicular to the wing contact surface.
    robbe-Boo-Slope-Glider-800mm- \(17\)

  4. Cut a thread in the hole with an M3 tap. Harden the thread by running a drop of thin superglue into the thread. You may have to cut the thread again afterwards.

  5. Place the assembled wing on the fuselage and fix the surface with the rear screw.

    • Mark the front drill hole. Make sure that the wing is aligned at right angles to the direction of flight. Measure the distance between the wing tips and at the end of the attached carbon fibre tail boom and ensure it is equal for both wing tips.
    • Drill the front fixing pilot hole with a 2.5mm bit and cut another 3 mm thread. Don‘t forget to harden the thread.

robbe-Boo-Slope-Glider-800mm- \(18\)

SERVO CUTOUTS

  1. NOTE:
    The aileron servo installation is designed for the previously recommended servos. If you use other servos, you may need to adjust the cutouts accordingly.

  2. Mark the centre of the servo access opening 39mm from the rear of the pylon. Drill and sand a 14 mm hole in the top of the pylon. You must be able to put the servo horns on through this hole and screw them tight.
    Caution: Make sure that this opening is as small as possible so as not to weaken the fuselage unnecessarily at this point!

  3. A slot is required in the sides of the pylon for the servo output arms to exit. These openings are approx. 16mm long and 5mm high. The top edge runs parallel to the top of the pylon and is approx. 4 mm below the top of the pylon.
    Repeat for the other side.
    Caution: Make sure that this opening is as small as possible so as not to weaken the fuselage unnecessarily at this point!

robbe-Boo-Slope-Glider-800mm- \(19\)

AILERON SERVO BRACKET

  1. The bracket for the aileron servos is assembled from the parts shown on the right.
    Insert the two nuts into the semi-circular board and glue them with thin superglue.

  2. Glue the thin board to the board with the nuts. Use the two screws to accurately position the parts. This is the support plate which is glued into the fuselage later.

  3. The bracket for the aileron servos is slotted together and glued with superglue. If using alternative servos check the fit and adjust as necessary.
    robbe-Boo-Slope-Glider-800mm- \(20\)

  4. Install the servos. The servo output arms are located towards the rear of the fuselage.
    The support plate is screwed tight behind the servo bracket with the two M2 screws with the thin plywood facing forwards.

  5. Note – only the support plate is glued to the fuselage. The bracket is supported at the rear on the carbon fibre tube, which is already glued to the fuselage.
    robbe-Boo-Slope-Glider-800mm- \(21\)

  6. Insert the two Bowden cable tubes through the carbon fibre stub at the rear of the fuselage and thread through to the canopy opening. Orientate the tubes vertically, one above the other and thread through the aileron bracket. Slide the servo mount back into the fuselage as far back as possible, over the carbon fibre stub in the rear. The servo output shafts must be in the middle of the two slots in the pylon sides and be accessible through the hole in the top of the pylon. Fit the servo output arms and check for clearance. Make sure the bracket is properly aligned and glue the support plate in place with medium-viscosity superglue. Now you can remove the servos at any time by simply undoing the two screws and sliding the bracket forward.

RUDDERVATOR SERVO BRACKET

  1. Screw the two servos for the V-tail into the servo bracket. The output shafts of the servos should both be in the middle.
    Push your receiver battery forward into the fuselage as far as possible and hold the servo bracket in the fuselage as a test. If you can get the battery out again and there is enough space for the receiver and the cables, you can position the servo bracket at this point. Glue the servo mount in place with quick-setting epoxy glue.
    Caution: Check the servo position when the canopy is closed. The servo arm must not protrude anywhere! If necessary, move the two servos closer to the center of the fuselage by relocating the mounting holes.

  2. Identify and layout the parts shown in the adjacent photo. The five black support elements are glued to the 4 mm carbon fibre tube with epoxy adhesive. The three middle elements are also glued together. To do this, grind the contact surfaces. The middle three elements should have a width of 17.5 mm after gluing.

