Context and Objectives.

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Presentation transcript:

Context and Objectives. The system I am going to study is the current environment cold blooded reptiles are kept in as pets within today's society, and how this effects their health. I am already aware of a few flaws in this system, due to the systems being fully open systems allowing for errors in user inputs. I believe that there is a lack of both knowledge and systems for the specific conditions that a reptile will require in order to live healthily. The combination of both these lacks can cause pet reptiles to suffer, causing unknown animal cruelty. If the systems could be improved to a specific level, then it would allow for the ignorance of pet owners and still cause the reptiles no further suffering. This is why I am studying this system, as a personal pet owner, and the keeper of an okeetee morphed corn snake I am aware of the difficulties of keeping it healthy with the current system. During my study I will need to investigate and gain more knowledge on the designing of a system to improve the living conditions of reptilian pets. Some of the design factors necessary to achieve this are: The use of CAM and CAD in the designing of the system, to enhance the overall system by making accurate calculations and/or design ideas. The consumer needs at present time and in the predictable future, meeting these needs, such as easy use of the system to keep the reptiles healthy, will allow for a more specific and appropriate system rather than a system that does hundreds of unrequited operations. The electronic systems required in the system to ensure everything works as it should in the vivarium, ensuring the health of reptilian pets. The analysis of existing products to ensure there are not any systems exactly the same as the improvement I will induce. I can also retain ideas from existing products (while considering copyright laws) to help enhance the system. The cost of my product is in need of deep investigation as I am already aware that vivariums are extremely expensive on their own, let alone with a system attached, although they are not relatively expensive to manufacture. The materials used in the systems will require good aesthetics and some ergonomics on a possible controller. Also there are certain materials used in the heat mats on the vivarium floor. Reptiles are extremely susceptible to their current environment, if this is inefficient in any way, the reptile can become unhealthy, thus the maintenance of the specific environment must be maintained or the reptile will become unhealthy, or even in more serious cases die. The operational costs of the system is in need of investigation also, because if the amount of power wastage can be reduced, then the costs of running the system are also reduced. The Quality to Cost ratio will also need to be addressed as good quality equipment is expensive and will raise the prices of the system, finding a balance between both price and quality is the best solution to consumer needs. There is also an amount of manufacturing issues that need investigation for this system these are: The interpolation of the entire system, how everything fits together and why, ensuring that nothing will break too easily, and what will go where and stay rather than move unexpectedly, while bearing in mind there will be a living moving creature inside, that might effect the entire interpolation of the system. The materials used in manufacture will also be investigated to show how the strength, aesthetics and ergonomics of the system whilst being able to maintain a specific environment. Health and safety issues will also need to be revised as the system must adhere to ALL of the laws regarding health and safety otherwise the system will be dangerous to use. The schools manufacturing limits will also require investigation as if it does not have the specific equipment for a job, I cannot use that part of the system, and may have to alter the entire system accordingly. I will also require investigation into the universal design tools used in the manufacture of this system, like what CAM software will I require to use the cutters available. The preparation of the manufacture will also require a decent amount of attention, what tools are required, what electronic components need to be purchased ect. The assembly of sub systems within the system is of great importance and will require a lot of research, if all the sub systems do not work as a whole, the system will not function adequately, causing suffering to the reptile. The readiness of the product to be converted into something that is batch producible is in need of research because at present the system will be a one off product, and if the system is to enter the market it will need to be available by batch production. The time of manufacturing will require a great deal of attention as I only have a set time limit in which to investigate, design, manufacture, test and evaluate, therefore I will have to be able to utilize all the time I have to the highest possible standard. The energy costs of manufacturing will need to be advised as if the manufacturing energy costs are high it will be both a danger to the environment and a less cost effective system. From this I hope to gain: Knowledge on how systems interpolate. The ability to manage not only my time but also different materials and circuits. A fully functioning system that will increase the quality of pet reptilian living conditions, Information about controlling systems and how they function for use in further life. Knowledge on mass production techniques, so I can use the knowledge in later life to aid in the job areas I am looking in. From this I hope the reader will gain: Enjoyment from reading this investigation and learning about the system. A gain of enthusiasm about both the system and reptilian needs. In depth knowledge about the requirements of reptiles, and the system itself. A realisation of how reptile pets are more demanding than most people realise. A gain of interest about reptilian pets

Plan of Action. Ghant chart. Hours. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 Plan of action and clarification of problem.   - analysis of the product. - production of a brief. - conduction of research. - analysis of research data. - production of the specifications Development of design proposals. - production of a range of ideas. - analysis of ideas to work up a proposal. - working up the proposal into a viable solution - production of a manufacture plan. Manufacturing and modelling. - ordering and collecting materials. - completion of sub systems. - assembly and testing. Conclusions, evaluations and recommendations. - designing testing procedure. - gaining user analysis. - writing up findings. Communication and presentation. Ghant chart. For my plan of action I have decided to use a Ghant chart to plan out the time distribution., this will allow me to plan my allotted time (100 hours) into all sections of work . I have split the time (100 hours) into 5 main sections: Plan of action and clarification of problem, Development of design proposals, Manufacturing and modelling, Conclusions evaluations and recommendations and finally communication and presentation. These 5 main sections cover all of the time given and are indicated by purple lines on the Ghant chart. The main sections are split into numerous sub-sections showing what I will be doing in this time and when I will be doing it in that time area, the subsection timings are shown by a blue line on the chart. I am aware that in a project certain circumstances arise that cannot be avoided and waste time, for this I have allowed for an overflow limit on each section to cover if this circumstances do arise, this is shown by a red marker on the Ghant chart. The lines overlap at the overflow limits as they can be started then if the other tasks are completed in time. The final main section (communication and presentation) covers all of the Ghant chart as I will be continuously working on this task throughout all my project, it also has a time slot at the end to allow for improvement of the whole project. Communication and presentation is also the only main section not to consist of sub-sections as these are trivial and not required within this section.

Possible areas of Research? Research Plan. This Spider diagram is a basic plan of research, I have indicated my main focuses of research (red ovals) and what I will need to research about them (black squares). This diagram is shown in a tabulated format, with the information on how and why I will do this research, on the page below. Safety. Humidity. Cost. Temperature. Demands. Animal Requirements. Commercial Viability. Materials. Vivarium Types. Humidity controllers. Possible areas of Research? Specific Condition Vivariums. Technology Required. Humidity measurers. Size. Already on market? Temperature controllers. Existing Products. Materials Required. Temperature measurers. Price? Woods. Size? Availability? Metals. Composites. Plastics.

Research Plan. What? Why? How? Commercial viability. To see if, and why the product will sell on the market. Questionnaires of reptile owners (sample of 20). The Cost of the finished product. To find out how much the consumers are willing to pay for the product. The consumers needs and wants. To find out what the product will require. Technologies. To gain knowledge of technologies that may be of use in the product. Various methods. Humidifiers/De-humidifiers. To find ways of controlling the humidity within the vivarium. Expert Advice, internet research. Temperature Control. To find a suitable way of controlling the temperate to the set requirement. Use of internet engineering sites. Temperature Recording. To find a suitable way to measure the temperature of the vivarium. Humidity Recording. To find a suitable way of measuring the humidity of the vivarium. Materials. To find suitable materials for the my product. Metals. To find if there are any suitable metals I can use in my product. Testing metals, internet research. Plastics To find if there are any suitable plastics I can use in my product. Testing plastics, internet research. Woods. To find if there is any suitable timber I can use in my product. Testing wood, internet research. Composites. To find if there are any suitable composites I can use in my product. Testing composites, internet research. Existing Products. To gain information on competition in the market, or a respective gap. Checking in-store, internet research. Any already on the market? To see competition or gaps for my product. Price of those on the market, or similar products. To gain a respectable price range for my product. Availability of the products. To find if there is a real need for my product Size of the products. To see if my product can be smaller than existing products whilst still functioning. Types of vivarium. to gain specific information as to whether my product is best suited to one type of vivarium. Personal knowledge, expert advice, internet research. Size. To gain appropriate info on size vs. heating strength ratio. To gain relevant information on he materials best suited to a vivarium. Specific condition vivariums. To see if my system is better in a specific condition vivarium e.g.: watertight. Personal knowledge, expert advice, internet research Animal Requirements. To ensure the system will meet the animals health requirements. Personal knowledge, expert advice. Temperature. To ensure the animal will not overheat/freeze. Humidity. To ensure the animal will not drown/dry out. Safety. To ensure my product cannot harm the animal.

