The document describes the development and promotion of locally assembled low-head drip irrigation systems called "dream drip kits" for small-scale farmers in Kenya. Key points:
1) The kits were designed to be simple, low-cost, and locally assembled using available materials to address limitations of imported systems and be affordable for small farmers.
2) Systems include bucket, jerrican, and mini-tank kits that can irrigate areas from 15-1,000 square meters, with costs ranging from $22-357.
3) Over 800 bucket kits, 500 jerrican kits, and 200 drum kits have been sold since 2002, and feedback from farmers has been positive on their
Canal & canal types with design of channels by dj sir covered kennedy lacey t...Denish Jangid
Canal its types with design of channels by Denish Jangid sir.
covered kennedy lacey theory IS code method with comparison drawbacks.
design steps by kennedy
design steps by lacey
design of canal types of canal trapezoidal shape. Canal Irrigation. Subject-
Water Resources Engineering By Dr.* Denish Jangid Assistant Professor Civil Engineering Department
Canal Classification based on Financial returns
Canal Classification based on Use
Canal Classification based on Size
Cana Masonry work
alluvial soil
Cross regulator
Head regulator
Silt Control device
Silt ejector
Silt excluder
Factor affecting the Canal Alignment
A contour canal is an artificially-dug navigable canal which closely follows the contour line of the land it traverses in order to avoid costly engineering works such as boring a tunnel through higher ground, building an embankment over lower ground, or constructing a canal lock (or series of locks) to change the level of the canal. Because of this, these canals are characterized by their meandering course.
Step Determine the depth D and bed width B from values of A & P
Cost of construction including cross drainage works should be minimized. .A shorter length of canal ensures less loss of head due to friction and smaller loss of discharge due to seepage and evaporation, so that additional area may be brought under cultivation. A canal may be aligned as a contour canal, a side slope canal or a ridge canal according to the type of terrain and culturable area. A contour canal irrigate areas only on one side of the canal. Where canal crosses valleys, different types of cross drainage works are required. A side slope canal is aligned at 90 degree to the contours of the region. A watershed or ridge canal irrigate areas on both sides. Cross drainage works are eliminated in case of ridge and side slope. Main canal is generally carried on a contour alignment. Branch and distributaries take off from a canal from or near the points where the canal crosses the watershed. All possible alignments should be studied and the best suited alignment should be selected. Number of rinks and acute curves should be minimized. They should be aligned as far as possible in partial cutting partial filling. Deep cutting should be avoided by comparing the overall cost of alternative alignments.
One of the newest materials in the construction of water structures in recent years is the rubber material that is widely used in the construction of dams or short dams. In rubber dams, the remarkable flexibility of materials against external factors, compatible with the environment, simplicity of design, short time of building, safety and stability of these structures, such dams than rigid, simplicity and ease of use and ultimately reducing operating costs caused has been used in large and small water projects. Due to the limited information in the field of rubber dams, this article provides the possibility of rubber dams introducing, how to design, building and maintaining.
Basics of network analysis
Need of soft wares in design of water distribution network
Capabilities of soft wares
Different soft wares used in design of water distribution network
Canal irrigation- (topics covered)
Types of Impounding structures: Gravity dam – Diversion Head works - Canal drop –
Cross drainage works – Canarl egulations – Canal outlets – Cana ll ining - Kennady s
and Lacey s Regim et heory
TYPES OF RIVER, PERENNIAL & NON PERENNIAL, PERENIAL V/S NON PERENIAL, STAGES OF RIVERS, RIVER STAGES COVERED, MEANDERING, CUT OFF, RIVER TRAINING WORKS, OBJECTIVE OF RIVER TRAINING, CLASSIFICATION OF RIVER TRAINING WORKS, TYPES OF RIVER TRAINING WORK, PICTURES
Canal & canal types with design of channels by dj sir covered kennedy lacey t...Denish Jangid
Canal its types with design of channels by Denish Jangid sir.
covered kennedy lacey theory IS code method with comparison drawbacks.
design steps by kennedy
design steps by lacey
design of canal types of canal trapezoidal shape. Canal Irrigation. Subject-
Water Resources Engineering By Dr.* Denish Jangid Assistant Professor Civil Engineering Department
Canal Classification based on Financial returns
Canal Classification based on Use
Canal Classification based on Size
Cana Masonry work
alluvial soil
Cross regulator
Head regulator
Silt Control device
Silt ejector
Silt excluder
Factor affecting the Canal Alignment
A contour canal is an artificially-dug navigable canal which closely follows the contour line of the land it traverses in order to avoid costly engineering works such as boring a tunnel through higher ground, building an embankment over lower ground, or constructing a canal lock (or series of locks) to change the level of the canal. Because of this, these canals are characterized by their meandering course.
