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floriculture

Floriculture is the cultivation and management of flowers and ornamental plants. It involves growing bedding plants, houseplants, cut flowers, and more for gardens, landscaping, and floral arrangements. Floriculture is an important industry both economically and aesthetically. It generates income, employment opportunities, and adds beauty to our surroundings. Globally, the ornamental crop industry is worth over $70 billion annually, with over three lakh hectares of land under flower production worldwide. India has suitable agroclimatic conditions for growing many commercial flowers.

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1 CONTENTS 1. FLORICULTURE – INTRODUCTION, IMPORTANCE 2. FLORICULTURE POTENTIAL AND ITS TRADE IN INDIA 3 .GREEN HOUSE 4. POLYHOUSE 5. SHADENET 6. MICROIRRIGATION SYSTEM 7. MIST PROPAGATING UNIT 8. BIBLIOGRAPHY
2 Floriculture,or flower farming, is a discipline of horticulture concerned with the cultivation of flowering and ornamental plants for gardens and for floristry, comprising the floral industry. The development, via plant breeding, of new varieties is a major occupation of floriculturists. Floriculture crops include bedding plants, houseplants, flowering garden and pot plants, cut cultivated greens, and cut flowers. As distinguished from nursery crops, floriculture crops are generally herbaceous. Bedding and garden plants consist of young flowering plants (annuals and perennials) and vegetable plants. They are grown in cell packs (in flats or trays), in pots, or in hanging baskets, usually inside a controlled environment, and sold largely for gardens and landscaping. Flowering plants are largely sold in pots for indoor use. The major flowering plants are poinsettias, orchids, florist chrysanthemums. Foliage plants are also sold in pots and hanging baskets for indoor and patio use, including larger specimens for office, hotel, and restaurant interiors. Cut flowers are usually sold in bunches or as bouquets with cut foliage. The production of cut flowers is specifically known as the cut flower industry. Farming flowers and foliage employs special aspects of floriculture, such as spacing, training and pruning plants for optimal flower harvest; and post-harvest treatment such as chemical treatments, storage, preservation and packaging. Floriculture may be defined as the branch of Horticulture which deals with the culture and management of flowers and ornamental plants. – It has been derived from two words ‘flor’ means flower and ‘cultura’ means cultivation. – But now in addition to flower other ornamental plants are also included in floriculture. Importance of Floriculture – As Floriculture deals with the culture of flowers and ornamental plants, it has great importance in our daily life as well as national economy.
3 -General importance of flower  Flowers help getting out of illness through psychological enchantment.  Flower gardens increase beauty of the house or an institution.  Scent and perfumes are extracted from the fragrance of flowers e.g., Rose water, Atar.  It is the source of incentive to the poets and writers.  Flower is a national symbol. Lotus is the national flower of India.  Flower increases the aesthetic sense of human being and satisfies demand of heart feelings.  Its beauty and fragrance give happiness to all irrespective of age and wealth.  It is the principal component of public functions and anniversaries and also extensively used for decoration.  Flower gardening is a good medium of passing leisure time and help keeping good health. -Economic importance of flower production  Perfume industries can be established in the country which can help improving national economy.  Flowers can be a source of earning huge foreign currency by exporting them.  Flowers can be considered as a commercial commodity. Commercial flower production may be helpful in increased earning of the grower.  Establishment of flower production farms and perfume industries can help solving unemployment problem to a large extent.  It provides scope to bring more unused land under flower cultivation. Scope of flower cultivation  Potted foliage and flowering plants are less perishable and has advantage over cut flowers. As most of the important foliage and flowering plants are native to the tropical region.  The agro climatic condition is well suited for growing many flowers and foliage plants in India.  Bonsai culture is a recent development in the field of floriculture . In bonsai culture a large tree is transformed into a miniature form giving a lucrative look. Such plants have heavy demand in the society though
4 they are expensive. To meet up local demand and for export many bonsai making farms can be established.  Cactus is a high valued ornamental crop sold in plant nurseries and shops. Some progressive nurserymen and amateurs are trying to make special types of plants like grafted cactus and bonsai in small scale. This gives a hope for trade in Floriculture.  Tissue culture technology can be exploited for developing quality seedling in many flower spp. in order to get local as well as international market.  There is a high demand of fresh flower and pot plants in the market. As such those flowers suitable for export such as rose, gladiolus, gerbera, tuberose, marigold, orchid etc. can easily be produced for this purpose. CHALLENGES - Growers face many challenges including: Declining margins – While prices have remained steady over the past several years, most input costs have risen steadily. To remain profitable, growers have had to become more efficient in production and management. Environment – Environmental issues are a major concern for growers. Growers have responded by re-using irrigation water, reducing pesticide and fertilizer use and reducing greenhouse runoff. Pest control – Concerns over pesticide use by the public and producers alike, along with pesticide resistance and the loss of approved pesticides, have prompted growers to adopt alternative pest control methods. Integrated pest management (IPM) is playing a larger role in greenhouse pest control. Many growers are now using biological or bio-rational control methods to supplement or replace existing pesticides. Employment – Labor is an important element in production. Bedding plant and cut flower growers face labor costs of up to one third of gross sales. Although increased mechanization is a necessary element of global competition, the industry continues to be a major agricultural employer. Urban-rural conflicts – Urban-rural conflicts are a fact of life for most agriculture in the Province. Some municipalities look upon floriculture
5 as more of a factory production industry rather than agriculture. Most municipalities have zoning regulations concerning the maximum site covering greenhouses. Capital costs – Modern, state-of-the-art greenhouse operations can cost up to $200 per square metre. This represents a barrier to entry for many potential growers. Field-grown cut flowers and bedding plant production have much lower capital costs, so they are often entry level crops. Seasonal demand – The demand for fresh floriculture products is seasonal and the product is very perishable. Large numbers of people want to buy flowers for special occasions or holidays like Valentine’s Day, Mother’s Day and Christmas. Growers must time their production to meet these periods of high demand. Some growers have 30% of their annual sales in a three week period in spring. IMPORTANCE OF FLORICULTURE  Besides food and nutritional security, the aesthetic value is also equally important for our daily lively hood as well as for environmental purity. Floriculture is important from the following point of view; 1. Economic point of view 2. Aesthetic point of view 3. Social point of view 1. Economic point of view:  Floriculture is a fast emerging major venture in the world, especially as a potential money-spinner for many third-world countries.  Many flowers and ornamental plants are being grown for domestic as well as for export will provide more return/unit area than any other agricultural/horticultural crops.  For example in markets such as Delhi and Mumbai and other metros a single spike of gladiolus and gerbera flower may
6 sell up to Rs. 3-5 in Kharif and Rs. 5-10/spike in Rabi/Summer.  Gestation period of flower crop is very less compared to other crops.  Modern-day floriculture refers to the production of high- value cut flowers such as Rose, Gladiolus, Carnation, Orchids, Tuberose, Anthurium, Lilium, Gerbera etc,.  Now days, growing of these cut flower crops, suited for flower arrangements/decorations for bouquets preparation, and for floral boskets, have increased substantially and its share of the total trade has also improved.  The sales of loose flowers of Jasmine, Crossandra, Marigold, China Aster, Chrysanthemums and Gaillardia etc are a roaring busyness in south India.  The present trend in floriculture is for making dry flowers, extraction of natural colors and essential oils.  At present the global ornamental crop industry is worth about US$ 70 billion.  The global consumption of the flowers is about US$ 35 billion.  More than three lakhs hectare are under flower production in different countries of the world. 1. Floriculture generates self employment opportunities round the year. 2. One can join the floriculture field as farm/estate managers, plantation experts, supervisors and project coordinators etc. 3. Research and teaching are some other avenues of employment in the field. 4. Marketing of Floriculture products for different ventures is emerging as a potential segment of this field. 5. Besides one can work as consultant, landscape architect etc with proper training.