Research area 1 - Commercial Viability. Primary research. For my primary research into the commercial viability I have chosen to ask 20 people who own reptilian pets, or are interested in reptilian pet safety what they want/need in a possible system, this questionnaire is shown in the appendices. I decided to use a liket scale as it provides a rapid and easy to understand set of quantitative data, this data will allow me to see where consumers want specific things or if they would prefer not to have them, by calculating the total score (multiplying the amount of people choosing a score (eg 3 people choosing four gives a total of 12), then adding all the scores for the question together and then dividing by the total amount of people asked (20). This will give me the average score for each question, I have decided that if the average score is above (or very close to) 3.5 then I will incorporate that idea into my project as a specification, if this is possible. The reason for choosing 3.5 is it is above halfway and will indicate a majority view on the subject. Results. The results below show that the potential consumers would prefer a self heating vivarium (average point score=4.15) and a majority would also like one that maintains humidity also. There seems to be a common thought as to the knowledge of reptilian pet safety is low, indicating the need for a self maintaining system to overcome human ignorance. The majority of potential consumers would prefer a separate attachment to a vivarium, so this will be the design base of my product if it is at all possible. This information will be what I base the most simple design of my product around, ensuring I meet all the criteria given by the results where possible (self heating, humidity controlling, separate from vivarium). By following these criteria I can ensure   1 2 3 4 5 Average score. a self heating vivarium? 12 4.15 a humidity controlling vivarium? 6 3.45 the widespread knowledge of reptilian pet requirements? 17 1.30 Fixed into a vivarium? 9 2.45 Separate add on? price. 8 2.35 Conclusions. From this set of results I can conclude that the consumers are almost all wanting a self heating vivarium, so I will have to include this as a specification into my product due to the sheer demand. While only scoring 3.45, the humidity control is very near the limit, and with my own personal knowledge I will include it in my product as there is a definitive lack of information known to the general public (shown by the small score of 1.30) so in order to fill this gap my product must cover all the reptilian requirements to ensure no animal cruelty is caused by ignorance. My product is probably going to be a separate add-on due to the higher demand of that to the fixed idea, even if it does fall short of my score limit, the product must be one of the 2 so I will go with the most popular answer. The consumers do not seem too influenced by the price of the product showing a preference of quality over prices, understandable within the circumstances, this means that I can use more expensive materials (when available) within my product to ensure it works efficiently. With these specifications I can now define the key areas where I will have to provide extra research on, these areas are : Temporary fixing methods Components – price, reliability and tolerance.

Research area 2 - Required Technologies. Humidity measurement. I found 2 main techniques to measure the humidity of the vivarium, one is a psychrometers using a wet and a dry bulb, the other is a mechanical system using organic matter. Wet and dry bulb psychrometers are the most simple and common way of measuring humidity. This type of hygrometer uses two basis thermometers, one with a wet bulb one with a dry bulb. Evaporation from the water on the wet bulb causes its temperature reading to drop, causing it to show a lower temperature than the dry bulb. Relative humidity is calculated by comparing the readings using a calculation table (shown on next page) that compares the ambient temperature (the temperature given by the dry bulb) to the difference in temperatures between the two thermometers. A mechanical hygrometer uses a slightly more complex system, based on one of the first Hygrometers designed in 1783 by Horace Bénédict de Saussure. This system uses an organic material that expands and contracts as a result of the surrounding humidity. The organic material is held under slight tension by a spring, which is linked to a needle gauge that indicates the level of humidity based on how the hair has moved. The best method to measure humidity will be with the psychrometers as I can use thermistors in a potential divider to measure the change in humidity via temperature. Humidity control. Increase. Steam – Often referred to as a "vaporizer," a steam humidifier boils water and releases the warm steam into the Air. This is the simplest, and therefore the least expensive, technology for adding moisture to the air Impeller - In this humidifier, a rotating disc flings water at a comb-like diffuser. The diffuser breaks the water into fine droplets that float into the air. These droplets are usually seen as a cool fog exiting the humidifier. Ultrasonic - An ultrasonic humidifier uses a metal diaphragm vibrating at an ultrasonic frequency, much like the element in a high-frequency speaker, to create water droplets. An ultrasonic humidifier is usually silent, and also produces a cool fog Decrease. The four main ways to decrease humidity are to: 1-Increase heating temperature 2-Increase minimum pipe temperature 3-Reducing the venting temperature 4-Set a minimum vent opening The first 2 options are ineffective on their own, and can even be counterproductive due to the water evaporating in the heat, the third option is highly effective as it condenses water in the air before it enters the vivarium reducing humidity, however it can also have a counter effect of cooling down the vivarium itself. Setting a minimum vent opening will allow for cooler dry air to be added when needed and not when the air is dry but too cold, a mixture of the last two ideas is probably the best for my circuit as there is always a pool of water in a reptile vivarium and it will also require no method of increasing humidity as with the temperature requirements in a vivarium water evaporation will occur naturally. Temperature measurement. I had previous knowledge of the first three options to measure temperature however after researching I compiled information on thermocouples also. Thermistors. Allow for direct input of the relative temperature into a circuit via a change in resistance, when used in a potential divider they can compare the temperature to a set amount (given by another resistor) before a signal is produced, causing a limit on the maximum/minimum temperature. Also if the second resistor is variable, the temperature limits can be changed. Limit switch on a thermometer. Applying two limit switches to a thermometer with a mechanical dial will allow for a permanent temperature limit to be reached, however as this cannot be changed it will only ever be suited for one type of reptile as they all have different requirements. Separate thermometers. A separate thermometer will allow the owner to see the temperature at the current setting and higher/lower the temperature output in accordance, however this makes the product an open system instead of a mainly closed system as it will require regular attention (every few days). Thermocouples. A junction between two dissimilar metals produces a voltage. In the thermocouple, the sensing junction produces a voltage that depends upon the temperature. This voltage can then be read by a circuit (eg: a programmable interface controller (PIC)) in order to display the temperature or to perform an action at the limit voltage. The best solution to my product is the thermistors as they are small, inexpensive and are easily integrated into the circuit, they also allow for an alteration in the limits of the temperature to allow for the different animal requirements. Temperature control. Heating. I could only find two methods of generating heat energy electronically, these method are known as Joule heating and friction conversion. Joule heating, also known as ohmic heating and resistive heating, is the process by which the passage of an electric current through a conductor releases heat. By varying the current and the length of the wire the heat produced varies in proportion to the square of the current multiplied by the electrical resistance of the wire. This will allow for the heating of the vivarium using strips of metal, however these will have to be covered as the metal will reach a high temperature and would harm the reptile. The conversion of friction into heat could be made by having two rotating objects moving at a reasonable speed against each other, this will convert some energy into heat which can then be supplied into the vivarium, however this is a highly inefficient system and would require more venting, so the best option of increasing the temperature is to induce joule heating. Conserving. A way to keep the temperature at an intended level for a longer period of time would be to conserve the heat already in the vivarium, this is usually very energy efficient and could be achieved by using insulating foam in the walls of a vivarium this however stops heat entering the vivarium via the walls and will not cover glass panels, or by using “solar glass” which allows heat to enter the vivarium but not escape, this could however overheat the vivarium if not constantly attended to. The main disadvantage of both of these is that they would require a full vivarium to be manufactured and altered, making my product large and expensive, these will have to be taken into further consideration with the consumer ideals. Cooling. I found two ways of cooling down the vivarium. The first method of cooling is to just let it cool itself down, this can take time to occur but allows for a gradual decrease of heat with no energy output at all. The other method is to use the Peltier effect when a current is passed through a specific circuit the upper junction of the circuit releases heat (could be used for a heating system) while the lower junction absorbs heat (used for cooling system) however this circuit is complex and requires the use of specific and expensive materials beyond my productivity limits.