Step Determine the depth D and bed width B from values of A & P
Cost of construction including cross drainage works should be minimized. .A shorter length of canal ensures less loss of head due to friction and smaller loss of discharge due to seepage and evaporation, so that additional area may be brought under cultivation. A canal may be aligned as a contour canal, a side slope canal or a ridge canal according to the type of terrain and culturable area. A contour canal irrigate areas only on one side of the canal. Where canal crosses valleys, different types of cross drainage works are required. A side slope canal is aligned at 90 degree to the contours of the region. A watershed or ridge canal irrigate areas on both sides. Cross drainage works are eliminated in case of ridge and side slope. Main canal is generally carried on a contour alignment. Branch and distributaries take off from a canal from or near the points where the canal crosses the watershed. All possible alignments should be studied and the best suited alignment should be selected. Number of rinks and acute curves should be minimized. They should be aligned as far as possible in partial cutting partial filling. Deep cutting should be avoided by comparing the overall cost of alternative alignments.
One of the newest materials in the construction of water structures in recent years is the rubber material that is widely used in the construction of dams or short dams. In rubber dams, the remarkable flexibility of materials against external factors, compatible with the environment, simplicity of design, short time of building, safety and stability of these structures, such dams than rigid, simplicity and ease of use and ultimately reducing operating costs caused has been used in large and small water projects. Due to the limited information in the field of rubber dams, this article provides the possibility of rubber dams introducing, how to design, building and maintaining.
Basics of network analysis
Need of soft wares in design of water distribution network
Capabilities of soft wares
Different soft wares used in design of water distribution network
Canal irrigation- (topics covered)
Types of Impounding structures: Gravity dam – Diversion Head works - Canal drop –
Cross drainage works – Canarl egulations – Canal outlets – Cana ll ining - Kennady s
and Lacey s Regim et heory
TYPES OF RIVER, PERENNIAL & NON PERENNIAL, PERENIAL V/S NON PERENIAL, STAGES OF RIVERS, RIVER STAGES COVERED, MEANDERING, CUT OFF, RIVER TRAINING WORKS, OBJECTIVE OF RIVER TRAINING, CLASSIFICATION OF RIVER TRAINING WORKS, TYPES OF RIVER TRAINING WORK, PICTURES
Canal Regulation Works:
Canal Fall- Necessity and Location- Types of Falls- Cross Regulator and Distributory Head Regulator- Their Functions, Silt Control Devices, Canal Escapes- Types of Escapes.
ALL TYPE OF SANITARY FITTING SHOULD BE FIXED AGAINST AN EXTERNAL WALLS , SO THAT THE APARTMENT IN WHICH THEY ARE PLACED CAN BE PROVIDED WITH NATURAL LIGHT AND AIR, AND ALSO THERE WASTES CAN BE EASILY COLLECTED IN DRAIN.
Canal Regulation Works:
Canal Fall- Necessity and Location- Types of Falls- Cross Regulator and Distributory Head Regulator- Their Functions, Silt Control Devices, Canal Escapes- Types of Escapes.
ALL TYPE OF SANITARY FITTING SHOULD BE FIXED AGAINST AN EXTERNAL WALLS , SO THAT THE APARTMENT IN WHICH THEY ARE PLACED CAN BE PROVIDED WITH NATURAL LIGHT AND AIR, AND ALSO THERE WASTES CAN BE EASILY COLLECTED IN DRAIN.
Sewer appurtenances are those structures and devices of a sewerage system which are constructed at suitable intervals along a sewer line to assist in the efficient operation and maintenance of the system. Following are the important sewer appurtenances: 1. Inlets 2. Catch Basins or Catch Pits 3. Clean-Outs 4.
sewer appurtenances ppt
sewer appurtenances and their details
types of appurtenances
appurtenances definition construction
appurtenances in construction
sewerage appurtenance
pipeline appurtenances definition
building appurtenances
sewerage appurtenance
sewer appurtenances and their details
appurtenances in construction
building appurtenances
appurtenances definition construction
types of appurtenances
pipeline appurtenances definition
The ultimate guide for drip irrigation 2018Amar Sawant
This Guide will teach you everything you need to know about Drip Irrigation.