7 6. One can also work as entrepreneur and offer employment to others. 7. In addition to these careers which involve research and actual growing of crops. 8. Floriculture also provides service career opportunities which include such jobs as floral designers, groundskeepers, landscape designers, architects and horticultural therapists. 9. Professional qualification combined with an inclination towards gardening and such other activities produces efficient floriculturists and landscaping professionals.  Presently more than 145 countries are involved in flower production on commercial scale. 2. Aesthetic point of view:  Lot of scope for landscaping and is considered as billion dollar earning industry in states which ultimately adds the monitory value of any building.  To a Japanese flower arranger each flower expresses one or more meaning (e.g. Ikebana).  Open breathing places through bio-aesthetic planning and landscape gardening, can expect to build up a healthy society and prosperous nation.  Horticultural therapy - is the new dimension of horticultural science to heal the psychic debility and the science is to use garden, landscape plants, parts of plants, growing activity as tools to work.  The bio-force of plants offer a permanent solution to the problems of bio force of human thus, bio aesthetic horticulture is emerging as a new occupational therapeutic tool to restore the lost rhythm and harmony back to human self or inner environment.
8  It is being utilized in psychiatric hospital, general hospitals, physical rehabilitation center, homes for elderly, prisons and schools.  The patients can achieve higher level of personal development and satisfaction. 3. Social point of view:  Flowers symbolize the purity, beauty, peace, love, adoration, innocence and passion etc., are used to express feelings.  In our society no social function is complete without the use of flowers.  In India, especially for Hindu’s, there’s greater significance in religions offerings. It has estimated that more than 30-40 % of the total flower productions are being consumed in Kolkata city alone used for worshiping purpose.  Floral garlands, gajras are required in marriage ceremonies for adornment of hairs by women of all ages.  In the present modern era sicks are wished, while the deads are bidden farewell with flowers. FLORICULTURE AND INDIA Floriculture is increasingly regarded as a viable diversification from the traditional field crops due to increased per unit returns and the increasing habit of “saying it with flower” during all the occasions. Though the art of growing flowers is not new to India, protected cultivation in poly- houses is relatively new in India. Enormous genetic diversity, varied agro climatic conditions and versatile human resources offer India a unique scope for diversification into new avenues which have not been explored to a greater extent. With the opening up of world market in the WTO regime, there is a free movement of floriculture products worldwide. In this context, each and every country has equal opportunity for trade in each other’s territory. Globally, more than 140 countries are involved in cultivation of floricultural crops. The USA continues to be
9 the highest consumer with more than $ 10 billion per annum, followed by Japan with more than $ 7 billion. India has better scope in the future as there is a shift in trend towards tropical flowers and this can be gainfully exploited by India with enormous amount of diversity in indigenous flora. Indian Council of Agriculture Research (ICAR) conducted a survey of assessment on the possibilities of cut flowers trade in India during 1960- 62. An important conclusion was that an internal sale as Rs.9.26 crores worth flower weighing 10,460 tons grown in an area of 4000 hectors. Flowers like Rose, Gladiolus, Tuberose, Chrysanthemum, Aster, Carnation, Orchids, and Marigold are most popular in cut flower market all over the World. Flower Trade Across The World: World trade on floriculture produces like cut flowers, ornamental plants, flowering plants, flower seeds and plantlets gaining tremendous momentum. Many countries, particularly the developed ones, are importing flowers to meet their internal demand. It will be worthwhile to mention that the annual import figures of some of the largest importers on flowers – USA (232 crores US$) Japan (192 crores US$), Germany (180 crores US$) France (77 Crores US$), Italy (55.6 Crores US$), Holland (50 Crores US$). The other importers like Switzerland, Sweden, Denmark, Belgium, Middle-east countries etc. also import a sizable amount of cut flowers. In recent past, growers of flowers are using modern agro-techniques like glass-house culture, drip irrigation, liquid pesticides & fertilizers application along with drip irrigation channels, Tissue Culture. Vis-a-vis such a huge market potential of floriculture produce, India’s contribution is not at all encouraging as its flower export amount to 30 lakh US dollar only, hence India has to do a lot to exploit this agro-business.