Research area 2 - Calculation Table. WET BULB TEMPERATURE of 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 3 7 11 15 19 23 27 31 36 68 73 78 84 89 94 100 1 4 8 12 16 20 24 28 32 37 64 69 74 79 95 2 6 10 14 17 21 25 29 33 38 26 30 34 39 65 70 9 13 35 75 80 85 90 18 DRY BULB 83 TEMPERATURE oF This table is used to calculate the relative humidity from the psychrometer readings (previous page) at the shown temperatures (of) on both the wet and dry bulb a reading is shown for the relative humidity. For example when the temperature is 61oF(16oC) in the vivarium and 50oF(10oC) in the water the relative humidity is 49% at some temperatures (eg:40oFin the wet bulb and 65oF there is no reading, this is because there is no relative humidity in these temperatures due to the fact that unless in a false condition the water should never reach lower than 41oF)

Research area 3 - Existing Products. Helix DBS-1000 Proportional Thermostat The best digital proportional thermostat on the market! $129.95 each You save $5.00 Helix DBS1000 Thermostat with grounded plug Same features as original DBS1000, but comes with a grounded plug for use with metal rack systems. $136.00 each You save $3.95 Helix DBS 1000 Thermostat & Temp Gun Special Helix DBS 1000 Thermostat & Infrared Temperature Gun $149.99 each You save $5.00 Helix DBS1000, Night Drop Cord & Temp Gun Combo Special includes the DBS1000 Helix Thermostat, the Appliance Timer Adapter Cord and the $25 Infrared Temperature Gun $174.99 each http://lllreptile.com/store/catalog/reptile-supplies/thermometers-thermostats-and-timers/ Conclusions. After Conducting some research I found these products that are similar to what mine will be, however they all only measure and control temperature (albeit accurately) and are extremely expensive and cost around the same price as a vivarium itself, even with the discounts. This means my product will have a good standing on the market, however as there are so few products like this it shows that the market niche is very small and I should be careful to make sure my product meets consumer demand, or it may not become successful. However the size of these products is very small and my product will have to be a lot larger in order to cope with the humidity, I believe though that the requirement for a set humidity will outshine the want for a small product. These products are small add-ons to a vivarium that both measure and alter the temperature within a vivarium, in this respect they are almost the same as my system, however they do not monitor humidity in any aspect which I am hoping for my product to do. However these products are from a reputable brand of thermostats and so consumers might look over my product at a lower price due to their reputation. Other products for the sub-systems. I have realised that to find alternate methods of controlling the humidity and temperature of my design it is possible to look at existing products for inspiration. Existing products to alter environments. - Fish tank heaters increase the temperature of the specific environment they are in quickly and are easy to attach, the main problem with using a fish tank heater is that my vivarium is not underwater and if a fish tank heater is turned on out of water they will crack and stop functioning. This problem is easily solved by encasing the heater within a water tight casing filled with water, this will allow the heat to travel by convection out of the water into the water and into the vivarium. This product can be used for both temperature and humidity if placed in a specified water bath. - Radiators increase the temperature in a house by moving hot water through the system, while moving hot water is not viable for my design, using still hot water being heated in copper tubes is viable and will give a similar effect. The convection of the heat will also supply a temperature gradient that reptiles require. Greenhouses alter the temperature and humidity by opening and closing windows automatically, while an open window would be a hazard for a reptile escaping, fixing a mesh into the window would prevent the reptile escaping, however a moving object in a vivarium is not viable due to predatory reptiles thinking it is prey and/or a threat. bi-metallic strips are used in greenhouses also, they detect larger fluctuations in temperature and bend accordingly, this being is caused by the two metals it is composed of having different rates of expansion and compression. Misting mechanisms extrude a mist of water into the environment greatly increasing the humidity, they however cool down the environment which is not a good thing for the reptile within the vivarium. These mechanisms use solenoid valves to separate the water into a mist these mechanisms also require larger amounts of water and can increase the humidity by an overly large amount.

Research area 4 - The Vivarium. There are various forms of vivarium, including: Aquarium - simulating a water habitat; for instance a river, lake or sea; but only the submerged area of these natural habitats. Plants in the water will use some nitrogen present within the system, and will provide areas for organisms to hide and forage. Insectariums - containing insects. Formicaries - with species of ants. Paludarium - simulating a rain forest or swamp environment. It also can be seen as an aquarium interconnected with a terrarium, having both the underwater area as well as the shore. Riparian - a Paludarium with circulating current through different-levelled pools Terrarium - simulating a dry habitat, for instance desert or savannah. A terrarium can also be formed to create a temperate woodland habitat, and even a jungle like habitat. This can be created with pebbles, leaf litter, and soil. By misting the terrarium, a natural water cycle occurs within the environment by condensation forming on the lid causing precipitation. Plants suitable for this type of terrarium environment include moss and tree seedlings. Many kinds of plants are suitable for these habitats, including bromeliads, African Violets and Crassulaceae. Animals commonly held for observation include reptiles, amphibians, insects, spiders, scorpions, and small birds. Size and materials Vivarium with epoxy-coated plywood walls It is usually made of a clear container (often plastic or glass). Unless it is an aquarium, it doesn't need to withstand the pressure of water, so it can also be made out of wood or metal, with at least one transparent side. The new fashion in vivariums are those constructed from epoxy-coated plywood and fitted with sliding glass doors. Coating the inside of a plywood vivarium helps to retain the natural effect of the environment. Epoxy-coated plywood vivariums retain heat better than glass or plastic enclosures and are able to withstand high degrees of humidity. They may be cubical, spherical, rectangular, or other shapes. The choice of materials depends on the desired size and weight of the entire ensemble, resistance to high humidity, the cost and the desired quality. The ground surface must be calculated to be enough for the species living inside, at their adult size. The height can also be important for the larger plants, climbing plants, or for tree climbing animal species. The width must be big enough to create the sensation of depth, both for the pleasure of the spectator and the good of the species inside. Most used substrates are : common soil, small pebbles, sand, peat, chips of various trees, wood mulch, vegetable fibres (of coconut for example), or a combination of them. The choice of the substrate depends on the needs of the plants (type of ground), or of the animals (need to dig galleries for example), moisture (resistance to mould, conservation of water), the risks involved (e.g. the risk of absorption by an animal) and aesthetic aspects. Sterile vivariums sometimes used to ensure high levels of hygiene (especially during quarantine periods), generally have very straightforward, easily removable substrates such as paper tissue, wood chips and even newspaper.