Components Of Drip irrigation system
Cost of installation
Government subsidy
And Guidelines For Maintenance and much other valuable information that I’ve never shared anywhere else before.
Let’s get started…
The available water for agriculture is decreasing day by day due to increase in population, industrialization, and short rainfall. it has become essential to use modern irrigation technologies like Drip irrigation, sprinkler irrigation in agriculture
Drip irrigation means providing the required quantity of water directly to the root zone of Crop plants through a network of small pipes this is also called micro-irrigation or trickle irrigation.
This is the most efficient irrigation technique.
In Drip irrigation system water supplies to plant roots through a collection of plastic pipes, lateral tubes, and valves. These components, controlled with the help of dripper and water pump. with help drip irrigation system it is become easy to provide liquid fertilizer to plant root system.
Water conservation by Rainwater Harvesting systems – Treatment of waste water : Physical,Chemical and
Biological methods – Root Zone treatment - Use of recycled water.
Use of Environment friendly materials, Embodied Energy of materials, Bio degradable materials. Recycling
and Reuse of steel, Aluminium and Glass.
An Overview of Aquaponic Systems: Hydroponic
Components
D. Allen Pattillo
Iowa State University, pattillo@iastate.edu
http://lib.dr.iastate.edu/ncrac_techbulletins/19/
Transforming Brand Perception and Boosting Profitabilityaaryangarg12
In today's digital era, the dynamics of brand perception, consumer behavior, and profitability have been profoundly reshaped by the synergy of branding, social media, and website design. This research paper investigates the transformative power of these elements in influencing how individuals perceive brands and products and how this transformation can be harnessed to drive sales and profitability for businesses.
Through an exploration of brand psychology and consumer behavior, this study sheds light on the intricate ways in which effective branding strategies, strategic social media engagement, and user-centric website design contribute to altering consumers' perceptions. We delve into the principles that underlie successful brand transformations, examining how visual identity, messaging, and storytelling can captivate and resonate with target audiences.
Methodologically, this research employs a comprehensive approach, combining qualitative and quantitative analyses. Real-world case studies illustrate the impact of branding, social media campaigns, and website redesigns on consumer perception, sales figures, and profitability. We assess the various metrics, including brand awareness, customer engagement, conversion rates, and revenue growth, to measure the effectiveness of these strategies.
The results underscore the pivotal role of cohesive branding, social media influence, and website usability in shaping positive brand perceptions, influencing consumer decisions, and ultimately bolstering sales and profitability. This paper provides actionable insights and strategic recommendations for businesses seeking to leverage branding, social media, and website design as potent tools to enhance their market position and financial success.
Between Filth and Fortune- Urban Cattle Foraging Realities by Devi S Nair, An...Mansi Shah
This study examines cattle rearing in urban and rural settings, focusing on milk production and consumption. By exploring a case in Ahmedabad, it highlights the challenges and processes in dairy farming across different environments, emphasising the need for sustainable practices and the essential role of milk in daily consumption.
Expert Accessory Dwelling Unit (ADU) Drafting ServicesResDraft
Whether you’re looking to create a guest house, a rental unit, or a private retreat, our experienced team will design a space that complements your existing home and maximizes your investment. We provide personalized, comprehensive expert accessory dwelling unit (ADU)drafting solutions tailored to your needs, ensuring a seamless process from concept to completion.
Hello everyone! I am thrilled to present my latest portfolio on LinkedIn, marking the culmination of my architectural journey thus far. Over the span of five years, I've been fortunate to acquire a wealth of knowledge under the guidance of esteemed professors and industry mentors. From rigorous academic pursuits to practical engagements, each experience has contributed to my growth and refinement as an architecture student. This portfolio not only showcases my projects but also underscores my attention to detail and to innovative architecture as a profession.