10 GREEN HOUSE A greenhouse (also called a 'glasshouse', or, if with sufficient heating, a hothouse) is a structure with walls and roof made chiefly of transparent material, such as glass, in which plants requiring regulated climatic conditions are grown. These structures range in size from small sheds to industrial-sized buildings. A miniature greenhouse is known as a cold frame. The interior of a greenhouse exposed to sunlight becomes significantly warmer than the external ambient temperature, protecting its contents in cold weather. Many commercial glass greenhouses or hothouses are high tech production facilities for vegetables or flowers. The glass greenhouses are filled with equipment including screening installations, heating, cooling, lighting, and may be controlled by a computer to optimize conditions for plant growth. Different techniques are then used to evaluate optimality-degrees and comfort ratio of greenhouse micro- climate (i.e., air temperature, relative humidity and vapor pressure deficit) in order to reduce production risk prior to cultivation of a specific crop. DESIGN The explanation given in most sources for the warmer temperature in a greenhouse is that incident solar radiation (the visible and adjacent portions of the infrared and ultraviolet ranges of the spectrum) passes through the glass roof and walls and is absorbed by the floor, earth, and contents, which become warmer and re-emit the energy as longer- wavelength infrared radiation. Glass and other materials used for greenhouse walls do not transmit infrared radiation, so the infrared cannot escape via radiative transfer. As the structure is not open to the atmosphere, heat also cannot escape via convection, so the temperature inside the greenhouse rises. This is known as the "greenhouse effect". Ventilation Ventilation is one of the most important components in a successful greenhouse, especially in hot and humid tropical climate condition. If
11 there is no proper ventilation, greenhouses and their growing plants can become prone to problems. The main purposes of ventilation are to regulate the temperature, humidity and vapor pressure deficit to the optimal level, and to ensure movement of air and thus prevent build-up of plant pathogens (such as Botrytis cinerea) that prefer still air conditions. Ventilation also ensures a supply of fresh air for photosynthesis and plant respiration, and may enable important pollinators to access the greenhouse crop. Ventilation can be achieved via use of vents - often controlled automatically via a computer - and recirculation fans. Heating Heating or electricity is one of the most considerable costs in the operation of greenhouses across the globe, especially in colder climates. The main problem with heating a greenhouse as opposed to a building that has solid opaque walls is the amount of heat lost through the greenhouse covering. Since the coverings need to allow light to filter into the structure, they conversely cannot insulate very well. Most greenhouses, when supplemental heat is needed use natural gas or electric furnaces. Passive heating methods exist which seek heat using low energy input. Solar energy can be captured from periods of relative abundance (day time/summer), and released to boost the temperature during cooler periods (night time/winter). Electronic controllers are often used to monitor the temperature and adjusts the furnace operation to the conditions. This can be as simple as a basic thermostat, but can be more complicated in larger greenhouse operations. Carbon dioxide enrichment The possibility of using carbon dioxide enrichment in greenhouse cultivation to enhance plant growth has been known for nearly 100 years. After the development of equipment for the controlled serial enrichment of carbon dioxide, the technique was established on a broad scale in the Netherlands. Commercial greenhouses are now frequently located near appropriate industrial facilities for mutual benefit
12 consuming both waste heat and CO2 from the refinery which would otherwise be vented to atmosphere TYPES In domestic greenhouses, the glass used is typically 3mm 'horticultural glass' grade, which is good quality glass that should not contain air bubbles (which can produce scorching on leaves by acting like lenses). Plastics mostly used are polyethylene film and multiwall sheets of polycarbonate material, or PMMA acrylic glass. Commercial glass greenhouses are often high-tech production facilities for vegetables or flowers. The glass greenhouses are filled with equipment such as screening installations, heating, cooling and lighting, and may be automatically controlled by a computer. Dutch Light Green House In the UK and other Northern European countries a pane of horticultural glass referred to as "Dutch Light" was historically used as a standard unit of construction, having dimensions of 28¾″ x 56″ (approx. 730mm x 1422 mm). This size gives a larger glazed area when compared with using smaller panes such as the 600mm width typically used in modern domestic designs which then require more supporting framework for a given overall greenhouse size. A style of greenhouse having sloped sides (resulting in a wider base than at eaves height) and using these panes uncut is also often referred to as of "Dutch Light design", and a cold frame using a full- or half-pane as being of "Dutch" or "half-Dutch" size. LEAN -TO GREENHOUSE: Less expensive than freestanding models and a good option where space is limited, the attached lean-to greenhouse shares one wall with a house, garage or other building. Lean- to greenhouse have available utility sources nearby and are cheaper to operate than full-size greenhouses. Besides providing more usable space, it has a superior shape for air circulation. FREE STANDING GREENHOUSE: They are separate structures. They allow many size options, and provision must be made for heat, water and electricity. Larger greenhouses are actually more easily
13 managed, because small greenhouses have more rapidly fluctuating temperatures. Several common frames are the quonset, a low, circular shape usually covered with plastic sheeting; the gothic, similar to the quonset but with a higher arch; the rigid-frame, with vertical sidewalls and rafters; and the A-frame, with sloping sides forming a triangular shape. USES Greenhouses allow for greater control over the growing environment of plants. Depending upon the technical specification of a greenhouse, key factors which may be controlled include temperature, levels of light and shade, irrigation, fertilizer application, and atmospheric humidity. Greenhouses may be used to overcome shortcomings in the growing qualities of a piece of land, such as a short growing season or poor light levels, and they can thereby improve food production in marginal environments. Greenhouses in hot, dry climates used specifically to provide shade are sometimes called "shade houses". As they may enable certain crops to be grown throughout the year, greenhouses are increasingly important in the food supply of high- latitude countries. One of the largest complexes in the world is in Almeria, Andalucía, Spain, where greenhouses cover almost 200 km2 (49,000 acres). Greenhouses are often used for growing flowers, vegetables, fruits, and transplants. Special greenhouse varieties of certain crops, such as tomatoes, are generally used for commercial production. Many vegetables and flowers can be grown in greenhouses in late winter and early spring, and then transplanted outside as the weather warms. Bumblebees are the pollinators of choice for most pollination, although other types of bees have been used, as well as artificial pollination. Hydroponics can be used to make the most use of the interior space. The relatively closed environment of a greenhouse has its own unique management requirements, compared with outdoor production.
14 POLYHOUSE A polytunnel (also known as a polyhouse, hoop greenhouse or hoop house, grow tunnel or high tunnel) is a tunnel typically made from z35 Steel and covered in polythene, usually semi-circular, square or elongated in shape. The interior heats up because incoming solar radiation from the sun warms plants, soil, and other things inside the building faster than heat can escape the structure. Air warmed by the heat from hot interior surfaces is retained in the building by the roof and wall. Temperature, humidity and ventilation can be controlled by equipment fixed in the polytunnel or by manual opening and closing of vents. Poly-tunnels are mainly used in temperate regions in similar ways to glass greenhouses and row covers. The nesting of row covers and low tunnels inside high tunnels is also common. USES: Poly-tunnels can be used to provide a higher temperature and/or humidity than that which is available in the environment but can also protect crops from intense heat, bright sunlight, winds, hailstones, and cold waves. This allows fruits and vegetables to be grown at times usually considered off season; market gardeners commonly use poly- tunnels for season extension. Beyond season extension, poly-tunnels are also used to allow cold-hardy crops to overwinter in regions where their hardiness isn't quite strong enough for them to survive outdoors. Temperature increases of only 5° to 15° above outdoor ambient, coupled with protection from the drying effect of wind, are enough to let selected plant varieties grow slowly but healthily instead of dying. The effect is to simulate "moving the farm south by several hardiness zones", that is, to create a microclimate that simulates the temperatures of a location several hardiness zones south (and protects from wind as well). Every factor influencing a crop can be controlled in a polytunnel. Poly- tunnels are often used in floriculture and plant nurseries, as the revenue value of the plants can justify the expense.