Research area 5 - Animal Requirements. Reptile Heating: Reptile heating is an extremely important factor in the success of keeping a pet reptile. It can be one of the main reasons to ensure the reptile has a long and healthy life, however there are many factors involved in the process of heating a reptiles housing. So I will have to take each of them into account before attempting to make a product. The Reason For Heating: Due to the fact that the majority of reptiles come from warm climates it is necessary for a reptile keeper to replicate their natural living environment within the housing created for them. The reason for keeping a high temperature in a reptile’s vivarium is because reptiles are ectothermic (cold blooded) creatures that cannot regulate their own body temperature meaning that they use the environment they are in to heat their body. Not only does a warm temperature keep the reptiles warm it also aids the digestion process, therefore it is imperative that a reptiles vivarium is heated correctly. This means that the system must work the majority of the time and if it breaks, it should possess a backup system that not only attempts to keep the vivarium in check but alerts the pet owner to the problem so the reptile is exposed to non-ideal conditions as little as possible. Temperature Gradient: A reptiles cage should have a temperature gradient within its housing that allows for a warm and a cool area, this is to allow the reptile hosed within the tank to move to a temperature where they feel comfortable. The benefits of this mean that reptiles can move to the hot area of the tank after a meal so the heat can help them digest their food quicker. An average reptile temperature within a housing should be no cooler than 20°C and no warmer than 32°C to ensure a good temperature variation within the tank. This could be created by using a heating system on the floor of the vivarium to crate a vertical temperature gradient. Hotspot: A hotspot is an area within a reptiles housing that has a higher temperature than the rest of the reptiles tank, this helps to provide a temperature gradient as stated above. This means I will have to centre the majority of my heating system into one area. Humidity: Different reptiles require different humidities due to changes in their habitat for example the majority of snakes live in dry areas and so require a low humidity, however a poison dart tree frog lives in rainforest and as such requires a high humidity. This is due to the fact that reptiles/amphibians are specifically adapted to their respected habitats. Components. Despite their scales reptiles are still vulnerable to injury, this means the my device will have to be as safe and/or enclosed as is possible. Below I have listed a few safety hazards my product will face along with possible solutions: Sharp objects in the vivarium – conceal all sharp objects within the casing and round off all edges of the casing. Exposed wires/visible wires – make sure all wires are connected up safely and ensure no loose wires are disconnected, if they are they must be covered up to conceal the wire itself. Also any visible wires within the vivarium must be fixed in place due to excessive movement might cause a reptile such as a snake to attack the wire thus endangering it further. Exposed heating/cooling surfaces – these can be particularly dangerous, an exposed heating surface could cause contact burns on the reptile itself, whilst if a reptile is caught on a cooling surface it could freeze to death before the pet owner noticed. Holes – my product might require hole being made in the walls of a vivarium, however if these holes are too big and/or weaken a wall surface this could give the reptile a way out of the vivarium into the colder air outside, or even into more danger caused by the outside world. Moving objects – if an object is in motion and is visible to a reptile, such as a snake, it will cause the reptile to strike the object assuming it to be food and/or a threat. This could cause not only faulty components but also damage to the reptile if It is caught within the moving objects. Light: Some reptiles prefer a certain level of U.V. lighting in their vivarium, this can be accomplished by the addition of a U.V. lamp, these are pretty low costs and highly cost effective, however these are unnecessary and could cause problems with the heat gradient of the vivarium itself, thus I have decided to not include the U.V. lighting within my circuit.

Research area 6 – extra research - fixing. 11 Research area 6 – extra research - fixing. Knock Down Joints. Adhesives.   PLASTIC CORNER BLOCK (FIXIT BLOCKS): The corner block is pressed against the two pieces of material (normally wood based). Screws are used to fix the block into position. This type of joint is used to fit modern cabinets such as those found in a kitchen. It is a relatively strong joint although it has the advantage that it can be dismantled using a screwdriver. NATURAL WOOD FITTING (SQUARE SECTION BATTEN): A piece of material such as pine can be drilled and screws can be passed through these holes. This gives a cheap and effective knock-down joint. The screws are normally countersunk into the knock-down fitting.    TWO BLOCK FITTING (LOK-JOINTS): These are made from plastic. A bolt passes through the first fitting into the thread of the second. As the bolt is tightened it draws the two fittings together. The pins help keep the fitting straight. This gives a very strong joint and it can be dismantled using a screwdriver. RIGID JOINT: These are normally moulded in plastic which makes them strong. Screws pass through the four holes which hold the sides at each corner firmly together. Adhesive or glue is a compound in a liquid or semi-liquid state that adheres or bonds items together. Adhesives may come from either natural or synthetic sources. Some modern adhesives are extremely strong, and are becoming increasingly important in modern construction and industry. The types of materials that can be bonded using adhesives are virtually limitless, but they are especially useful for bonding thin materials. Adhesives usually require a controlled temperature to cure or set. They can be electrically and thermally conductive or insulative. Pressure sensitive adhesives (PSA) form a bond by the application of light pressure to marry the adhesive with the adherent. They are designed with a balance between flow and resistance to flow. The bond forms because the adhesive is soft enough to flow (i.e. "wet") the adherent. The bond has strength because the adhesive is hard enough to resist flow when stress is applied to the bond. Once the adhesive and the adherent are in close proximity, molecular interactions, such as Van der Waals forces, become involved in the bond, contributing significantly to its ultimate strength. PSAs are designed for either permanent or removable applications. Examples of permanent applications include safety labels for power equipment, foil tape for HVAC duct work, automotive interior trim assembly, and sound/vibration damping films. Some high performance permanent PSAs exhibit high adhesion values and can support kilograms of weight per square centimetre of contact area, even at elevated temperature. Permanent PSAs may be initially removable (for example to recover mislabelled goods) and build adhesion to a permanent bond after several hours or days. Removable adhesives are designed to form a temporary bond, and ideally can be removed after months or years without leaving residue on the adherent. Removable adhesives are used in applications such as surface protection films, masking tapes, bookmark and note papers, price marking labels, promotional graphics materials, and for skin contact (wound care dressings, EKG electrodes, athletic tape, analgesic and transdermal drug patches, etc.). Some removable adhesives are designed to repeatedly stick and unstick. They have low adhesion and generally can not support much weight. Pressure sensitive adhesives are manufactured with either a liquid carrier or in 100% solid form. Articles are made from liquid PSAs by coating the adhesive and drying off the solvent or water carrier. They may be further heated to initiate a cross-linking reaction and increase molecular weight. 100% solid PSAs may be low viscosity polymers that are coated and then reacted with radiation to increase molecular weight and form the adhesive; or they may be high viscosity materials that are heated to reduce viscosity enough to allow coating, and then cooled to their final form. Mayor raw material for PSA´s are acrylate based polymers. Plastic wrap displays temporary adhesive properties as well.

