Wiki source code of LSS-P - Mechanical

Version 68.1 by Eric Nantel on 2023/08/01 15:01
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Eric Nantel 32.1 1 {{warningBox warningText="More information coming soon"/}}
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Eric Nantel 68.1 3
Eric Nantel 32.1 4 (% class="wikigeneratedid" id="HTableofContents" %)
5 **Page Contents**
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7 {{toc depth="3"/}}
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Eric Nantel 68.1 9 |(% colspan="3" %)(((
Eric Nantel 43.1 10 = Mounting Points =
Eric Nantel 39.1 11 )))
Eric Nantel 68.1 12 |(% rowspan="2" style="width:25%" %)[[image:LSS-P-L1-Mounting.png]]|(% rowspan="2" style="width:35%" %)
Eric Nantel 43.1 13 |(((
Coleman Benson 45.1 14 **LSS-P-L1**
Eric Nantel 43.1 15
Coleman Benson 45.1 16 There are 6 untapped holes and 6 tapped holes around the circumference of the gearbox. The tapped holes are used to fix the frame to the gearbox and are M4 tapped on a 65mm diameter circle. The untapped holes are 4.5mm diameter on a 96mm diameter circle with a depth of 7mm.
Eric Nantel 43.1 17
Coleman Benson 45.1 18 Gearbox Output Mounting
19
20 * Six equally space M4 threaded holes on a 23mm diameter circle with a depth of 5mm
21
22 Mounting Plate
23
24 * Six equally space M4 threaded holes on a 23mm diameter circle with a depth of 5mm (LSS-P-L1 output)
25 * Six equally space M5 threaded holes on a 27mm diameter circle with a depth of 5mm (LSS-P-S1 output)
26 * Six equally space M8 threaded holes on a 42mm diameter circle at a depth of 15mm (LSS-P-M1 output)
27 * Six equally spaced 3.2mm diameter holes on a 58mm diameter circle (clamp mounting)
28 * Six equally spaced holes to mount the top PCB (explained in PRO Electrical)
29
30
Eric Nantel 40.1 31 )))
Eric Nantel 68.1 32 |(% rowspan="2" style="width:350px" %)[[image:LSS-P-S1-Mounting.png]]|(% rowspan="2" style="width:35px" %)
Coleman Benson 45.1 33 |(((
34 **LSS-P-S1**
35
36 There are 6 untapped holes and 6 tapped holes around the circumference of the gearbox. The tapped holes are used to fix the frame to the gearbox and are M4 tapped on a 71mm diameter circle. The untapped holes are 4.5mm diameter on a 71mm diameter circle with a depth of 7mm.
37
38 Gearbox Output Mounting
39
40 * Six equally space M5 threaded holes on a 27mm diameter circle with a depth of 5mm
41
42 Mounting Plate
43
44 * Six equally space M4 threaded holes on a 23mm diameter circle with a depth of 5mm (LSS-P-L1 output)
45 * Six equally space M5 threaded holes on a 27mm diameter circle with a depth of 5mm (LSS-P-S1 output)
46 * Six equally space M8 threaded holes on a 42mm diameter circle at a depth of 15mm (LSS-P-M1 output)
47 * Six equally spaced 3.2mm diameter holes on a 58mm diameter circle (clamp mounting)
48 * Six equally spaced holes to mount the top PCB (explained in PRO Electrical)
49 )))
Eric Nantel 68.1 50 |(% rowspan="2" style="width:350px" %)[[image:LSS-P-M1-Mounting.png]]|(% rowspan="2" style="width:350px" %)
Coleman Benson 45.1 51 |(((
52 **LSS-P-M1**
53
54 There are 6 untapped holes and 6 tapped holes around the circumference of the gearbox. The tapped holes are used to fix the frame to the gearbox and are M5 tapped on a 96mm diameter circle. The untapped holes are 5.5mm diameter on a 96mm diameter circle.
55
56 Gearbox Output Mounting
57
58 * Six equally space M8 threaded holes on a 42mm diameter circle at a depth of 15mm
59
60 Mounting Plate
61
62 * Six equally space M4 threaded holes on a 23mm diameter circle with a depth of 5mm (LSS-P-L1 output)
63 * Six equally space M5 threaded holes on a 27mm diameter circle with a depth of 5mm (LSS-P-S1 output)
64 * Six equally space M8 threaded holes on a 42mm diameter circle at a depth of 15mm (LSS-P-M1 output)
65 * Six equally spaced 3.2mm diameter holes on a 58mm diameter circle (clamp mounting)
66 * Six equally spaced holes to mount the top PCB (explained in PRO Electrical)
67 )))
Eric Nantel 68.1 68 |(% colspan="3" style="width:350px" %)(((
Eric Nantel 39.1 69 == Case ==
70 )))
Eric Nantel 68.1 71 |(% rowspan="4" style="width:350px" %)[[image:LSS-P-L1-Frame.png]]|(% rowspan="4" style="width:350px" %) |(((
Coleman Benson 45.1 72 The case of the Lynxmotion PRO Smart Servo is in three parts: the main body, the cap and the mounting plate. Each of these three parts is milled from aluminum and anodized black.