15 SHADE NET Agro shade net is a simple yet powerful innovation that helps protect crops, used to provide the crops with a shade from the sunrays. Though sunrays are the major requirement for the growth of plants and crops, yet it has been seen and recorded that over-exposure to sun rays can lead to much damage to the crops. This happens because certain crops and plants are extremely fragile. They do not require too much of sun exposure. Moreover, there are certain geographical locations which are more prone to harsh sun rays than other places. In these places, the cultivation of many crops is unfeasible. To cultivate fragile plants, one must take care of the crops well. The agro shade net is one such way to protect the crops. They are a very real and cost effective way to control the ill effects of UV radiations on plants and crops, extremely useful in protected cultivation of high value crops. Especially for high value crops, where no risk can be taken by the farmers or cultivators, it is very important of take optimum care of the crops and make sure that they are protected against the vagaries of nature. With innovation in this field, now shade nets can successfully control the harmful effects of UV rays on plants and keep them safe and sound. Shade Selection: A good shade net must have high strength and should be durable. This will ensure that it will not wear out soon and will last you several crop lives. The biggest benefit and feature is the UV stabilization feature that will ultimately protect the crops against the harmful effects of UV radiations. A good shade net must offer optimum shade factor that protects the crops well. The shade net must be technically designed for higher yield. MICRO-IRRIGATION SYSTEM Micro-irrigation or trickle irrigation is an irrigation method with lower pressure and flow than a traditional sprinkler system. Low volume irrigation is used in agriculture for row crops, orchards, and vineyards. It is also used in horticulture in wholesale nurseries, in landscaping for civic, commercial, and private landscapes and gardens, and in the
16 science and practice of restoration ecology and environmental remediation. There are several types of micro-irrigation systems. Many of the components are the same for all of these types of systems. Most systems typically include filters, pipes, valves, and tubing. The main difference is in the type of emission device that is used to deliver the water to the plants. Drip irrigation utilizes drip emitters that deliver water at very low rates. The typical range is 0.2 to 4.0 gallons per hour. In some systems, the emitters are installed manually on the outside of the tubing and placed where needed. Other systems might use integral dripper line or drip tape with the emitters already installed at a predetermined spacing. Micro-sprinklers, which can include fixed stream sprays and rotating spinners typically deliver water at a higher rate, such as 10 to 25 gallons per hour and will cover a larger area than drip emitters. These are more typically used in tree orchards where the plants are larger. The goal is to distribute water slowly in small volumes and target it to plants' root zones with less runoff or overspray than landscape and garden conventional spray and rotary sprinklers. The low volume allows the water to penetrate and be absorbed into slow- percolation soils, such as clay, minimizing water runoff. System components: There is a wide variety of system components included in a micro-irrigation system. Most systems include a filter. These may include pre-filters, sand separators, media filters, screen filters, and disc filters. The level of filtration required depends on the size of the emission device and the quality of the water source. A pressure regulator or regulating valve may be required to reduce the system pressure to the desired level. Automatic or manually operated valves will be required to switch from one irrigated section to another. An irrigation controller will be used with automatic systems and may also be needed for back flushing the filter or sand separator. Emission devices: Micro tubing consists of very small diameter tubing. Flow is regulated purely by the length and diameter of the tubing.
17 Fixed flow drip emitter: Low-flow irrigation systems in gardens using drip apply water through two methods:  pre installed small holes in small diameter tubes placed on or below the surface or  Self cleaning emitters, in different precipitation rates, pre installed or contractor installed for different rate emitters on same supply. Low volume irrigation systems often use the two delivery components of drip systems to apply water through small holes in small diameter tubes placed on or below the surface of the field. This is done instead of agricultural surface irrigation and furrow irrigation for vegetables, fruits and berries, and other high-value crops. Adjustable drip emitters Trickle emitters, also called 'spider sprays,' come in fixed or adjustable radius shapes and diameters, and are installed directly on the flexible supply pipe or on tubing connected to it, and mounted on small stakes. Trickle emitter-'Spider sprays' work well for plants with more fibrous root systems, tree and large shrub basins, and in pots and container gardens - allowing automated watering of plants on decks and patios. Mist emitters can also be used in pot, both on the ground and hanging, with humidity-fog watering for epiphytes and ferns replicating habitats. Micro-sprinklers: Low volume micro-sprinklers may be attached to hard plastic risers or attached to standard sprinkler heads, but are more typically mounted on stakes and attached to small diameter micro-tubing connected to polyethylene tubing with a barbed connector. Some micro- sprinklers have a fixed spray or stream pattern, while others rotate. These are installed above ground and are often used for fruit and nut orchards and vineyards. These systems are expensive, even for large- scale agricultural use, and are predominantly used for high-value crops.
18 MIST PROPAGATINGUNIT Mist Propagation of Herbaceous and Softwood Cutting: Mist propagation consists of maintaining a film of water on the leaves of the cutting and relative humidity of the ambient air. In this way, the rate of transpiration is reduced to a minimum and as result the guard cells remain turgid. The stomata’s remain open, and the manufacture of carbohydrates and related substances proceeds unabated even in presence of high light intensity. Further, with the high light intensity, the evaporation of water from the leaves keep the tops relativity cool, and this in turn lowers the rate of respiration. Thus, with the low rate of transpiration combines with the low rate of respiration, other manufactured substances become available for the initiation and growth of the root system. There are Two Kinds or Types of Misting: i) Continuous and ii) Intermittent. The continuous involve applying the mist continuously during the light period, whereas the intermittent system involves applying the mist at definite intervals during the light period. Each system has advantages and disadvantages. Continuous has disadvantage that excessive leaching of soluble compounds from the leaves is likely to take place and unless the media is well drained, water logging of the media is likely to occur. The main advantages of the intermittent system are that excessive leaching of soluble compounds from the leaves and water lagging of the media is likely to occur. The main advantages of the intermittent system is that excessive leaching of soluble compounds from the leaves and water logging of the media is not take place. In general, five system have been development to control the misting cycle of the intermittent system. Of these five systems, three are used in
19 commercial installations. These are 1) misting cycle time clock, 2) electronic leaf, and 3) Mistomatic, the electric time clock consist of a day night clock and a misting cycle clock connected with a solenoid valve. The day night clock turns on the system in the morning, usually just after sunrise, and off in the evening, usually just after sunset, the misting cycle clock turns the system on and off for definite intervals during the day, for ex, a commonly used misting cycle is one minute with the clock set to mist the cutting for three, four, or five or more seconds per minute. The main advantages of this system are that it has a relatively low installation and maintenances cost. Its main disadvantages are that manual operations required to change the misting cycle. The electronic leaf consists of a piece of plastic with two electrodes and a control unit connected to a solenoid valve. It is based on the assumption of evaporation of water from the leaves. Thus, the main advantage of this system is that the period of misting varies with the rate of evaporation and transpiration of waster from the leaves, which varies according to temperature and light intensity. The Mistomatic system consists of a small stainless steel or grid and a control unit connected to a solenoid valve. Here again, this system operates on the assumption that the rate of evaporation of water from the screen or grid is practically the same as the rate of transpiration and evaporation of water from the leaves. The operation of the Mistomatic system is similar to that of the electronic leaf system, and its main advantages and disadvantages are practically the same. …………………*………………………..*…………………………..
20 Reference Homeguides.sfgate.com, www.dpi.nsw.gov.au https://en.wikipedia.org/wiki/greenhouse ecourse.iasr.res.in , www.biologydiscussion.com floriculture-india.blogspot.in , www.agrinfo.in My Agriculture information bank ,www.quora.com Jugraphia.wordpress.com , www.agrislide.com Common core, Unified botany IV Date of submission: 3rd Oct ‘17 Marks allotted:

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floriculture

  • 1.