Research area 6 – extra research – Components. 12 Research area 6 – extra research – Components. I have researched the different components I may require, they're prices, availabilities and tolerances. This will give me a general overview of what components would be best suited to my product. Environmental control. THERMISTORS – these components increase/decrease the resistance upon an increase of the temperature, this is accomplished by the energy of the electrons being increased as the resistive material is heated, this allows them to flow more freely around the material, thus reducing/increasing the resistive qualities of the material. The resistance increases by a specific constant known as the first-order temperature coefficient of resistance. The equation to work out resistance from temperature is: ΔR = kΔT Where: ΔR = the change in resistance, k = the first order temperature co-efficient of resistance and ΔT = the change in temperature. If k is the positive coefficient then the resistance will increase as temperature, similarly if k is negative then resistance will decrease as temperature increases. The different coefficients allow us to use thermistor to both increase and decrease the resistance in a circuit, however each thermistor has its own value of k that cannot be changed. Thermistor tend to be relatively cheap and are easy for me to acquire making the ma suitable device for measuring temperature in my circuit. HEATING PADS – in their most basic form these are just strips of high resistance metals, through which a large current is passed, as this current flows through the strips they heat up in accordance to the current, these strips can reach fairly high temperatures, and can become very dangerous very quickly if not properly covered up. The heat produced is calculated using the following equation: where Q is the heat generated by a constant current I flowing through a conductor of electrical resistance R, for a time t. this shows that the temperature is equivalent to the current squared, multiplied by the resistance of the material and then this is then multiplied by the time the current is applied for. Using this formula we can calculate the maximum temperature we want the strips to reach, to ensure that the vivarium doesn’t overheat, nor will the strips burn through their protective coating, endangering the reptile. Despite the extreme safety precautions these heating pads are reasonably priced and easy to access, or even manufacture by hand. MAINS CONNECTION – this would allow me to connect a mains powered component into my circuit this would allow for a higher voltage supply. Processing. PROGRAMMABLE INTERFACE CONTROLLERS (PICS) – these are programmable chips that will hold a set amount of data within them, this data will tell them how to operate when certain scenarios occur (example: temperature dropping below preferred value) these components use a software on the computer known as livewire. Using these allow for complicated systems to be made with relative ease, whilst also lowering the amount of components and hence the price and reliability. TRANSISTORS - these amplify the current allowing for a low amp output from a set component (e.g. a PIC) can operate a high ampage component such as a motor. These also allow things to be activated and de-activated. Inputs. VARIABLE RESISTOR – a resistor that allows the user to change its resistance, this will allow for an alteration in the set value that will decide the temperature limits if used in a potential divider . These are cheap and extremely easy to acquire, and thus are of great use in any circuit, however a rotating panel on my product might be altered by the reptile if it is housed internally, this could cause large implications. PUSH TO MAKES (PTM) – these are simple push to use switches, they make a connection when pressed and break it when released, they are useful for singular inputs or even multiple inputs with limited effects, they are of great use in a code or a number pad.

What? Why? Evidence. Specifications. Must accurately measure and control temperature. To ensure a safe temperature for the reptile to live in. Page 10: paragraphs 1-4. Must control the humidity within the vivarium. To ensure a maximum comfort for the reptile, the reptile should, ideally, have the same humidity within the vivarium as is in its natural habitat. Page 5: questionnaire results. Page 10 paragraph 5 Must strongly attach to the vivarium, whilst still being removable. To ensure that the system can stay in the vivarium without risk of potential harm to a reptile by collapse. General Knowledge. Must have no sharp edges. Sharp edges could easily cut the soft underbelly of a reptile. Page 10: components paragraph. Must leave no wires bare or easy to bite through. A bare wire and/or an easy to bite wire could cause the potential hazard of electrocution occurring to the reptile. Must have no exposed heating or cooling components. Can cause the potential for the reptile to freeze/overheat if it gets caught on the component. Any holes made in the vivarium must not be too large. Larger holes might let smaller reptiles escape the vivarium risking it damage from the outside world. There must be no moving objects within the vivarium. Moving objects will not only cause a risk to the snake by potential collision but also, a predatory reptile such as a snake, might mistake the object as a threat and/or food and will, as such, attempt to bite the object, either endangering the animal or causing damage to the system. Must be able to alter the temperature and humidity limits. Different reptiles will have different requirements of heat and humidity. Page 10: paragraphs 1-5. Must be easy to use. People might not be able to use the system if it is too complicated of use. General Knowledge Must have an alerting system if anything fails. So consumers will know when something requires a replacement and/or repairs. Must have a backup system if anything fails. To ensure the reptile is not harmed whilst the system is down. Must be able to be converted from bespoke into batch or mass production. To allow for adequate marketing.

14 Introduction To Ideas. Ideas. The next stage of progress is the designing of the ideas, these ideas will consist of in depth explanations of how the circuit works, the advantages that idea has above the others, or any disadvantages it may have, these will also allow me to decide which ideas are more suitable for my design. I have decided that instead of approaching each idea as a whole design idea I will explain each sub-system in detail and then choose not only the most efficient subsystems to make the final, whole, idea but also the subsystems that are the most compatible with each other. There are numerous different sub-sections that need to be addressed, but I will address them in groups which are: Temperature sensing and processing. Temperature modification. Humidity sensing and processing. Humidity modification. User interfacing. Casing of the design. Attachment of the case into a vivarium. Power supplies. These subsystems are shown in this diagram, with all the basic idea titles that I will be including. in my ideas section.

Ideas, subsection 1 – Power. 15 Ideas, subsection 1 – Power. 1. Temporary battery power, through a voltage regulator to produce a 5V DC supply. A normal pp3 battery produces a 9V DC supply without the capability of high current. By running this through a voltage regulator I can produce the steady 5V DC supply that is required to run my PIC, this will however decrease the current available from the battery. while they supply a decent voltage at low amps batteries have a short shelf life, even if rechargeable, this means that the user will have to pay to keep the product running when the battery runs out. Batteries however can be integrated into the case (as long as they can be easily removed by a user) allowing the product to become fully portable, most batteries take up very little space, the pp3 battery is approximately 48 mm × 25 mm × 15 mm so if integrated into a case there would be little if any need to increase the size of the case. by working out the ampere hours of the circuit you can calculate how long the battery will last for. because the battery only has a set voltage and current it is practically useless as a supply to any heavy duty items such as heathers or motors, however it is a highly adequate supply for processing signals as this is very low duty and thus will not wear out the battery too quickly. 4. Permanent battery power, through a voltage regulator to produce a 5V DC supply. This design is almost identical to the temporary battery, however the user would not be able to remove the battery from the casing without totally dismantling the case, this prevents the removing of the battery by children, or by animals, but causes the issue of not being able to remove an empty battery. Due to the lack of ability to remove the battery this system would require a rechargeable battery, this idea would also provide a professional look to the product. This power supply is often used in mp3 players and ipods. 5. Dynamo. A dynamo is basically a motor in reverse, it converts rotary mechanical energy into electric energy using a magnet and a coil of wire. This supply could only be viably used in conjunction with a fan for the cooling system as it could be attached to one end of the fan causing a feed back of a small amount of energy from the motor being used to rotate the fan. This, like the solar panels, could not viably be used as a full power source, however it would be able to charge a battery or could be used as an emergency backup generator. 2. Mains 240V AC supply. Every house in the UK is connected to a mains supply and so it is a readily available supply of energy. the mains supply can supply massive amounts of current to a circuit making it the perfect supply to use on heaters, motors and other heavy duty components that require rather large amounts of power. However in order to be used for lower duty components it would require passing through a transformer to lower the voltage (see section on transformers.) A high voltage and current make this idea extremely flexible, however it involves a high level of danger to myself. 6. Transformers. Not a power supply in themselves but they can be used to step-up, or step-down the voltage and current of other supplies (such as the 240V mains supply to generate a 12V supply). these are of great use when running two circuits that both require different power supplies (such as a 12V circuit activating a 240V circuit via a relay.) However transformers require a supply of AC as the electromagnetic effect cannot be established with a DC supply, similarly they also can only emit AC, however this can be altered into a DC supply by using a bridge rectifier diode setup. 3. Solar. This would only be useable as a backup supply of power or as a charger for the main source (if it’s a rechargeable battery) solar would be of use in my project as the majority of vivarium use a lamp to provide a light source for the reptile to provide a sense of night and day, so while the lamp is on using solar panels on the upper face of the casing would re-use a miniscule amount of the light energy provided by the lamp as electrical energy for my system making it more energy efficient.