Dive into the innovative world of smart garages with our insightful presentation, "Exploring the Future of Smart Garages." This comprehensive guide covers the latest advancements in garage technology, including automated systems, smart security features, energy efficiency solutions, and seamless integration with smart home ecosystems. Learn how these technologies are transforming traditional garages into high-tech, efficient spaces that enhance convenience, safety, and sustainability.
Ideal for homeowners, tech enthusiasts, and industry professionals, this presentation provides valuable insights into the trends, benefits, and future developments in smart garage technology. Stay ahead of the curve with our expert analysis and practical tips on implementing smart garage solutions.
Book Formatting: Quality Control Checks for DesignersConfidence Ago
This presentation was made to help designers who work in publishing houses or format books for printing ensure quality.
Quality control is vital to every industry. This is why every department in a company need create a method they use in ensuring quality. This, perhaps, will not only improve the quality of products and bring errors to the barest minimum, but take it to a near perfect finish.
It is beyond a moot point that a good book will somewhat be judged by its cover, but the content of the book remains king. No matter how beautiful the cover, if the quality of writing or presentation is off, that will be a reason for readers not to come back to the book or recommend it.
So, this presentation points designers to some important things that may be missed by an editor that they could eventually discover and call the attention of the editor.
1. Background
Most drip irrigation systems operate with high head (>10 meter water pressure). However,
currently affordable small-scale low-head drip technologies for individual households are being
developed, promoted and adopted in Kenya. It consist of a water supply source (20-litre bucket,
40-100-litre jerrican or 200-litre drum/mini-tank), placed at a head of 0.5-1.0m, from which
water flows through a filter and then to row crops planted along the laterals at specified emitter
spacing. The pioneer Chapin system includes a bucket or a drum equipped with drip lines and
was promoted by KARI and FPEAK in Kenya. The systems have been adapted for use with the
conventional piped water supply system. The bucket drip irrigation has proved popular among
the small-scale farmers because of its low cost, increased beneficial use of available water, easy
management, and high value crops grown. By 2000, KARI had sold over 3,000 bucket kits and
400 eighth-acre kits, most of them through women groups since its introduction in the country
in1996.
However, despite the adoption rate, the farmers identified some challenges that needed to be
addressed to improve its performance and sustainability (Winrock, 2000; Kabutha et al., 2000).
This prompted the University of Nairobi in collaboration with the International Water
Management Institute (IWMI) and the Kenya Agricultural Research Institute (KARI) to
undertake a technical evaluation of, not only the Chapin bucket kit, but other drip systems that
can be adopted for low-head drip irrigation.
Design and Development of Locally Assembled Drip Irrigation Systems
Bucket Kit
A simple locally assembled low-head drip system called dream drip kit, was designed and
developed to address most of the limitations identified by farmers. It consist of a water supply
source, 20-litre bucket, placed at a head of 0.8m, from which water flows to drip laterals
through a filter to the crops planted along the laterals. The bucket kit has been up-scaled to 40-
100-litre jerrican or 200-1,500-litre drum/mini-tank kits. The dream drip kits are simple, low
cost, flexible, easy to install, operate and maintain, and are up-scalable in terms of emitter
spacing, water requirement and irrigable area.. All the components of dream drip kits are
locally available.
The system was adapted from Chapin kit in which the complicated filter-cork connection was
replaced by a simple elbow connection, which is fitted with a filter that can be plugged in and
out easily from inside the bucket (see Fig. 1). The filter connection was further modified to
allow quick dismantling to ease bulk transportation—piling a number of buckets together.
This was achieved by using a threaded galvanized iron socket from which the nippled filter is
screwed from inside the bucket and the outlet nipple screwed from outside.
The bucket and the drip laterals are connected through a 0.8m long, clear and flexible hose-
pipe, which is connected to a PVC header connector. The header connector is fitted with PVC
pipes up to the required lateral spacing. The PVC pipes are then fitted either to a tee
connector for a kit with more than two laterals or to elbow connector, from which the drip
line (barb) connectors are force-fitted. The clear hose pipe is used to allow detection of
airlock that may affect water distribution due to reduced pressure head. If airlock is detected,
the elbow connection to the bucket is slightly pulled out and pushed in to release trapped air.
This priming process is done repeatedly until the clear hose pipe is filled with water—all the
trapped air is released to enable attainment of the required head.