Eric Nantel 68.1 73 )))
74 |(((
Coleman Benson 45.1 75 **Main Body**
76
77 The main body is in the shape of a compact T, with the stepper motor located in the center.
Eric Nantel 68.1 78 )))
79 |(((
Coleman Benson 45.1 80 **Cap**
81
82 The cap supports the top and bottom PCB which make up the electronics inside the actuator. The bottom PCB must be located at the rear of the stepper motor in order to make use of the encoder.
Eric Nantel 68.1 83 )))
84 |(((
Coleman Benson 45.1 85 **Mounting Plate**
86
87 The mounting plate provides a convenient connection point onto which another actuator, clamp or bracket can be connected. As indicated above, it has the mounting pattern for the gearbox output for each of the three servo motors, as well as the clamp.
Eric Nantel 39.1 88 )))
Eric Nantel 68.1 89 |(% colspan="3" style="width:350px" %)(((
Coleman Benson 45.1 90 == Connectors ==
Eric Nantel 39.1 91 )))
Eric Nantel 68.1 92 |(% rowspan="2" style="text-align:center; width:350px" %)[[image:LSS-P-S1-Connectors.png]]|(% rowspan="2" style="text-align:center; width:350px" %) |(((
Coleman Benson 45.1 93 **RJ45 - CAN Communication**
94
95 There are two RJ45 connectors which allow the servos to be daisy chained. Either connector can be used as the pinout is identical. More information about the pinout can be found on the LSS-P - Electrical page.
Eric Nantel 68.1 96 )))
97 |(((
Coleman Benson 45.1 98 **XT60 - Power**
99
100 The actuators are powered via ONE of the two XT60 connectors. The second XT60 is to provide power to the next actuator in the bus. Never feed an actuator with two sources of power. More information about the power requirements can be found on the LSS-P - Electrical page.
101 )))
Eric Nantel 68.1 102 |(% colspan="3" style="width:350px" %)(((
Eric Nantel 39.1 103 == Gearing ==
104 )))
Eric Nantel 68.1 105 |(% style="text-align:center; width:350px" %)[[image:LSS-P-S1-Gearbox.png]]|(% style="text-align:center; width:350px" %) |(((
Coleman Benson 45.1 106 Each of the actuators use Strain Wave Gearing (a.k.a. "Harmonic Drive" which is a brand like "Kleenex" is associated with tissue paper). This allows for a high torque transfer and very high angular precision. Strain wave gearing is not meant to be back-driven. The gear ratios for each are:
107
108 * Lite: 100:1
109 * Standard: 100:1
110 * Mega: 100:1
111 )))
Eric Nantel 68.1 112 |(% colspan="3" style="width:350px" %)(((
Eric Nantel 39.1 113 == Stepper Motor ==
114 )))
Eric Nantel 68.1 115 |(% style="text-align:center; width:350px" %)[[image:LSS-P-S1-Stepper.png]]|(% style="text-align:center; width:350px" %) |(((
Coleman Benson 45.1 116 Unlike many tabletop "Cobot" ("collaborative robot") robotic arms which use BLDC / frameless DC motors and measure the current needed for a motion, the LSS-P actuators use standard sized and industry proven bipolar stepper motors. These motors provide high torque at low speeds, but operate at a set current and therefore do not have a direct way of measuring the torque.
Eric Nantel 34.1 117
Coleman Benson 45.1 118 * Lite: NEMA 14
119 * Standard: NEMA 17
120 * Mega: NEMA 25
121 )))
Eric Nantel 64.1 122
Eric Nantel 65.1 123 == Dimensions ==
Eric Nantel 64.1 124
125 |(% style="text-align:center" %)**Lite / LSS-P-L1**|(% style="text-align:center" %)**Standard / LSS-P-S1**|(% style="text-align:center" %)**Mega / LSS-P-M1**
126 |{{lightbox image="https://wiki.lynxmotion.com/info/wiki/lynxmotion/download/lynxmotion-smart-servo-pro/WebHome/LSS-P-L1-Dimensions.png"/}}|{{lightbox image="https://wiki.lynxmotion.com/info/wiki/lynxmotion/download/lynxmotion-smart-servo-pro/WebHome/LSS-P-S1-Dimensions.png"/}}|{{lightbox image="https://wiki.lynxmotion.com/info/wiki/lynxmotion/download/lynxmotion-smart-servo-pro/WebHome/LSS-P-M1-Dimensions.png"/}}

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