Microphone
From DDL Wiki
Contents |
Executive Summary
-Dan
this page needs a fricking backlink!
Engineering_Design_II_-_Conceptualization_and_Realization_Course
Stakeholders
-Luo
yes i am a stakeholder
User Study
-Nakul
Assembly
-Justin
Function of the System
Mechanical Analysis
-Nakul
Parts List
-Dan & Justin
Part Number | Photo | Part name | Mass (g) | Notes | Material | Manufacturing Method | |
---|---|---|---|---|---|---|---|
1 | Ring (2x) | 2 | attaches to mic end of boom shaft | Steel | Machining | ||
2 | Boom shaft | 493 | Steel Pipe(mass includes counterweight) | Steel | Extrusion | ||
3 | Counterweight | - | Solid | Steel | Casting | ||
4 | Mic Holder | 10 | Holds the microphone in place, allows the user to pivot the microphone up or down, giving the whole system an extra degree of freedom | Plastic | Casting and Machining | ||
5 | Bolt A | 3 | holds mic holder to #7 Connection A | Steel | Machining and Threading | ||
6 | Bolt B | 2 | #6 Bolt B can be screwed into #5 Bolt A | Steel | Machining and Threading | ||
7 | Connection Part A | 12 | screws onto the boom | Plastic | Injection Molding | ||
8 | Connection Part B | 71 | Connects with #7, allows boom shaft to be pivoted, given the whole boom stand an extra degree of freedom | Steel | Casting and Threading | ||
9 | Rubber pad (2x) | 8 | The two pads go inside #8 Connection B to hold #11 Boom holder. The friction between the surfaces of the two pads and the boom holder is strong enough to keep the entire boom stand above it still. At the same time the user can easily adjust (pivot) it | Rubber | Molding | ||
10 | Bolt C | 16 | Bolt that goes through Connection Part B, the rubber pads, and the Boom holder, connecting them all together, there is a nut that is paired with the bolt | Steel | Machining | ||
11 | Boom holder | 65 | has a long hole in which the boom is inserted. Attaches to mic stand via #8 | Steel | Casting and machining | ||
12 | Washer | 1 | #10 goes throught this washer | Steel | Stamping | ||
13 | Handle | 28 | Has a threaded hole in which the end of #10 is inserted | Steel | Casting and machining | ||
14 | Thumbscrew (2x) | 3 | Acts as a tighener to hold the boom in place. Goes into a hole in #11 Boom holder. The second one goes through the #19 Tripod Core and fixes the #16 Boom to it.Has plastic nub so as not to scratch the boom, which keeps the sprayed finish from being damaged | Two kinds of plastic (head and nub) and steel (screw) | Molding (plastic) and machining (steel) | ||
15 | Wire clip | 2 | Attaches to mic stand, used to hold wire in place | Plastic | Molding | ||
16 | Image:Boom.jpg | Boom | Steel pipe. It is essentually the body of the stand, there's a # 17 Fastener Connector between them for the user to adjust the two (Boom and Extension) to a desired height between 33-61 inches | Steel | Extrusion | ||
17 | Boom Extension | Steel pipe, the extension has a thinner diameter so it may fit in the boom itself. The end of the extension is exploded out so that it can't be easily taken off. | Steel | Extrusion | |||
18 | Fastener Connector | Plastic fastener connector reinforces tightness, preventing slipping | Plastic | Injection Molding | |||
19 | Tripod Core | Connection between the boom and the tripod legs of the stand, also serves as a weight to lower the center of mass and prevents the stand from tipping. The #14 Thumbscrew fixes the body to it and the legs are attached using #20 nuts and bolts | Steel | Casting and Threading | |||
20 | Nut and Bolt (3x) | Used to fasten the legs to the Tripod core | Steel | Machining and Threading | |||
21 | Leg (3x) | One of the ends of the legs was clammed for a tighter fit to the Tripod core, which also allows the #20 bolts used to be shorter | Steel | Extrusion | |||
22 | Rubber Ends | These ends go on the other end of the legs. Their main function is to increase friction when in contact with the floor to prevent sliding from occuring | Plastic | Molding |
Part Number | Photo | Part name | Masss(g) | Notes | Material | Manufacturing Method |
---|---|---|---|---|---|---|
M1 | cell 1,1 | Switch slider | <1 | cell 1,2 | Plastic | Molding |
M2 | cell 2,1 | Sticker A | <1 | Goes on M1 | Plastic | Stamped out of a thin sheet |
M3 | cell 2,1 | Screw A (2X) | <1 | Holds switch electronics to the microphone body | Steel | Machining |
M4 | cell 2,1 | Screw B | <1 | Atttaches gground pin to the back of the microphone body | Steel | Machining |
M5 | cell 2,1 | Body | 187 | Large, machined | Metal | Casting and machining, sandblasted finish |
M6 | cell 2,1 | Rubber disc | 2 | Holds three pins in place | Rubber | Molding |
M7 | cell 2,1 | Pin | 1 | Transmits signal from the microphone to the wire | Metal | ????? |
M8 | cell 2,1 | Switch electronics | 3 | Use physical user input from switch to affect electrical circuit | Plastic housing, metal wire | Molding (housing), extrusion (wire) |
M9 | cell 2,1 | Foam cover | <1 | Covers the magnet and diaphragm | Polymer foam | ???? |