1
2. Bucket (20-litres)
Wooden stand (0.8m high)
Clear down-pipe
Header connector (4 laterals)
Drip line (7.5m long)
Fig. 1. Typical dream drip kit 20-litre bucket irrigation system
Jerrican and Drum or Mini-Tank Systems
Depending on the farmers’ preference, intermediary systems with storage capacity between
20-1,500-litre are also available. The bucket kit can be up-scaled to 40-100-litre jerrican
system raised at 0.8m. The drum/mini-tank systems range from 200-1,500-litre raised at 1.0 -
1.5m depending on the method of water delivery. The mini-tank system can even be up-
scaled up to 5,000-litre where bigger storage facilities are available or where the system can
be connected directly to a household water supply system. Thus the micro-irrigation system
can be used to cover between 15-4,000m2. The cost of intermediary and up-scaled systems is
proportional to the size and material used, though bigger system are cheaper due to economy
of scale. The 200-litre drum is held horizontally with the inlet on the upper side while the
mini-tank orientation is similar to the bucket or jerrican system (see Fig. 2).
Fig.2. Layout of dream drip kit mini-tank (200-litre) irrigation system
2
3. Like the bucket kit, the jerrican, drum or mini-tank drip irrigation kit is assembled from
locally available materials. All the accessories are made of 2.5cm diameter low pressure
polyethylene (PE) pipes and PVC connectors. The outlet system is fitted with a double screen
filter and a silt trap at the lower end. This is done to allow enough pressure to push the water
through the dense screen filter. Any debris and solid particles are collected by the silt trap,
which is flushed regularly. The barb (lateral) connectors are directly fitted to the PE header
connector at predetermined spacing based on crop to be grown. The header connector is fitted
with removable end plugs for flushing any silt that may pass through the filter. To ease
transportation, the header connector is cut into short pieces (e.g. 1.2 - 1.5m each for 2
laterals), and provided with simple force fit connections.
The optimal height for placing the water supply reservoir is mainly based on ergonomics—
level that will allow an average person to refill the drum/mini-tank using a 20-litres container
without straining—in case of manual refilling. In most cases, a height of 0.8m is ideal, which
means that the inlet will be less than 1.2m. This eases manual refilling of water, which is
common in most rural situations. The effect of water supply head (see section 4.3) between
0.5 – 1.5m was no significant and hence lower heads will not drastically affect water
distribution uniformity. However, if the drip kit is near a water source (a shallow well, stream
or reservoir (farm pond, water pan, earthdam or underground tank) it may be refilled by a
simple manual pump (hand pump or treadle pump) or motorized pump. A hose pipe from a
yard connection water supply may also be used. In such cases, a higher head can be achieved.
To regulate the flow of water, a gate valve is fitted at the outlet (Figs. 7 & 8). The gate valve
is closed after the drum/tank is empty and then the drum/tank is refilled for the next
irrigation. The header is connected to 10-20 laterals depending on topography, i.e. more
lateral for the flat land and fewer for gently sloping land to enhance emission uniformity. The
emission uniformity can be further enhanced by ensuring that the header connector is at 0%
slope. Otherwise the laterals on the lower side will receive more water leading to low water
distribution uniformity.
The dream drip kit bucket irrigation system has also been adapted for irrigating tree nursery
seedlings as shown in Fig. 3. This need was first identified during a community training in
Mwanza, Tanzania.
Fig. 3. Dream drip bucket kit adaptation for irrigating tree nursery seedlings
3
4. Promotion and Adoption
Most rural communities consist of subsistence smallholder farmers whose low income
hinders adoption of a complex technology that would improve their livelihoods. Their
knowledge level may also affect adoption of a complicated technology. These factors were
considered in the design and development of “dream drip kits”. The complicated, delicate and
fragile imported low-head drip system was simplified and localized to make it attractive to
rural farmers. Its installation and management is within the capacity of most smallholder
farmers, even those without prior knowledge of drip irrigation technology. The “dream drip
kits” are low-cost and hence affordable. Table 6 shows that the cost ranges from US$ 22 for
the smallest unit to US$ 172 for the 200-litre mini-tank (drum) kit and US$ 357 for larger
systems (a 500-litre mini-tank kit, which can irrigate up to 1,000m2). Except for the bucket
adaptation for tree nursery, the cost per unit area decreases with the size of the drip kit due to
economy of scale. Socio-economic analysis revealed that a benefit: cost ratio of up to 4 : 1
can be attained within a 3-month growing season (Ngigi et al., 2005; Ngigi, 2001 & 2002;
Winrock, 2000; and Kabutha et al., 2000).