    1 CONTENTS 1. FLORICULTURE –INTRODUCTION, IMPORTANCE 2. FLORICULTURE POTENTIAL AND ITS TRADE IN INDIA 3 .GREEN HOUSE 4. POLYHOUSE 5. SHADENET 6. MICROIRRIGATION SYSTEM 7. MIST PROPAGATING UNIT 8. BIBLIOGRAPHY
  • 2.
    2 Floriculture,or flower farming,is a discipline of horticulture concerned with the cultivation of flowering and ornamental plants for gardens and for floristry, comprising the floral industry. The development, via plant breeding, of new varieties is a major occupation of floriculturists. Floriculture crops include bedding plants, houseplants, flowering garden and pot plants, cut cultivated greens, and cut flowers. As distinguished from nursery crops, floriculture crops are generally herbaceous. Bedding and garden plants consist of young flowering plants (annuals and perennials) and vegetable plants. They are grown in cell packs (in flats or trays), in pots, or in hanging baskets, usually inside a controlled environment, and sold largely for gardens and landscaping. Flowering plants are largely sold in pots for indoor use. The major flowering plants are poinsettias, orchids, florist chrysanthemums. Foliage plants are also sold in pots and hanging baskets for indoor and patio use, including larger specimens for office, hotel, and restaurant interiors. Cut flowers are usually sold in bunches or as bouquets with cut foliage. The production of cut flowers is specifically known as the cut flower industry. Farming flowers and foliage employs special aspects of floriculture, such as spacing, training and pruning plants for optimal flower harvest; and post-harvest treatment such as chemical treatments, storage, preservation and packaging. Floriculture may be defined as the branch of Horticulture which deals with the culture and management of flowers and ornamental plants. – It has been derived from two words ‘flor’ means flower and ‘cultura’ means cultivation. – But now in addition to flower other ornamental plants are also included in floriculture. Importance of Floriculture – As Floriculture deals with the culture of flowers and ornamental plants, it has great importance in our daily life as well as national economy.
  • 3.
    3 -General importance offlower  Flowers help getting out of illness through psychological enchantment.  Flower gardens increase beauty of the house or an institution.  Scent and perfumes are extracted from the fragrance of flowers e.g., Rose water, Atar.  It is the source of incentive to the poets and writers.  Flower is a national symbol. Lotus is the national flower of India.  Flower increases the aesthetic sense of human being and satisfies demand of heart feelings.  Its beauty and fragrance give happiness to all irrespective of age and wealth.  It is the principal component of public functions and anniversaries and also extensively used for decoration.  Flower gardening is a good medium of passing leisure time and help keeping good health. -Economic importance of flower production  Perfume industries can be established in the country which can help improving national economy.  Flowers can be a source of earning huge foreign currency by exporting them.  Flowers can be considered as a commercial commodity. Commercial flower production may be helpful in increased earning of the grower.  Establishment of flower production farms and perfume industries can help solving unemployment problem to a large extent.  It provides scope to bring more unused land under flower cultivation. Scope of flower cultivation  Potted foliage and flowering plants are less perishable and has advantage over cut flowers. As most of the important foliage and flowering plants are native to the tropical region.  The agro climatic condition is well suited for growing many flowers and foliage plants in India.  Bonsai culture is a recent development in the field of floriculture . In bonsai culture a large tree is transformed into a miniature form giving a lucrative look. Such plants have heavy demand in the society though
  • 4.
    4 they are expensive.To meet up local demand and for export many bonsai making farms can be established.  Cactus is a high valued ornamental crop sold in plant nurseries and shops. Some progressive nurserymen and amateurs are trying to make special types of plants like grafted cactus and bonsai in small scale. This gives a hope for trade in Floriculture.  Tissue culture technology can be exploited for developing quality seedling in many flower spp. in order to get local as well as international market.  There is a high demand of fresh flower and pot plants in the market. As such those flowers suitable for export such as rose, gladiolus, gerbera, tuberose, marigold, orchid etc. can easily be produced for this purpose. CHALLENGES - Growers face many challenges including: Declining margins – While prices have remained steady over the past several years, most input costs have risen steadily. To remain profitable, growers have had to become more efficient in production and management. Environment – Environmental issues are a major concern for growers. Growers have responded by re-using irrigation water, reducing pesticide and fertilizer use and reducing greenhouse runoff. Pest control – Concerns over pesticide use by the public and producers alike, along with pesticide resistance and the loss of approved pesticides, have prompted growers to adopt alternative pest control methods. Integrated pest management (IPM) is playing a larger role in greenhouse pest control. Many growers are now using biological or bio-rational control methods to supplement or replace existing pesticides. Employment – Labor is an important element in production. Bedding plant and cut flower growers face labor costs of up to one third of gross sales. Although increased mechanization is a necessary element of global competition, the industry continues to be a major agricultural employer. Urban-rural conflicts – Urban-rural conflicts are a fact of life for most agriculture in the Province. Some municipalities look upon floriculture
  • 5.
    5 as more ofa factory production industry rather than agriculture. Most municipalities have zoning regulations concerning the maximum site covering greenhouses. Capital costs – Modern, state-of-the-art greenhouse operations can cost up to $200 per square metre. This represents a barrier to entry for many potential growers. Field-grown cut flowers and bedding plant production have much lower capital costs, so they are often entry level crops. Seasonal demand – The demand for fresh floriculture products is seasonal and the product is very perishable. Large numbers of people want to buy flowers for special occasions or holidays like Valentine’s Day, Mother’s Day and Christmas. Growers must time their production to meet these periods of high demand. Some growers have 30% of their annual sales in a three week period in spring. IMPORTANCE OF FLORICULTURE  Besides food and nutritional security, the aesthetic value is also equally important for our daily lively hood as well as for environmental purity. Floriculture is important from the following point of view; 1. Economic point of view 2. Aesthetic point of view 3. Social point of view 1. Economic point of view:  Floriculture is a fast emerging major venture in the world, especially as a potential money-spinner for many third-world countries.  Many flowers and ornamental plants are being grown for domestic as well as for export will provide more return/unit area than any other agricultural/horticultural crops.  For example in markets such as Delhi and Mumbai and other metros a single spike of gladiolus and gerbera flower may
  • 6.