M10 | cell 2,1 | Plastic cover | 2 | Protects diaphragm and magnet | Plastic | Molding |
M11 | cell 2,1 | Chip | <1 | Takes signal from coil (M13) and transmits it to the the pins. Is glued to a slot on M16 | Silicon chip, copper conductors | Chemical etching |
M12 | cell 2,1 | Diaphragm | <1 | Made from a thin piece of plastic with a spiral stamped into it to give it better elastic properties | Plastic | Stamping |
M13 | cell 2,1 | Coil | <1 | Thin insulated copper wire | Copper | Extrusion |
M14 | cell 2,1 | Magnet | 5 | Attached to diaphragm | Magnetic metal | Casting |
M15 | cell 2,1 | Sticker B | <1 | Covers cavity in the housing, below where the magnet sits | Plastic | Stamping |
M16 | cell 2,1 | Housing | 10 | Holds parts M11-M15, the parts that actually convert sound into an electrical signal | Plastic | Molding |
M17 | cell 2,1 | Wind screen | <1 | Made of a hollow foam ball. Inserted into the metal screen. Used to soften sounds of users' voices | Polymer foam | ???? |
M18 | cell 2,1 | Metal screen | 49 | Made of a wire mesh attached to metal rings | Steel | Extrusion, weaving, ??(Don't know how rings are attached) |
Design for Manufacturing and Assembly (DFMA)
Microphone:
Boom Stand:
The parts that construct the boom stand are mainly constructed of either plastic or steel. Most of these parts are mass produced since stands are very common and high in demand. The few parts that plastic (handle and end of thumbscrews) along with the rubber ends on the bottom are most likely made through injection molding. Injection molding provides a high volume mass production of identical parts with very low tolerance. The initial tooling costs are very high but the unit costs are low (meaning a high initial fixed cost but in exchange the marginal cost per unit is sufficiently low), thus when a large quantity of identical parts are produced injection molding will save money in comparison to other processes.
The counter weight on the end of the boom shaft and the microphone holder are both solid pieces of metal made through the casting process. The counter weight is then glued onto the end of the boom shaft. The casting process (my guess is die casting) has a similar manufacturing feature as injection molding cost-wise. They are generally a high volume production with high initial tooling costs but low unit costs.
Thing on bottom…..casting, plastic thing that was press fit into pipe
All the steel tube components have identical thicknesses and diameter, meaning that they can all be produced by the same machinery while each part is cut into the desired length. The raw steel is cast then made into a pipe by stretching the steel out into a tube. The steel tubes are seamless, which are suitable for the job as the shafts for being strong, durable, and light weight. The exterior of all steel components are sprayed on a metta-black finish for a good look to appeal to the consumers.
DFA:
The assembly of the parts can be either by man or machine. To our surprise, the after the stand was dissected and analyzed it took less than 5 minutes for a single person to reassemble everything part together.
Failure Modes and Effects Analysis
Considering ways in which a product could potentially fail is a crucial part of the design process. All products must be designed such that they are both safe and reliable for use and any potential dangers must be addressed in the design phase.
Assembly/Parts | Failure Mode | Consequence of Failure | S | Causes of Failure | O | Prevention | D | RPN | Recommendations | Responsibility |
---|---|---|---|---|---|---|---|---|---|---|
On/Off Switch | Soldering Becomes Loose | Microphone will not turn on | 7 | Bad soldering | 2 | N/A | 2 | 28 | Check soldering before assembly | Controls engineer |
Diaphragm | Torn Diaphragm | Inoperable | 7 | Misuse or Outside particles gets inside microphone | 1 | Foam Cover | 2 | 14 | None | N/A |
Extending Stand | Grip fails | Stand does not stay extended | 5 | Wear from lots of use | 1 | Exploded end | 1 | 5 | Add rubber stoppers or grips | Design Engineer |
Microphone Clip | Loose Joint | Unable to orient to desired location | 4 | Loose Screws, wear from use | 6 | N/A | 1 | 24 | Tighten Screws constantly, add friction to joint | Controls Engineer |
Rubber Pads | Worn down thickness | Boom shaft is unstable, gravity overcomes friction force | 5 | Worn pads | 1 | N/A | 1 | 5 | Do not pivot shaft aggressively or unnecessarily | N/A |
Rubber Ends | Torn or lost | Stand may slide | 2 | Worn down ends | 1 | N/A | 1 | 2 | None | N/A |
Design for Environment
Greenhouse Gas Emissions
Greenhouse gases, such as carbon dioxide and chlorofluorocarbons, contribute to the prevalent problem of global warming. With a $1 million injection into the Audio-Video Manufacturing sector, the overall global warming potential (GWP) increase by 574 metric tons of CO2 equivalent. As we can see from the graph above, the actual audio-video manufacturing process only contributes 19.7 MTCO2E, less than 4% of the total. Most of the emissions come from power supply.