Table 6. Specifications and cost of dream drip kit irrigation systems (1US$ @ Ksh. 70)
Specification of dream drip kits irrigation systems Area (m2) Cost (US $) Cost ($/m2)
20-litres bucket kit: 4 laterals of 7.5m; 2 laterals of 15m 15-20 22 1.14
or 6 laterals of 5m; and 15 - 30cm emitter spacing
20-litres bucket kit for tree nurseries: 6 laterals of 6-10 34 3.38*
10m; 8 laterals of 7.5m or 10 laterals of 6m; and 10 -
15cm emitter spacing
40[50]-litres jerrican kit: 4 laterals of 15m; 6 laterals 30-40 40 1.09
of 10m or 8 laterals of 7.5m; and 30 - 60cm emitter
spacing
60[70]-litres jerrican kit: 6 laterals of 15m; 12 laterals 50-60 62 1.00
of 7.5m or 8 laterals of 10m; and 30 - 60cm emitter
spacing
80-litres jerrican kit: 8 laterals of 15m; 12 laterals of 60-80 75 0.99
10m; 16 laterals of 7.5m; and 30 - 60cm emitter
spacing
100-litres jerrican kit: 10 laterals of 15m; 16 laterals 80-120 93 0.90
of 10m or 20 laterals of 7.5m; and 30 - 60cm emitter
spacing
150-litres mini-tank Kit: 12-16 laterals of 15m or 20 150-250 130 0.63
laterals of 10m; and 30 - 60cm emitter spacing
200[230]-litres mini-tank/drum kit: 16 - 20 laterals of 300-500 172 0.41
15m or 12 - 16 laterals of 20m; and 30 - 60cm emitter
spacing
500-litres mini-tank kit: 32 – 40 laterals of 20-25m 800-1,000 357 0.31
laterals; and 30 -60cm emitter spacing
The attractive attributes, which includes ease of operation, simplicity and durability, have
contributed to adoption of dream drip kits in Kenya and to some extent in East Africa. The
demand for the dream drip kits for micro-irrigation has been increasing for the last 5 years
(2000-2005). Since 2002, more than 200 drum kits, 500 jerrican kits and 800 bucket kits have
been sold (WAREM, 2006). Though the bucket kit may be considered as economically
unviable (Kulecho and Weatherhead (2006), it has been proven adequate for supplying
4
5. vegetables for household consumption. However, for income generation, bigger systems are
more viable. The feedback from the users has also been encouraging, in terms of
practicability and replicability in diverse climatic areas of the country. External support
agencies such as Non-Governmental Organizations (NGOs) and Community-Based
Organizations (CBOs) have been instrumental in the promotion of the dream drip kits.
Publicity and awareness creation has also been achieved through Nairobi International
Agricultural Show (2001-2006), Kenya Rainwater Association (KRA) Annual Exposition
(2000-2005), workshops and farmers’ demonstration training and field days.
The dream drip kit has won a number of awards during annual Rainwater Exposition
organized by the Kenya Rainwater Association since 2000. At the international scene, the
dream drip kit was entered in the International Contest on Innovative Irrigation Ideas &
Technologies for Stallholders sponsored by the World Bank, Irrigation Association,
International Development Enterprises, IPTRID/FAO and Winrock in 2001and 2002. It was
among the top 5 contestants in both years; i.e. 3rd finalist in 2001 & 2002 (Ngigi 2002 &
2001).
Performance of Dream Drip Kits
The developed dream drip kit performs better than similar systems as shown in the
comparison between imported Chapin and locally manufactured Victoria 0.5 drip lines that
was adopted. Dream drip kit is also simple, flexible, and adaptable and hence can easily be
fabricated and repaired by local artisans and farmers. The kit is durable, especially with
respect to the fragile drip laterals, which are strong enough to withstand rough handling. The
PVC header connector can also be buried under the soil to reduce the effects of direct solar
radiation. For larger systems, e.g. 1/8th or ¼ acre kit, ultra-violent resistant polyethylene (PE)
header connector has been adopted to enhance durability. Adoption of dream drip kits has
made an impact as a means to grow the much-needed vegetables and also for income
generation at household level. The reported performance and impact of the dream drip kit is
based on feedback from the farmers, some of whom had used the Chapin systems. For
example, this has been verified by field evaluation and monitoring in the semi-arid Ndeiya
Karai area of Kiambu district in Kenya, where the drip systems have been in use for 3 years.