  3. Slide the five support elements onto the carbon fibre tube. The three elements in the middle have a groove to accommodate the tail skid. The last element is flush with the carbon fibre tube. The two GRP V-tail fixings are pushed between the first and last element and the three middle elements. These should have space in between without wobbling. Remove the GRP fixings without moving the sup-ports. Align the five elements with each other to create a seat for the V-tail. To do this turn the assembly upside down on the building board and press down firmly.robbe-Boo-Slope-Glider-800mm- \(24\) V-TAIL SUPPORT

  4. Before the glue hardens, check that the space for the GRP brackets is correct and that the middle elements are close together and correctly aligned.
    Thoroughly remove any glue that has oozed out. If necessary, you can use a cotton swab and Acteon for this.
    Glue the tail skid into the groove of the three middle support elements with epoxy glue.
    The GRP V-tail fixings are glued into the V-tail later.

  5. The V-tail is held to the tail boom with a short piece of wire and piece of the Bowden cable left over from the ruddervators.
    The wire is bent at right angles at one end so that the pin can be pulled out. It is also slightly curved so that there is minimal tension and the bolt can slip out. The wire and Bowden cable tube are glued with superglue. Check the fit of the components and open up the hole through the assembly with a 2mm drill bit to allow the locking pin to be inserted. The V-tail fixings slide between the supports and the tail is held in place by the wire pin.robbe-
Boo-Slope-Glider-800mm- \(25\)

TAIL BOOM

  1. Place the fuselage into the building jig and make sure the components are all accurately aligned. The front edge of the V-tail support should line up with the support on the building jig. The Bowden cables should exit the tube horizontally at the rear.zThread the 6 mm carbon fibre tube onto the two Bowden cables and glue the tube to the fuselage pod with slow setting epoxy glue. Push the V-tail support onto the two Bowden cables and glue the rear support to the 6 mm fibre tube of the tail boom. Place back into the building jig while the glue dries. Align the fuselage pod horizontally with the aid of the jig.

  2. Place the fuselage into the building jig and make sure the compon-ents are all accurately aligned. The front edge of the V-tail support should line up with the support on the building jig. The Bowden cables should exit the tube horizontally at the rear.
    robbe-Boo-Slope-Glider-800mm- \(26\)

  3. Mask the top of the rear support with a layer of scotch tape to prevent glue from sticking and to compensate for the missing cove-ring. Thoroughly coat the rear V-tail seat with Vaseline to prevent it from sticking. Insert the two GRP brackets into the rear support and secure them with the wire locking pin. This should also be rubbed with Vaseline. If necessary, carefully adjust the hole in the five support elements and the two GRP V-tail mounts to the securing pin using a 2 mm drill bit. Apply a thin coat of epoxy glue to the GRP stubs and slide the V-tail into place. Check for correct alignment of the V-tail unit and weigh down until the adhesive hardens.

COVERING

  1. Before you can start with the actual covering, you must thoroughly dust all surfaces. A slightly damp cotton cloth can also be used for this purpose. Starting with the bottoms, tack the iron-on film first on selected straight lines at a moderate temperature. You can then cover the adjoining surfaces from the inside out with a gentle pull. The top is then covered. Make sure that you do not get any distorti-on due to excessive tension in the film.robbe-Boo-Slope-Glider-800mm- \(16\)

ATTACH AILERONS AND RUDDERVATORS

  1. Use clear tape to attach the two ailerons and the two V-tail rudder-vators ensuring that full up and down movement is achieved.
    robbe-Boo-Slope-Glider-800mm- \(10\)

V-TAIL LINKAGE

  1. Cut approximately 35 mm long pieces from the end of the rudder-vator control wires and bend each one as narrow as possible to match the servo horns.
    Position the two pieces of wire in the inner hole (6 mm) of the rud-elevator servo arms.
    robbe-Boo-Slope-Glider-800mm- \(17\)

  2. Bend an approx. 10 mm long piece at right angles at the end of the wire. Push the wire into the Bowden cable tube from the rear and connect the ruddervator horns to the wire.
    Fix both tail ruddervators in neutral.
    Cut the linkage wire to length in the canopy opening so that it and the wire from the servo overlap by approx. 20 mm.

