Hardware: Frame Assembly

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Finished rails (load cell mounts). Two go under the hive, one on each side.
End view of rail with end cap and closure strip removed.

Parts List

For part numbers, suppliers and prices, see the Parts List.

Tools

  1. Tape Measure
  2. Pencil
  3. Layout or speed square
  4. Hacksaw
  5. Drill
  6. 1/4" drill bit
  7. Center Punch
  8. File
  9. 10 mm wrench
  10. 13 mm open end wrench
  11. 7/16" [hollow punch]
  12. Feeler Gauge

Optional tools:

  1. Metal cutting band saw or cut off saw
  2. Drill press
  3. Stationary disk sander


Fabricate Rails

Cut Strut

Cut the strut in 20" lengths. Three can be cut from 5' strut, 6 can be cut from 10 foot lengths. After loosing the saw kerf, the rails may be slightly less than 20".

  1. Mark the strut using a tape measure, If using a hack saw, transfer the marks around the strut using a layout square.
  2. Carefully cut the strut on the lines, trying to keep as straight and square as possible.

Transfer Layout

Method 1:

  1. Place a load cell on the top of the rail. It should be about 4 mm (1/4") from the end. NOTE: If it is more than 4 mm from the end you will not be able to tighten the lock nut on the foot and the end cap will not cover the closure strip.
  2. Using a transfer punch, mark the two 8 mm mounting holes.
  3. Repeat on the other end.
  4. Check the punch marks to make sure they are in a straight line.
  5. Punch the marks deeper using the center punch.

Drill and Debur

Drill the four 1/4 holes in each rail to mount the load cells. Use a file, deburring tool, or stationary disk sander to clean up the ends. They will be covered by the End Caps so they don't have to be perfect. Use a file or deburring tool to debur the holes.


Assemble Rails

Turn a rail upside down with the open side up. Place a spacer over the holes. Carefully position the load cell over spacer. Align the holes without shifting the spacer.

NOTE: The green arrow on the end of the load cell should point down, toward the top of the rail.

Place a lock washer and flat washer on a M6x30mm bolt. While holding the load cell and spacer in place with one hand, start the bolt in one of the holes. Do the same for the other bolt. Make sure the load cell is centered in the strut and not touching the sides. Tighten the bolts.

Thread an 8 mm hex nut on each leveling foot.

Screw the leveling feet all the way into the load cells. The leveling foot should go all the way through the load cell, but not touch the strut.

Cut Closure Strips

Measure the distance between the leveling feet.

Using the hacksaw, cut the closure strip to fit between the leveling feet. If the strip is cut too long, a rat tailed file or rasp can be use to cut a semicircle in the ends. The closure strips should not contact the threaded portion of the leveling feet.

Punch End Caps

Set Overload Limits


Assemble Electronics

Block Diagram

The electrical connections are made as shown on the block diagram.

Solder shield and connectors.

This is already done on the developer kits, This step is only necessary if you obtain parts independently.

Solder shield and connectors on HX711 board.

Connect load cells.

  1. Each load cell has five wires:
  • Red (V+)
  • White (A+)
  • Green (A-)
  • Black (Ground)
  • Black (Shield)

Connect power and serial I/O cable to HX711 board.

Plug HX711 serial I/O cable to Pi.

Connect USB/Serial Console cable to Pi

Connect Hub, WiFi, and TEMPerHUMs

Testing

If you have not installed the operating system and software on the SD card, load hivetool on the Pi now.


Mount in Enclosure

Several enclosures can be used.

XP004 enclosure.jpg
HX711 with screw terminals and metal shield installed connected to H5 on the Pi. H5 is no longer used as it was dropped from the B+.
Exploded parts diagram.
Parts Detail
Assembly



Goals:

  • Complete system parts cost under $100.
  • Scale parts cost under $50 and are readily available.
  • Low thermal drift and creep.
  • Low power consumption.
  • Overload protection.
  • Automatically resumes operation after power failure.
  • Can be built by 15 year old student (9th grader) using hand tools.
  • No soldering.
  • No lethal voltages.

Design Features

  • No frame: no welding, no bending.
  • Load cells are mounted in metal strut readily available from electrical or industrial suppliers in aluminum. galvanized or painted steel.
  • Only straight cuts and drilled holes.
  • All electrical connections are made with crimp plugs or terminal blocks.

Design Flaws

  1. The M6 Cap Screws stick up and require a spacer or mortising the bottom board (Use counter sunk flat head screws?).
  2. The leveling feet form the over limit protection and are not for leveling. If they are used to level, the over limit protection will break.
  3. The feet stick out from the rail and can damage the load cells if dropped or if improperly packed for shipping.