The minimum investment cost and high returns of the system shows that minimum amount of
water can be used effectively for supplemental irrigation especially for kitchen gardening. A
number of external support agents (e.g. Sida supported Regional Land Management Unit
(RELMA), Dutch supported Semi Arid Rural Development Program (SARDEP), Danish
supported Kitui Agricultural Project (KAP), USAID supported KRA/GHARP project, and
UNDP-DED Community Water Initiative (CWI) through KRA) in their endeavor to promote
viable technologies for poor farmers have adopted dream drip kits. The technology is being
disseminated in Eastern and Southern Africa by RELMA, Arid Land Information Network
(ALIN), WAREM Consultants and the Greater Horn of Africa Rainwater Partnership
(GHARP), among other stakeholders.
Past experiences have shown that the investment cost recovery is guaranteed within one
season of 3 months for most vegetables (e.g. kale, spinach, tomatoes, etc). Hence this is as a
profitable enterprise, especially for smallholder farmers and more so for those initially hand-
watering their kitchen gardens. The kits are applicable to different localities especially the
semi arid areas where water is scarce. In the absence of reliable water supply, rainwater
harvested through surface tanks, underground tanks, shallow wells, farm ponds, earthdams, or
water pans can also be used effectively.
5
6. References
Kabutha, C., H. Blank and B. Van Koppen. 2000. Drip kits for smallholders in Kenya:
Experience and a way forward. Proceedings of 6th International Micro-Irrigation
Congress on “Micro-irrigation Technology for Developing Agriculture”. October 22-27,
2000. Cape Town, South Africa.
Kulecho, I.K. and E.K. Weatherhead. 2006. Adoption and experience of low-cost drip
irrigation in Kenya. Irrigation and Drainage, 55(4): 435-444
Ngigi, S.N. 2002. Up-scaling dream drip kits irrigation systems for small-scale farmers. 2002
International Contest on Innovative Irrigation Ideas & Technologies for Stallholders
sponsored by the World Bank, Irrigation Association, International Development
Enterprises, IPTRID/FAO and Winrock.
http://ww.irrigation.org/press_releases/default.aspx?r=1&pg=2002-PR7.htm (see 3rd
Finalist)
Ngigi, S.N. 2001. Dream drip kits irrigation system for small-scale farmers. 2001
International Contest on Innovative Irrigation Ideas & Technologies for Stallholders
sponsored by the World Bank, Irrigation Association, International Development
Enterprises, IPTRID/FAO & Winrock.
http://lnweb18.worldbank.org/ESSD/ardext.nsf/26ParentDoc/IrrigationandDrainageEve
ntsContestforInnovativeIrrigation (see 4th Finalist)
Ngigi, S.N., H.H.G. Savenije, J.N. Thome, J. Rockström and F.W.T. Penning de Vries. 2005.
Agro-hydrological evaluation of on-farm rainwater storage systems for supplemental
irrigation in Laikipia district, Kenya. Agricultural Water Management, 73(1): 21-41
Ngigi, S.N., J.N. Thome, D.W. Waweru and H.G. Blank. 2000. Low-cost irrigation for
poverty reduction: An evaluation of low-head drip irrigation technologies in Kenya.
IWMI Research Report. Collaborative research project between University of Nairobi
and IWMI. IWMI Annual Report 2000-2001; pp. 23-29.
WAREM. 2006. Sale records. Water Resources Management (WAREM) Consultants,
Nairobi, Kenya.
Winrock, 2000. Proceedings of Stakeholders Workshop on Low-Head Drip Irrigation
Technologies in Kenya. Nairobi, Kenya.
For more information contact:
Stephen N. Ngigi, Ph.D
Projects Coordinator
GHARP/KRA Secretariat
C/O Kenya Rainwater Association
P.O. Box 10742-00100
Nairobi, Kenya
Tel.: (0)20-2710657; 0722-864606; 0720-419222
E-mail: gharp@wananchi.com or gharp.kra@gharainwater.org
6