Ideas, subsection 2 – Temperature measurement and processing. 16 Ideas, subsection 2 – Temperature measurement and processing. 1. Thermistor with operation amplifiers and potential dividers. This circuit consists of two potential dividers, one using a variable resistor to allow a limit to be set (PD2) and the other using a thermistor to measure the temperature in the vivarium (PD1), these potential dividers are then compared by two operation Amplifiers (OP-AMPS). Depending on whether the temperature is high enough to allow a voltage from PD1 that is larger than the one produced in PD2, through to the OP-AMP then the cooling system will switch on, while at the same time the heating system will be switched off. However when the temperature is too low, the voltage from PD2 is greater than that from PD1 and so the cooler is turned off and the heater is turned on. This occurs due to the set up of the two OP-AMPS, the first is set up so it will supply a positive voltage if PD1 is greater than PD2 but a negative if it is smaller, the second OP-AMP however is connected in the opposite way, so when PD1 is of a higher value than PD2 it supplies a negative voltage, but supplies a positive voltage if PD1 is lower. When a positive voltage is released from the first OP-AMP into transistor 1 (T1), the transistor allows current to flow from its collector to its emitter activating the relay for the cooling system (RLY1). Whereas if a positive voltage is released from the second OP-AMP then it activates T2 allowing current to flow through activating RLY2 for the heating system. This circuit will measure the temperature by altering the first resistor value in PD1, thus altering the voltage signal (Vs). This Vs is then compared against the Vs from another potential divider set at a constant value, until changed by user input. When temperature is higher the resistance of the thermistor decreases, thus increasing the Vs for that potential divider. This circuit will allow for an accurate measurement and processing of temperature value, comparing it against a set limit and activating the heater/cooler respectively, while also preventing both the heater and the cooler being active at the same time. The main problems with this circuit are that is has no settable timer to receive values from the PDs so every flux in the temperature is measured, so a small change in temperature, that might not need noticing can cause the heater to turn off and the cooler turn on, or visa versa, this circuit will also rely on a split rail voltage that includes a negative voltage, this can cause issues when manufacturing the circuit board especially if short circuits occur. 3. Thermistor with a Programmable Interface Controller (PIC). this Circuit consists of a single thermistor within a potential divider that feeds into the analogue input of the PIC this is then compared against the voltage of another potential divider which can be set to certain values using a variable resistor. After a set time the PIC will compare the two voltages and if the thermistor provides the higher voltage then the PIC will only activate relay one, this in turn will activate the cooling system, however if the variable resistor provides the higher voltage the PIC will only activate relay two in turn activating the heating system. attached to seven of the outputs is a 16pin resistor array set at 220ohms, this resistor array is also connected to seven light emitting diodes (LED), these seven LEDs provide a user interface display, one LED will be used as a power light showing that the system is active the other six are temperature representative, if the air is too cold, only the first two will light, if it is within the boundaries of limitation that have been set then the second pair will light, so four LEDs are lit and finally if the temperature is too hot, all LEDs will be lit, these six LEDs will be colour coded, two green to show cold, two orange to show acceptable and two red to show too hot. D1 R1 R2 R5 D2 OP-AMP1 TR1 R3 R4 OP-AMP2 R6 TR2 4. Thermocouple with two Operational Amplifiers used as comparators. Thermocouples (TC1) induce a current dependant on the temperature this voltage is then compared against the voltage from the first potential divider (PD1) in OP-AMP1 if the voltage induced is larger than that from the first potential divider then OP-AMP1 produces a positive voltage, this voltage will activate TR1 which allows current to flow through TR1 this activates the first relay (RLY1) which controls the cooling system, however if the voltage induced from TC1 is smaller than that of PD1, OP-AMP1 will supply a negative voltage to TR1, this will however not activate it, so RLY1 will not be activated and the cooling system remains switched off. the voltage induced from TC1 is also compared against the second potential divider (PD2) by OP-AMP2 however if the voltage induced from TC1 is larger than that from PD2 then OP-AMP2 supplies a negative voltage to TR2 so both TR2 and RLY2 remain inactive and thus the heating system remains inactive, however if the voltage induced from TC1 is lower than that of PD2, OP-AMP2 will produce a positive current to TR2 allowing current to pass through, activating RLY2 and in turn activating the heating system. Because TC1 produces a voltage dependant upon the temperature it is a consistent monitoring of the temperature, however the voltage increase from the small temperature increases in my design could be difficult to limit, due to limitations upon the resistors in the potential dividers. 2. Bi-metallic strip breaking a circuit. This circuit uses a bi-metallic strip to monitor the temperature, because the bottom half of the bi-metallic strip (in this case copper or Cu) has a higher expansion rate than the upper half (in this case iron or Fe), the Cu expands at a faster rate than the Fe as the temperature increases, however they are bonded together and fixed into a solid support at one end, thus the Cu expands and bends the bi-metallic strip towards the Fe, using this I can place a push to brake (PTB) in the path of the bending strip, thus setting a temperature limit. While the PTB is not pressed by the bi-metallic strip, current passes to the base of the resistor activating both it and the relay, while the relay is active the heating system is active but when the PTB is activated by the bi-metallic strip hitting it, the relay is de-activated and the cooling system is activated. This system records a wide range of temperatures, and tiny fluctuations will not effect the bimetallic strip, so the relay will not constantly switch on and off, however with the temperature changes required in the vivarium, the bi-metallic strip might not be effected due to the changes being too small, the strip will also require a time to bend, this could cause complications in the speed of reactions. The circuit is relatively simple and easy to manufacture and could be the least expensive circuit to manufacture, however the practical offsets made by the bi-metallic strip greatly outweigh the circuits simplicity and ease of manufacture, and thus it is probably not the best method for my design.