    6 sell up toRs. 3-5 in Kharif and Rs. 5-10/spike in Rabi/Summer.  Gestation period of flower crop is very less compared to other crops.  Modern-day floriculture refers to the production of high- value cut flowers such as Rose, Gladiolus, Carnation, Orchids, Tuberose, Anthurium, Lilium, Gerbera etc,.  Now days, growing of these cut flower crops, suited for flower arrangements/decorations for bouquets preparation, and for floral boskets, have increased substantially and its share of the total trade has also improved.  The sales of loose flowers of Jasmine, Crossandra, Marigold, China Aster, Chrysanthemums and Gaillardia etc are a roaring busyness in south India.  The present trend in floriculture is for making dry flowers, extraction of natural colors and essential oils.  At present the global ornamental crop industry is worth about US$ 70 billion.  The global consumption of the flowers is about US$ 35 billion.  More than three lakhs hectare are under flower production in different countries of the world. 1. Floriculture generates self employment opportunities round the year. 2. One can join the floriculture field as farm/estate managers, plantation experts, supervisors and project coordinators etc. 3. Research and teaching are some other avenues of employment in the field. 4. Marketing of Floriculture products for different ventures is emerging as a potential segment of this field. 5. Besides one can work as consultant, landscape architect etc with proper training.
  • 7.
    7 6. One canalso work as entrepreneur and offer employment to others. 7. In addition to these careers which involve research and actual growing of crops. 8. Floriculture also provides service career opportunities which include such jobs as floral designers, groundskeepers, landscape designers, architects and horticultural therapists. 9. Professional qualification combined with an inclination towards gardening and such other activities produces efficient floriculturists and landscaping professionals.  Presently more than 145 countries are involved in flower production on commercial scale. 2. Aesthetic point of view:  Lot of scope for landscaping and is considered as billion dollar earning industry in states which ultimately adds the monitory value of any building.  To a Japanese flower arranger each flower expresses one or more meaning (e.g. Ikebana).  Open breathing places through bio-aesthetic planning and landscape gardening, can expect to build up a healthy society and prosperous nation.  Horticultural therapy - is the new dimension of horticultural science to heal the psychic debility and the science is to use garden, landscape plants, parts of plants, growing activity as tools to work.  The bio-force of plants offer a permanent solution to the problems of bio force of human thus, bio aesthetic horticulture is emerging as a new occupational therapeutic tool to restore the lost rhythm and harmony back to human self or inner environment.
  • 8.
    8  It isbeing utilized in psychiatric hospital, general hospitals, physical rehabilitation center, homes for elderly, prisons and schools.  The patients can achieve higher level of personal development and satisfaction. 3. Social point of view:  Flowers symbolize the purity, beauty, peace, love, adoration, innocence and passion etc., are used to express feelings.  In our society no social function is complete without the use of flowers.  In India, especially for Hindu’s, there’s greater significance in religions offerings. It has estimated that more than 30-40 % of the total flower productions are being consumed in Kolkata city alone used for worshiping purpose.  Floral garlands, gajras are required in marriage ceremonies for adornment of hairs by women of all ages.  In the present modern era sicks are wished, while the deads are bidden farewell with flowers. FLORICULTURE AND INDIA Floriculture is increasingly regarded as a viable diversification from the traditional field crops due to increased per unit returns and the increasing habit of “saying it with flower” during all the occasions. Though the art of growing flowers is not new to India, protected cultivation in poly- houses is relatively new in India. Enormous genetic diversity, varied agro climatic conditions and versatile human resources offer India a unique scope for diversification into new avenues which have not been explored to a greater extent. With the opening up of world market in the WTO regime, there is a free movement of floriculture products worldwide. In this context, each and every country has equal opportunity for trade in each other’s territory. Globally, more than 140 countries are involved in cultivation of floricultural crops. The USA continues to be
  • 9.
    9 the highest consumerwith more than $ 10 billion per annum, followed by Japan with more than $ 7 billion. India has better scope in the future as there is a shift in trend towards tropical flowers and this can be gainfully exploited by India with enormous amount of diversity in indigenous flora. Indian Council of Agriculture Research (ICAR) conducted a survey of assessment on the possibilities of cut flowers trade in India during 1960- 62. An important conclusion was that an internal sale as Rs.9.26 crores worth flower weighing 10,460 tons grown in an area of 4000 hectors. Flowers like Rose, Gladiolus, Tuberose, Chrysanthemum, Aster, Carnation, Orchids, and Marigold are most popular in cut flower market all over the World. Flower Trade Across The World: World trade on floriculture produces like cut flowers, ornamental plants, flowering plants, flower seeds and plantlets gaining tremendous momentum. Many countries, particularly the developed ones, are importing flowers to meet their internal demand. It will be worthwhile to mention that the annual import figures of some of the largest importers on flowers – USA (232 crores US$) Japan (192 crores US$), Germany (180 crores US$) France (77 Crores US$), Italy (55.6 Crores US$), Holland (50 Crores US$). The other importers like Switzerland, Sweden, Denmark, Belgium, Middle-east countries etc. also import a sizable amount of cut flowers. In recent past, growers of flowers are using modern agro-techniques like glass-house culture, drip irrigation, liquid pesticides & fertilizers application along with drip irrigation channels, Tissue Culture. Vis-a-vis such a huge market potential of floriculture produce, India’s contribution is not at all encouraging as its flower export amount to 30 lakh US dollar only, hence India has to do a lot to exploit this agro-business.
  • 10.
    10 GREEN HOUSE A greenhouse(also called a 'glasshouse', or, if with sufficient heating, a hothouse) is a structure with walls and roof made chiefly of transparent material, such as glass, in which plants requiring regulated climatic conditions are grown. These structures range in size from small sheds to industrial-sized buildings. A miniature greenhouse is known as a cold frame. The interior of a greenhouse exposed to sunlight becomes significantly warmer than the external ambient temperature, protecting its contents in cold weather. Many commercial glass greenhouses or hothouses are high tech production facilities for vegetables or flowers. The glass greenhouses are filled with equipment including screening installations, heating, cooling, lighting, and may be controlled by a computer to optimize conditions for plant growth. Different techniques are then used to evaluate optimality-degrees and comfort ratio of greenhouse micro- climate (i.e., air temperature, relative humidity and vapor pressure deficit) in order to reduce production risk prior to cultivation of a specific crop. DESIGN The explanation given in most sources for the warmer temperature in a greenhouse is that incident solar radiation (the visible and adjacent portions of the infrared and ultraviolet ranges of the spectrum) passes through the glass roof and walls and is absorbed by the floor, earth, and contents, which become warmer and re-emit the energy as longer- wavelength infrared radiation. Glass and other materials used for greenhouse walls do not transmit infrared radiation, so the infrared cannot escape via radiative transfer. As the structure is not open to the atmosphere, heat also cannot escape via convection, so the temperature inside the greenhouse rises. This is known as the "greenhouse effect". Ventilation Ventilation is one of the most important components in a successful greenhouse, especially in hot and humid tropical climate condition. If
  • 11.
