Summary

• Page properties (1 modified, 0 added, 0 removed)

Details

Page properties

Content

...	...	@@ -14,18 +14,18 @@
14	14	1. [[MES - Center Frame Assembly>>doc:multirotor-erector-set.mes-reconfigurable-modular-frame.mes-modular-frame-quickstart.mes-center-frame.WebHome]]
15	15	1. [[MES - Landing Gear Assembly>>doc:multirotor-erector-set.mes-reconfigurable-modular-frame.mes-modular-frame-quickstart.mes-landing.WebHome]]
16	16	1. [[MES - Quick Release Assembly>>doc:multirotor-erector-set.mes-reconfigurable-modular-frame.mes-modular-frame-quickstart.mes-quick-release.WebHome]]
17		-1. [[MES - Final Assembly>>doc:multirotor-erector-set.mes-reconfigurable-modular-frame.mes-final-assembly.WebHome]]
18		-1. [[MES - Arm Clip Positions>>doc:multirotor-erector-set.mes-reconfigurable-modular-frame.mes-arm-clip-positions.WebHome]]
	17	+1. [[MES - Final Assembly>>doc:multirotor-erector-set.mes-reconfigurable-modular-frame.mes-modular-frame-quickstart.mes-final-assembly.WebHome]]
	18	+1. [[MES - Arm Clip Positions>>doc:multirotor-erector-set.mes-reconfigurable-modular-frame.mes-modular-frame-quickstart.mes-arm-clip-positions.WebHome]]
19	19
20	20	The Multirotor Erector Set (MES) - Reconfigurable Frame is an all-in-one frame designed to allow the user to easily experiment with a variety of different multirotor designs, without having to invest in a variety of custom frames. The frame is based on the M.E.S. system which uses aluminum tubing clamps, G10 composite plates and carbon fiber tubing. A wide variety of different designs can be created using this single frame system and each can vary in terms of arm length, motor configurations, accessories and more.
21	21
22		-== Applications ==
	22	+= Applications =
23	23
24	24	* UAV / drone / multirotor education, development & experimentation
25	25	* Sensor experimentation
26	26	* Design & payload optimization
27	27
28		-== Features ==
	28	+= Features =
29	29
30	30	* Reconfigurable center frame
31	31	* Mounting for one or two batteries
...	...	@@ -36,7 +36,7 @@
36	36	* Side mounted ESC for easy access
37	37	* Wiring within tubing
38	38
39		-== What's Included ==
	39	+= What's Included =
40	40
41	41	* G10 composite (non-conductive) parts for complete frame assembly
42	42	* Anodized (orange) aluminum tubing clamps
...	...	@@ -43,7 +43,7 @@
43	43	* Carbon fiber tubes
44	44	* Hardware (screws, standoffs, grommets, bearings, foam)
45	45
46		-== What's Needed ==
	46	+= What's Needed =
47	47
48	48	* Brushless DC (BLDC) motors (4 to 12 depending on design) and corresponding mounting screws
49	49	* Electronic Speed Controllers (ESCs) compatible with BLDC motors selected
...	...	@@ -53,7 +53,7 @@
53	53	* Remote Control (RC) system with minimum 4ch and receiver
54	54	* Optional: Gimbal; Video transmitter / receiver; Camera; Sensors;
55	55
56		-== Design Examples ==
	56	+= Design Examples =
57	57
58	58	The following designs are examples of what is possible with the MES system. These are all included in the assembly guide and allow you to become familiar with the system. Spare parts are included to allow you to create alternative designs, and additional hardware can be purchased separately.
59	59
...	...	@@ -101,21 +101,21 @@
101	101	The H12 hexacopter design incorporates folding arms and removable landing gear. There is a motor mounted to both the top and bottom of each of the six arms. Wiring is internal. This design requires independent control of 12 motors, which is not supported by MultiWii /
102	102	)))
103	103
104		-== Design Guide ==
	104	+= Design Guide =
105	105
106	106	This section covers only the basics of how to select additional components to complete the MES frame.
107	107
108		-=== Accessories ===
	108	+== Accessories ==
109	109
110	110	The types of accessories to connect to the frame are at the discretion of the designer. Components can be added above the frame or below, and a universal mounting plate is included. The length of the landing gear was selected in order to accommodate both a battery below the center frame as well as a standard two axis gimbal. For three axis gimbals, note that the distance between the bottom of the center frame and the ground is ~_~_~_~_.
111	111
112	112	The Lynxmotion Servo Erector Set (SES) pattern has been incorporated into several positions on the frame. This pattern allows SES compatible hardware (brackets, C-channels and accessories) to be connected to the frame and used as universal mounting points. When mounting accessories, be check the center of gravity of the entire assembly and ensure it is at the very center of the drone. Should there be a weight imbalance, certain motors may need more power than others, and the flight characteristics may change significantly.
113	113
114		-=== Battery ===
	114	+== Battery ==
115	115
116	116	The MES frame supports using either one centrally mounted battery (below or above the main frame) or two batteries mounted on either the landing gear tubes or above the center plate. In a two battery configuration, we strongly recommend using identical batteries to ensure weight balance and uniform discharge. Note that both batteries should be fully charged before use, and your method of power distribution should support a two battery configuration. The battery is held in place by rubber foam and velcro straps, which supports a wide variety of different sizes. The battery's voltage should ideally match that of the BLDC motors selected, and the continuous discharge current rating ('C' rating) should be above the sum of the maximum current consumption of the motors used.
117	117
118		-=== Motor, ESC, Propeller ===
	118	+== Motor, ESC, Propeller ==
119	119
120	120	In order to help determine the type and number of BLDC motors to use in a specific configuration, we propose following the steps below:
121	121