Ideas, subsection 2 – Temperature measurement and processing continued Ideas, subsection 3 – user interfaces Ideas, subsection 4 – temperature control. 17 5. Thermistor through a potential divider into a PIC controlled by a rotary switch into 5 inputs. A change in temperature is recorded by the thermistor within the potential divider, this then produces a signal which is recorded by the PIC. Depending on which input is activated by the rotary switch, the signal from the potential divider is compared against a set value range specific to which of the digital inputs on the PIC is activated. this allows for a multitude of set ranges for the temperature within the vivarium with relatively easy use. However this will use every input into the PIC with the only exception of one analogue input this will thus prevent any extra inputs if necessary. 2. Cooling by increased ventilation. Increasing the ventilation of the vivarium would rapidly cause a decrease in temperature (down to that of the rooms ambient temperature) this would be useful as long as the ventilation holes were either covered by the product OR covered by a fine mesh small enough so while air can still traverse through, neither the reptile nor its respective food can escape. By using a metal panel (as shown) we can monitor the amount of ventilation And thus maintain the amount of relatively cool air Being let into the vivarium. An increase of cool air entering the vivarium would cause a decrease in the time taken for the temperature within the vivarium to fall whereas less air would cause the temperature to fall less rapidly. A rotary fan may also be used. 1. Two seven-segment LED displays displaying the temperature at a specific point of time. Using further research into the temperature ranges and their specific values from the potential divider with the thermistor in (this is going to be necessary in the project with or without this interface) I can program the PIC to generate a number of pulses depending on value (approximately equal to the temperature) so this value can then be counted by two 4018’s providing the 7-segment LEDs with current to the correct pins in order to display the approximate temperature value, another output from the PIC would reset the 7-segments this operation would occur every time the PIC Checked the temperature. 3. Fish tank heaters. By conducting research about existing products, I found that fish tank heaters are an efficient method of increasing temperature within an isolated environment. Connecting the heater to a supply that can automatically alternate between on and off would be simple enough if used with a relay but could be very complicated if done in other ways due to the requirement of a power supply consisting of 240V A.C. Using a fish tank heater outside of water however will cause the casing to crack and break, preventing the heater itself from functioning and could cause large issues to the reptiles safety due to broken glass and potentially hot surfaces. However if the heater is encased in liquid (for example water (H2O)) which is contained by a glass or polymeric case the heater will not break and the liquid will allow for the heat to travel by convection through the casing into the vivarium heating the entire isolated environment. 4. The conduction of heat using water. Because water is a good conductor of heat it can be used to convey the heat produced around the entirety of the vivarium equally. The heat could be produced using one of the above methods, this system however will require the construction of an entire vivarium and will provide no temperature gradient. 2. Six Led’s providing a coloured scheme display to show relative temperature to set values. When the temperature is monitored by the PIC depending on which operation the PIC must perform it will send two signals to two specific LEDs through the resistor array the LEDs will be coloured in a specific order (see figure right) this shows whether the temperature is cold (G), just right (A) or too warm (R). this will allow the user to note as to whether the system is faulty, or if it is safe for use at that specific moment (when first set up). This interface would best be used in conjunction with idea no. 5 of the systems for monitoring of temperature as the use of macros would enable easy use of set programs and the idea in speculation is very easily adapted to using macros. This interface is relatively easy to manufacture and for use by the user. 5. Heating effect by power wastage. When current is passed through a circuit with resistance, some power is lost from the circuit as heat, while this is a problem in most circuits it may have a use in mine. If I can contain the metal (preferably copper) strips in a conducting material, so the heat can escape but the reptile wont run the risk of burning itself on the strips themselves. There is an equation to calculate the power lost as heat in a circuit in Watts, this equation is shown below, and is also converted to include the resistivity of copper strips; Pw = I2R Pw = I2ρSal Pw = I2ρV Where Pw is the power in Watts, R is the resistance of the circuit, I is the current of the circuit, ρ is the resistivity of copper, Sa is the surface area of the copper strip, l is the length of the copper strip and V is the volume of the copper strip. This equation allows me to alter the heat output of the circuit, while it would be difficult and expensive to alter the volume of copper in the equation I can easily alter the current and/or voltage of the circuit to increase/decrease the heating output. 1. Underground heating. Using a system in which the heating is on the bottom floor of the vivarium (either built into the base, or kept under the woodchips) allows for the heat to travel through the vivarium by convection, this will induce a temperature gradient throughout the vivarium with higher temperatures at the bottom and lower temperatures along the roof, however it will take time for heating effects to take place and at lower temperatures the heating effect may not reach the top parts of the vivarium at all. This system is also inefficient due to the heat wastage in the convection, however it is easy to construct and relatively inexpensive.

Ideas, Development of idea - Circuitry. 18 Ideas, Development of idea - Circuitry. Thermistor through a potential divider into a PIC controlled by a rotary switch into 5 inputs. A change in temperature is recorded by the thermistor within the potential divider, this then produces a signal which is recorded by the PIC. Depending on which input is activated by the rotary switch, the signal from the potential divider is compared against a set value range specific to which of the digital inputs on the PIC is activated. this allows for a multitude of set ranges for the temperature within the vivarium with relatively easy use. However this will use every input into the PIC with the only exception of one analogue input this will thus prevent any extra inputs if necessary. Reasons: For - Allows for preset “allowable” temperature ranges to give reptile a variety of temperatures to allocate its preferences. Enables security of temperature range, as the rotary switch is less likely to be accidentally turned than a variable resistor. Very specific design allows for concentration to be allocated on its main functioning. Not overly complicated circuit. Against - Design is very specific limiting the amount of variations available to make product more diverse. Very few spare inputs stop use of extra controls Quite sizeable circuit board would be required. Six Led’s providing a coloured scheme display to show relative temperature to set values. When the temperature is monitored by the PIC depending on which operation the PIC must perform it will send two signals to two specific LEDs through the resistor array the LEDs will be coloured in a specific order (see figure right) this shows whether the temperature is cold (G), just right (A) or too warm (R). this will allow the user to note as to whether the system is faulty, or if it is safe for use at that specific moment (when first set up). This interface would best be used in conjunction with idea no. 5 of the systems for monitoring of temperature as the use of macros would enable easy use of set programs and the idea in speculation is very easily adapted to using macros. This interface is relatively easy to manufacture and for use by the user. Reasons: For - Allows display of relative temperature, thus suiting the temperature recording system as it can show if, for the selected input, whether the temperature is too low, high or just right. Easy to integrate into a circuit. Cheap cost due to low price of LEDs Simple design makes it easy for consumer use. No further research is required in order to use this option. Against - simple design might make design seem less professional. May cause problems if the temp range is set wrong as no indication of true temperature. Will not satisfy and user curiosity of the temperature. Heating effect by power wastage. When current is passed through a circuit with resistance, some power is lost from the circuit as heat, while this is a problem in most circuits it may have a use in mine. If I can contain the metal (preferably copper) strips in a conducting material, so the heat can escape but the reptile wont run the risk of burning itself on the strips themselves. There is an equation to calculate the power lost as heat in a circuit in Watts, this equation is shown below, and is also converted to include the resistivity of copper strips; Pw = I2R Pw = I2ρSal Pw = I2ρV Where Pw is the power in Watts, R is the resistance of the circuit, I is the current of the circuit, ρ is the resistivity of copper, Sa is the surface area of the copper strip, l is the length of the copper strip and V is the volume of the copper strip. This equation allows me to alter the heat output of the circuit, while it would be difficult and expensive to alter the volume of copper in the equation I can easily alter the current and/or voltage of the circuit to increase/decrease the heating output. Reasons: For - Is capable of giving large amounts of heat out. Not overly expensive, especially if made by hand. Quick response to alteration of the circuit. Allows for a varied heating effect. A prebuilt “heat mat” can be used. Against - High energy running costs. “Heat mats” can be expensive. Requires 240V AC supply. (mains.) My cause damage if metal is not insulated properly.

Ideas, Development of idea. 19 Ideas, Development of idea. Temporary battery power, through a voltage regulator to produce a 5V DC supply. A normal pp3 battery produces a 9V DC supply without the capability of high current. By running this through a voltage regulator I can produce the steady 5V DC supply that is required to run my PIC, this will however decrease the current available from the battery. while they supply a decent voltage at low amps batteries have a short shelf life, even if rechargeable, this means that the user will have to pay to keep the product running when the battery runs out. Batteries however can be integrated into the case (as long as they can be easily removed by a user) allowing the product to become fully portable, most batteries take up very little space, the pp3 battery is approximately 48 mm × 25 mm × 15 mm so if integrated into a case there would be little if any need to increase the size of the case. by working out the ampere hours of the circuit you can calculate how long the battery will last for. because the battery only has a set voltage and current it is practically useless as a supply to any heavy duty items such as heathers or motors, however it is a highly adequate supply for processing signals as this is very low duty and thus will not wear out the battery too quickly. Mains 240V AC supply. Every house in the UK is connected to a mains supply and so it is a readily available supply of energy. the mains supply can supply massive amounts of current to a circuit making it the perfect supply to use on heaters, motors and other heavy duty components that require rather large amounts of power. However in order to be used for lower duty components it would require passing through a transformer to lower the voltage (see section on transformers.) A high voltage and current make this idea extremely flexible, however it involves a high level of danger to myself. I have decided to use the two power inputs as my circuit requires two separate voltages the mains supply can provide enough voltage and current to run the heater whilst the batteries can provide the low voltage – low current requirements of the PIC. My circuit could not include humidity control as this was unfeasible within the time constraints and with schools supplies.

Ideas, Development of design – PCB programming design. 20 Ideas, Development of design – PCB programming design.