    11 there is noproper ventilation, greenhouses and their growing plants can become prone to problems. The main purposes of ventilation are to regulate the temperature, humidity and vapor pressure deficit to the optimal level, and to ensure movement of air and thus prevent build-up of plant pathogens (such as Botrytis cinerea) that prefer still air conditions. Ventilation also ensures a supply of fresh air for photosynthesis and plant respiration, and may enable important pollinators to access the greenhouse crop. Ventilation can be achieved via use of vents - often controlled automatically via a computer - and recirculation fans. Heating Heating or electricity is one of the most considerable costs in the operation of greenhouses across the globe, especially in colder climates. The main problem with heating a greenhouse as opposed to a building that has solid opaque walls is the amount of heat lost through the greenhouse covering. Since the coverings need to allow light to filter into the structure, they conversely cannot insulate very well. Most greenhouses, when supplemental heat is needed use natural gas or electric furnaces. Passive heating methods exist which seek heat using low energy input. Solar energy can be captured from periods of relative abundance (day time/summer), and released to boost the temperature during cooler periods (night time/winter). Electronic controllers are often used to monitor the temperature and adjusts the furnace operation to the conditions. This can be as simple as a basic thermostat, but can be more complicated in larger greenhouse operations. Carbon dioxide enrichment The possibility of using carbon dioxide enrichment in greenhouse cultivation to enhance plant growth has been known for nearly 100 years. After the development of equipment for the controlled serial enrichment of carbon dioxide, the technique was established on a broad scale in the Netherlands. Commercial greenhouses are now frequently located near appropriate industrial facilities for mutual benefit
  • 12.
    12 consuming both wasteheat and CO2 from the refinery which would otherwise be vented to atmosphere TYPES In domestic greenhouses, the glass used is typically 3mm 'horticultural glass' grade, which is good quality glass that should not contain air bubbles (which can produce scorching on leaves by acting like lenses). Plastics mostly used are polyethylene film and multiwall sheets of polycarbonate material, or PMMA acrylic glass. Commercial glass greenhouses are often high-tech production facilities for vegetables or flowers. The glass greenhouses are filled with equipment such as screening installations, heating, cooling and lighting, and may be automatically controlled by a computer. Dutch Light Green House In the UK and other Northern European countries a pane of horticultural glass referred to as "Dutch Light" was historically used as a standard unit of construction, having dimensions of 28¾″ x 56″ (approx. 730mm x 1422 mm). This size gives a larger glazed area when compared with using smaller panes such as the 600mm width typically used in modern domestic designs which then require more supporting framework for a given overall greenhouse size. A style of greenhouse having sloped sides (resulting in a wider base than at eaves height) and using these panes uncut is also often referred to as of "Dutch Light design", and a cold frame using a full- or half-pane as being of "Dutch" or "half-Dutch" size. LEAN -TO GREENHOUSE: Less expensive than freestanding models and a good option where space is limited, the attached lean-to greenhouse shares one wall with a house, garage or other building. Lean- to greenhouse have available utility sources nearby and are cheaper to operate than full-size greenhouses. Besides providing more usable space, it has a superior shape for air circulation. FREE STANDING GREENHOUSE: They are separate structures. They allow many size options, and provision must be made for heat, water and electricity. Larger greenhouses are actually more easily
  • 13.
    13 managed, because smallgreenhouses have more rapidly fluctuating temperatures. Several common frames are the quonset, a low, circular shape usually covered with plastic sheeting; the gothic, similar to the quonset but with a higher arch; the rigid-frame, with vertical sidewalls and rafters; and the A-frame, with sloping sides forming a triangular shape. USES Greenhouses allow for greater control over the growing environment of plants. Depending upon the technical specification of a greenhouse, key factors which may be controlled include temperature, levels of light and shade, irrigation, fertilizer application, and atmospheric humidity. Greenhouses may be used to overcome shortcomings in the growing qualities of a piece of land, such as a short growing season or poor light levels, and they can thereby improve food production in marginal environments. Greenhouses in hot, dry climates used specifically to provide shade are sometimes called "shade houses". As they may enable certain crops to be grown throughout the year, greenhouses are increasingly important in the food supply of high- latitude countries. One of the largest complexes in the world is in Almeria, Andalucía, Spain, where greenhouses cover almost 200 km2 (49,000 acres). Greenhouses are often used for growing flowers, vegetables, fruits, and transplants. Special greenhouse varieties of certain crops, such as tomatoes, are generally used for commercial production. Many vegetables and flowers can be grown in greenhouses in late winter and early spring, and then transplanted outside as the weather warms. Bumblebees are the pollinators of choice for most pollination, although other types of bees have been used, as well as artificial pollination. Hydroponics can be used to make the most use of the interior space. The relatively closed environment of a greenhouse has its own unique management requirements, compared with outdoor production.
  • 14.
    14 POLYHOUSE A polytunnel (alsoknown as a polyhouse, hoop greenhouse or hoop house, grow tunnel or high tunnel) is a tunnel typically made from z35 Steel and covered in polythene, usually semi-circular, square or elongated in shape. The interior heats up because incoming solar radiation from the sun warms plants, soil, and other things inside the building faster than heat can escape the structure. Air warmed by the heat from hot interior surfaces is retained in the building by the roof and wall. Temperature, humidity and ventilation can be controlled by equipment fixed in the polytunnel or by manual opening and closing of vents. Poly-tunnels are mainly used in temperate regions in similar ways to glass greenhouses and row covers. The nesting of row covers and low tunnels inside high tunnels is also common. USES: Poly-tunnels can be used to provide a higher temperature and/or humidity than that which is available in the environment but can also protect crops from intense heat, bright sunlight, winds, hailstones, and cold waves. This allows fruits and vegetables to be grown at times usually considered off season; market gardeners commonly use poly- tunnels for season extension. Beyond season extension, poly-tunnels are also used to allow cold-hardy crops to overwinter in regions where their hardiness isn't quite strong enough for them to survive outdoors. Temperature increases of only 5° to 15° above outdoor ambient, coupled with protection from the drying effect of wind, are enough to let selected plant varieties grow slowly but healthily instead of dying. The effect is to simulate "moving the farm south by several hardiness zones", that is, to create a microclimate that simulates the temperatures of a location several hardiness zones south (and protects from wind as well). Every factor influencing a crop can be controlled in a polytunnel. Poly- tunnels are often used in floriculture and plant nurseries, as the revenue value of the plants can justify the expense.
  • 15.
    15 SHADE NET Agro shadenet is a simple yet powerful innovation that helps protect crops, used to provide the crops with a shade from the sunrays. Though sunrays are the major requirement for the growth of plants and crops, yet it has been seen and recorded that over-exposure to sun rays can lead to much damage to the crops. This happens because certain crops and plants are extremely fragile. They do not require too much of sun exposure. Moreover, there are certain geographical locations which are more prone to harsh sun rays than other places. In these places, the cultivation of many crops is unfeasible. To cultivate fragile plants, one must take care of the crops well. The agro shade net is one such way to protect the crops. They are a very real and cost effective way to control the ill effects of UV radiations on plants and crops, extremely useful in protected cultivation of high value crops. Especially for high value crops, where no risk can be taken by the farmers or cultivators, it is very important of take optimum care of the crops and make sure that they are protected against the vagaries of nature. With innovation in this field, now shade nets can successfully control the harmful effects of UV rays on plants and keep them safe and sound. Shade Selection: A good shade net must have high strength and should be durable. This will ensure that it will not wear out soon and will last you several crop lives. The biggest benefit and feature is the UV stabilization feature that will ultimately protect the crops against the harmful effects of UV radiations. A good shade net must offer optimum shade factor that protects the crops well. The shade net must be technically designed for higher yield. MICRO-IRRIGATION SYSTEM Micro-irrigation or trickle irrigation is an irrigation method with lower pressure and flow than a traditional sprinkler system. Low volume irrigation is used in agriculture for row crops, orchards, and vineyards. It is also used in horticulture in wholesale nurseries, in landscaping for civic, commercial, and private landscapes and gardens, and in the
  • 16.