  3. Slide a 20 mm long piece of shrink tubing over the linkage wire and glue the two pieces of wire with medium-viscosity superglue. The shrink tube is pushed over the overlap area and shrunk .

robbe-Boo-Slope-Glider-800mm- \(28\)

AILERON LINKAGE

  1. Shorten the thread of the two ball joint heads to a length of approx. 4 mm so that they don’t protrude on the other side of the aileron. Drill a 2 mm hole in the aileron about 13 mm from the centre of the wing. The ball joint is screwed into this hole and glued with epoxy glue.
    robbe-Boo-Slope-Glider-800mm- \(18\)

  2. Two pieces of wire approx. 28 mm long are cut from the rest of the linkage wire and bent with a narrow Z-bend. Please take the exact length of the wire from your model.
    The wire is soldered into a soldering sleeve.
    robbe-Boo-Slope-Glider-800mm- \(29\)

  3. Screw the ball joint connector onto the soldering sleeve and adjust the length to suit when the wings are fitted.
    robbe-Boo-Slope-Glider-800mm- \(19\)

CANOPY

  1. Use offcuts from the ruddervator linkage to hold the canopy in place on the fuselage.
    The wire should be a little longer than the canopy. Two approximately 1 cm pieces of the Bowden cable tube are used as spacers. Push these two Bowden cable tubes onto the wire and bend the wire ends slightly. Sand the adhesive area in the canopy a little. Glue the two Bowden cable tubes into the canopy with medium-viscosity superglue. Align the wire and glue it into the two tubes with superglue as well.
    robbe-Boo-Slope-Glider-800mm- \(20\)

RADIO INSTALLATION

  1. Plug the four servo connection cables into the receiver according to the specifications of your RC transmitter system. To connect the receiver battery, we recommend plugging an extension cable into the receiver. Now place the receiver in the fuselage and fix it with some foam if necessary.
    robbe-Boo-Slope-Glider-800mm- \(10\)

BALANCING

  1. NOTE:
    Observe the seller‘s hazard warnings when using lead.

  2. The center of gravity is set with the balance scale included in the kit.
    In strong winds, it is advisable to set the BOO slightly more nose-heavy.
    The center of gravity in the specification is a recommended setting for the first flight. Once you are familiar with the model, you can adjust the centre of gravity to your liking.

SETTINGS AND FLIGHT PHASES

  1. Program your RC system and, if necessary, create the desired flight phases for normal flight, thermals, etc.
    Before the first start, you should always carry out a range and function test to ensure that all the controls move as desired, and that operational safety is ensured.

  2. The following settings were determined during the flight testing of the original BOO. These should be used as a starting point and adjusted to suit your own flying style.

  3. For the first flight tests, set the centre of gravity as shown in the plan to 39 mm from the leading edge.

robbe-Boo-Slope-Glider-800mm- \(32\)

RUDDER THROWS

robbe-Boo-Slope-Glider-800mm- \(6\)001

TEST FLIGHT

For the first flight it is advisable to have a helper to launch the model for you.
Throw the BOO gently downwards and give it a short time to pick up the necessary speed. Throwing too hard or throwing upwards often leads to unsuccessful starts.
The BOO develops its performance through speed. Try to fly it faster, even in very poor conditions. As you do this, you will notice that the BOO maintains its altitude better than it does at slow speed.

robbe-Boo-Slope-Glider-800mm- \(1\) Robbe Modellsport
Industriestraße 10
4565 Inzersdorf im Kremstal

Austria
Phone: +43(0)7582/81313-0
Mail: info@robbe.com
UID No.: ATU69266037 robbe“ is a registered Trademark.
Errors, misprints and technical changes reserved.

Copyright 2023

  • Robbe Modellsport 2023
  • Copy and reprint only with our permission.
  • Service-Address
  • Contact your Dealer or:
  • Robbe Modellsport, Industriestraße 10,
  • 4565 Inzersdorf im Kremstal  service@robbe.com +43(0)7582-81313-0 www.robbe.com

References

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