21 PCB Development. The first section of my development is to design and develop a printed circuit board (PCB). This is the base for my entire circuit to be on and will give an impression as to the size of my overall product. To design the PCB I used a piece of software on the computer called “PCBwiz.” As with any circuit I began by creating a power source (fig1) (this can be moved at later times to shrink the PCB if necessary). Due to the fact I am using a 9V battery to supply my PIC processing unit (which requires a steady 5V supply) I will have to include a voltage regulator within my power source which will lower the supply to a steady 5V. to connect the battery into the circuit I am using a terminal block (T1) mounted on the PCB in which I will connect a “battery snap” to provide power to the circuit. The positive volts from the battery will be fed through a diode (D1) into the voltage regulator (VR1). In order for the voltage regulator to function it requires two 10µF capacitors (C1 and C2) connecting both of its outer pins to 0V (on my circuit board this is direct to the 0V side of my batteries terminal block, however this can be done at any point on the 0V rail). After I had designed my power source I decided my next step would be to connect my PIC to the power and to the LED display (fig2). For my LEDs I am using 7 terminal blocks (T2-8) conne- cted to the PIC through 14 pins of a 220Ω resistor array, the 0V legs of the LED terminal blocks are connected together and then to the 0V supply from the battery to save space on the PCB, the outputs for the 7 LEDs are outputs 0-6, or pins 6-12. Pin 5 of the PIC is connected directly to 0V while pin 14 is connected directly to +V and then to 0V by a 10µF ceramic capacitor (C2). Finally pin 4 on the PIC (reset) is connected to +V through a 10kΩ resistor (R1) and then to 0V through a Push To Make switch (PTM) that is connected by a ninth terminal block (T9). After this had been completed, the next step was to connect my PIC to the rotary switch to determine the limits of the analogue signal produced by the temperature and to the potential divider providing the analogue signal for processing (fig3). the rotary switch is connected by using three terminal block (T10-12) in a ┴ shaped pattern, the topmost connection will be the common connection while the other 5 connections will be normal poles of the switch. each connection of the switch is connected to 0V through a 10kΩ resistor (R2-6) and directly to the input pins of the PIC (pins1-3 + 15-16 or digital inputs0-4). The potential divider is connected to pin 17 (analogue input0) of the PIC, with the negative coefficient thermistor, connected using a terminal block (T13) connected to +V and the 10kΩ resistor (R7) connected to the bottoms of two other 10kΩ resistors (from the rotary switch) then to 0V through a 0Ω resistor (R8). D2 My next, and final, step is to add the relay switch (RLY1) to the PIC and the power supply. On the relay there are 5 pins normally open (No), normally closed (Nc), common (Co) and the two power pins (+V and 0V). Pin +V is connected to the +V supply and has a diode (D2)(polarised against the +V supply) to prevent the relay from blowing, the 0V pin is connected to the collector of a high gain tran- sistor (TR1). The base pin of the transistor is connected to pin 13 (output7) of the PIC through a 1KΩ resistor (R9) which acts to protect the transistor, the emitter pin of the transistor is connected directly to 0V. For the switching pins of the relay I have connected pin Co to a leg of a terminal block (T14), pin No to the other leg of the same terminal block and finally pin Nc is connected directly to 0V. This layout causes the heater attached to the terminal block to receive voltage from its supply when the relay is activated, however when the relay is closed, nothing will occur as there is no connection between the two pins of the terminal block. I am now left with a complete circuit on the PCB, however with too many white gaps a lot of copper would be wasted, so my next job is to “block in” the circuit to save on the cost of copper. while blocking my circuit I noticed a gap between my thermistor’s terminal block and the positive volt rail, this would cause a major problem in my circuit, however it is easily fixed during designing, to fix this problem I simply blocked over the gap making the connection in that way. in addition to blocking I also placed my initials onto the circuit for identification reasons. I am now left with a complete circuit board PCB wasting as little copper as is possible given the size of my circuit.(fig6) No VR1 +V C1 Co R1 C2 Nc T14 0V T1 R8 fig1 C3 R9 TR1 R1 DIL2 C3 T9 fig2 T2 T3 DIL2 T4 T7 T6 T5 T5 T11 R3 T10 T12 R7 R6 R4 R5 R5 R8 R1 T9 C3 fig3 Now that I have completed my PCB I am finished designing and can move on to development and manufacturing.

Materials and processes. 22 Manufacture plan. Tasks. Time required for task. Materials and processes. Health and safety. Quality control. Final checks of the PCB design on a computer prior to printing design onto an acetate sheet. Computer PCB software. N/A Receive supervisors appreciation of the PCB design. Printout PCB design onto acetate sheet. PCB software Acetate sheet Printer and ink Low amounts if any. Check the quality of the printout is acceptable, with no smudges or unwanted gaps. Develop PCB within UV box. UV box Cut to size photo etch board Acetate. UV light so minimise exposure, and 240V equipment. Develop for the appropriate time. (ask supervisor if unsure) Etch PCB in chemical bath. Chemical bath Developing solution Developed PCB Corrosive acid is being used so protective guards must be used. Use of the correct concentration of acid and etch for the correct amount of time (see supervisor for values) Drilling holes for components. Pillar drill PCB Drill bits Use a drill guard Wear safety goggles Tie hair back with bobble Ensure to take time while drilling to increase accuracy of drilling, ensure use of correct size drill bit and check drill holes after. Clean with steel wool. Steel wool Wear goggles at all times. Solder in components. Components Soldering equipment Flux Be careful to avoid touching iron. Always replace iron in holder. Use flux to assist soldering. Use correct solder amount Try not to burn components. Solder and attach flying leads Multi-core wire Screwdriver Use “helping hands” Wear goggles at all times Avoid touching iron Always return iron to holder Use shrink-wrap tubing to insulate. Programme PIC PIC programming software PIC programmer PIC Snagging. Multimeter. Signal probe Repair equipment. Battery. This is all Quality control.

23 Product Development. Firstly I needed to check my PCB design for any flaws, this is just quality control of my product, ensuring that it works and functions adequately. After this was completed (and double checked by my supervisor) the next step was to print my design onto a sheet of transparent acetate. This printout would be the basis of etching my circuit board. In order to etch my PCB I had to place the acetate sheet on top of a photo-etch board, then add both pieces into a UV light box for approximately 2-3 minutes to develop parts of the board. After development in a UV box I placed the photo-etch board in developing solution to prime the photo-etch board for etching in an acid tank. After priming the board I placed the photo-etch board into the acid bath, this would remove all UV-treated copper from the board. (takes approximately 20mins) While the board was etching I connected the loose components (LEDs, battery snaps and switches) to flying leads. I am now left with a completely etched PCB, after washing all acid off the board the next step is to solder in the components, as in case of mistakes its easier to start smallest first, the first thing I soldered in was the resistors, directly mounted onto the PCB board. The next components that required soldering were the DIL holders and the capacitors, no chips are added to the circuit at this point to help avoid any heat damage. After soldering in the DIL holders I inserted my PIC and my resistor array into their respective holders. After I have soldered all my DIL holders and capacitors in the penultimate components left to solder are the terminal blocks, when soldering these in I noticed I had left too small a gap for them to fit in, this however was simple to fix my filing down the wide back of certain ones. The final thing to solder to my circuit board is the relay, this is mounted onto my PCB directly. Now I had completed my soldering I attached my flying leads to their respective terminal blocks and my circuit was complete. Snagging. However my circuit had a few flaws in its design, I had placed several tracks too close to pads and during etching this had left a short circuit, this was easy to fix however by scoring through the copper using a scribe. I had also soldered in my transistor the wrong way and the diode above the relay was in back-to-front causing a short circuit, this meant I had to de-solder and then re-solder both components, this was highly time consuming. After fixing these minor issues I had a fully operational circuit board, the programme used (left) was mildly complex and took a while to configure..