    16 science and practiceof restoration ecology and environmental remediation. There are several types of micro-irrigation systems. Many of the components are the same for all of these types of systems. Most systems typically include filters, pipes, valves, and tubing. The main difference is in the type of emission device that is used to deliver the water to the plants. Drip irrigation utilizes drip emitters that deliver water at very low rates. The typical range is 0.2 to 4.0 gallons per hour. In some systems, the emitters are installed manually on the outside of the tubing and placed where needed. Other systems might use integral dripper line or drip tape with the emitters already installed at a predetermined spacing. Micro-sprinklers, which can include fixed stream sprays and rotating spinners typically deliver water at a higher rate, such as 10 to 25 gallons per hour and will cover a larger area than drip emitters. These are more typically used in tree orchards where the plants are larger. The goal is to distribute water slowly in small volumes and target it to plants' root zones with less runoff or overspray than landscape and garden conventional spray and rotary sprinklers. The low volume allows the water to penetrate and be absorbed into slow- percolation soils, such as clay, minimizing water runoff. System components: There is a wide variety of system components included in a micro-irrigation system. Most systems include a filter. These may include pre-filters, sand separators, media filters, screen filters, and disc filters. The level of filtration required depends on the size of the emission device and the quality of the water source. A pressure regulator or regulating valve may be required to reduce the system pressure to the desired level. Automatic or manually operated valves will be required to switch from one irrigated section to another. An irrigation controller will be used with automatic systems and may also be needed for back flushing the filter or sand separator. Emission devices: Micro tubing consists of very small diameter tubing. Flow is regulated purely by the length and diameter of the tubing.
  • 17.
    17 Fixed flow dripemitter: Low-flow irrigation systems in gardens using drip apply water through two methods:  pre installed small holes in small diameter tubes placed on or below the surface or  Self cleaning emitters, in different precipitation rates, pre installed or contractor installed for different rate emitters on same supply. Low volume irrigation systems often use the two delivery components of drip systems to apply water through small holes in small diameter tubes placed on or below the surface of the field. This is done instead of agricultural surface irrigation and furrow irrigation for vegetables, fruits and berries, and other high-value crops. Adjustable drip emitters Trickle emitters, also called 'spider sprays,' come in fixed or adjustable radius shapes and diameters, and are installed directly on the flexible supply pipe or on tubing connected to it, and mounted on small stakes. Trickle emitter-'Spider sprays' work well for plants with more fibrous root systems, tree and large shrub basins, and in pots and container gardens - allowing automated watering of plants on decks and patios. Mist emitters can also be used in pot, both on the ground and hanging, with humidity-fog watering for epiphytes and ferns replicating habitats. Micro-sprinklers: Low volume micro-sprinklers may be attached to hard plastic risers or attached to standard sprinkler heads, but are more typically mounted on stakes and attached to small diameter micro-tubing connected to polyethylene tubing with a barbed connector. Some micro- sprinklers have a fixed spray or stream pattern, while others rotate. These are installed above ground and are often used for fruit and nut orchards and vineyards. These systems are expensive, even for large- scale agricultural use, and are predominantly used for high-value crops.
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    18 MIST PROPAGATINGUNIT Mist Propagationof Herbaceous and Softwood Cutting: Mist propagation consists of maintaining a film of water on the leaves of the cutting and relative humidity of the ambient air. In this way, the rate of transpiration is reduced to a minimum and as result the guard cells remain turgid. The stomata’s remain open, and the manufacture of carbohydrates and related substances proceeds unabated even in presence of high light intensity. Further, with the high light intensity, the evaporation of water from the leaves keep the tops relativity cool, and this in turn lowers the rate of respiration. Thus, with the low rate of transpiration combines with the low rate of respiration, other manufactured substances become available for the initiation and growth of the root system. There are Two Kinds or Types of Misting: i) Continuous and ii) Intermittent. The continuous involve applying the mist continuously during the light period, whereas the intermittent system involves applying the mist at definite intervals during the light period. Each system has advantages and disadvantages. Continuous has disadvantage that excessive leaching of soluble compounds from the leaves is likely to take place and unless the media is well drained, water logging of the media is likely to occur. The main advantages of the intermittent system are that excessive leaching of soluble compounds from the leaves and water lagging of the media is likely to occur. The main advantages of the intermittent system is that excessive leaching of soluble compounds from the leaves and water logging of the media is not take place. In general, five system have been development to control the misting cycle of the intermittent system. Of these five systems, three are used in
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    19 commercial installations. Theseare 1) misting cycle time clock, 2) electronic leaf, and 3) Mistomatic, the electric time clock consist of a day night clock and a misting cycle clock connected with a solenoid valve. The day night clock turns on the system in the morning, usually just after sunrise, and off in the evening, usually just after sunset, the misting cycle clock turns the system on and off for definite intervals during the day, for ex, a commonly used misting cycle is one minute with the clock set to mist the cutting for three, four, or five or more seconds per minute. The main advantages of this system are that it has a relatively low installation and maintenances cost. Its main disadvantages are that manual operations required to change the misting cycle. The electronic leaf consists of a piece of plastic with two electrodes and a control unit connected to a solenoid valve. It is based on the assumption of evaporation of water from the leaves. Thus, the main advantage of this system is that the period of misting varies with the rate of evaporation and transpiration of waster from the leaves, which varies according to temperature and light intensity. The Mistomatic system consists of a small stainless steel or grid and a control unit connected to a solenoid valve. Here again, this system operates on the assumption that the rate of evaporation of water from the screen or grid is practically the same as the rate of transpiration and evaporation of water from the leaves. The operation of the Mistomatic system is similar to that of the electronic leaf system, and its main advantages and disadvantages are practically the same. …………………*………………………..*…………………………..
  • 20.
    20 Reference Homeguides.sfgate.com, www.dpi.nsw.gov.au https://en.wikipedia.org/wiki/greenhouse ecourse.iasr.res.in ,www.biologydiscussion.com floriculture-india.blogspot.in , www.agrinfo.in My Agriculture information bank ,www.quora.com Jugraphia.wordpress.com , www.agrislide.com Common core, Unified botany IV Date of submission: 3rd Oct ‘17 Marks allotted: