Category Archives: Uncategorized

Help Wanted – Science Extension Manager

June 2019

We’re not quite sure what to call the job: science manager, extensionist, project manager, consultant? We know it offers diverse activities and needs excellent communication skills and practical knowledge of horticulture and technology. For the right person, this is a role with considerable potential to grow.

At Page Bloomer Associates we care about sustainable land and water management. We are looking for someone to help identify and lead research projects and extension activities across a variety of issues and regions.

Since the dawn of the new millennium, we’ve been providing progressive, pragmatic and independent services through projects and consultancy. A key feature of our work is close collaboration with end users, researchers and developers. We talk about “linking thinking from the farm out”.

Our clients are both private and public including individual farmers, levy bodies, industry, research organisations and local and central government. We are proud to power LandWISE Inc, providing management and project services and running their annual conference.

If you have passion for smarter farming, a background in research and extension, and want a key role in a small dedicated organisation, we’d like to chat with you!

There is a brief Job Description here>

Well Within Nutrition Launches

wellwithinWe are delighted that Well Within, a community and personal nutrition consultancy, is up and running. This complements our sustainable food production values and services to provide a full programme of services “from soil to gut”.

Well Within was established by Phillipa Page, Principal at Page Bloomer Associates. A qualified nutritionist (Dip Nutritional Science), Phillipa has a particular interest in helping people understand their own unique digestion, food needs, cultural values and habits to achieve best health.

Well Within operates from consulting rooms at the Centre for Land and Water at 21 Ruahapia Road, Hastings.

IRRIG8Lite Updated

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The On-farm Irrigation System Calibration Tool, IRRIG8Lite was updated on 11 February 2014.

The key changes are in the Centre Pivot and Linear Move Irrigator calibration protocols. The only difference is that the Collector numbering has been reversed, so that Collector Number 1 is now the one closest to the machine inlet. In the case of Centre Pivots that is the closest to the pivot centre. For Linear Moves it is the collector nearest the tractor.

Minor changes include correcting a misnumbering in the Application Graphs.

The help files and Field Sheets have been updated to reflect these changes.

Download the latest version from http://www.pagebloomer.co.nz/resources/irrig8lite/

The assistance of ASL Software in processing these changes is gratefully acknowledged.

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Managing Water a Whole Farm Project

This article first appeared in Irrigatin New Zealand’s Quarterly magazine in 2012.

Hew Dalrymple says mapping maize yields with his combine harvester highlighted problems with water in his paddocks: some parts had too much and some had too little. Hew and brother, Roger, now have 20 pivot irrigators at Waitatapia, their 2400ha Manawatu sand country farms. And a comprehensive drainage programme as well.

Soils at Waitatapia are low-lying, deep sands in flat to undulating contour.  Crops often suffer yield loss due to drought stressed dune tops, a high water table and ponding in depressions. 

An integrated irrigation and drainage programme is in train, using high-tech land-levelling and drainage, centre pivots and precision irrigation.

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Land-levelling, or re-contouring, aims to even out the soil pattern and change the contours to gently rounded or more flattened slopes which follow the natural lie of the land. Elevation data collected on-farm with high accuracy GPS is fed into a software package that identifies best cut-and-fill options. A 560hp tractor and two large GPS controlled scrapers do the work. In effect, the tops are put in the hollows, and a median grade established.

The re-contouring is complemented by a surface drainage network, also installed with the help of GPS. “We need to be careful with open drains in sand, but it is a critical part of our infrastructure,” says Hew.

Water for irrigation comes from the Rangitikei River. Gravity helps deliver it to the and through the farm, greatly reducing energy costs. Pivots are the only realistic method given the soil type and scale of operation. But they do have limitations.

Several belts of pine forested sand dunes prevent pivots from completing full irrigation circles.  In several places dunes have been removed to increase the arc and irrigated area.

Because some areas under the pivots still have wet spots or drains requiring no irrigation, Hew has invested in three variable rate systems.  

Mapping with electromagnetic (EM) sensors and GPS logging helped identify variable soil zones.  “We’ve got a clear picture of the lower wet spots and the higher dry spots, and they correspond to our yield maps.” Carolyn Hedley at Landcare Research turned the EM maps into soil water holding capacity maps. These were used to design and manage the VRI system. 

The Dalrymples use a soil-moisture measurement service to help schedule irrigation. Light soils, variable weather, a high water table and capillary rise make careful scheduling essential. “We are also using EM survey information to select positions for soil moisture probes. That way, they will best represent the range of soil characteristics and drainage patterns,” says Hew.

So water management at Waitatapia is more than irrigation. Hew says, “It is about using water, nutrients and energy in better ways.  Better soil water management equals better nutrient management.  We invest a fair amount in irrigation.  We don’t want to pay a big power bill to over-water and flush nutrients through the soil profile.”

 “It is a big, expensive, integrated programme, but introducing irrigation and managing drainage has massive benefits for production and confidence,” says Hew. “The soils here are very light, but with good management they grow crops and pasture amazingly well.”

Measure Irrigation Energy Efficiency

IRRIG8Quick Irrigation Energy Efficiency guidelines and worksheets have been loaded on the Page Bloomer website: See http://www.pagebloomer.co.nz/resources/tools/irrigation-energy-efficiency/

These guidelines and worksheets were funded by the Energy Efficiency and Conservation Authority, EECA.

There are two separate guidelines, one for the pumping plant (pump and motor) and one for the delivery system (headworks and mainline). Ideally you’ll do both – they are designed to work together.

Why check pump performance?

Profitability – Incorrectly sized or physically deteriorated pumps will waste energy and money. A good pumping system saves money!

Sustainability – efficient pumping minimises energy use and carbon emissions. A good pumping system saves the environment!

Pump and motor selection are important system design considerations. Incorrectly sized pumps and/or motors will not operate at their most efficient points. So they will waste energy.

Low pressure is a common cause of poor irrigation uniformity which reduces overall system effectiveness and efficiency. The pump must provide adequate pressure and flow to ensure the system operates as designed.

Excessive pressure affects performance and wastes energy. Pump selection will usually allow about 5% extra pressure capacity to allow for slippage with time. But excessively oversized pumps are major energy wasters.

Why check delivery system performance?

Profitability – Incorrectly sized or physically deteriorated components can waste energy and money. A good system saves money!

Sustainability – energy efficient irrigation minimises energy use and carbon emissions. A good system saves the environment!

Pipe and component selection are important system design considerations. Selecting smaller options may reduce up front capital cost, but increases ongoing energy costs as bigger pumps are required. The correct selections optimise the necessary trade-offs.

Calibrating the Troxler Soil Moisture Density Gauge

Dan Bloomer (LandWISE) and Bruce Searle (Plant & Food Research)

Soil Moisture-Density Gauges are commonly used in construction and roading to monitor soil density. This enables engineers to determine that sufficient compaction has been achieved to ensure foundation stability.

This article summarises results from a Sustainable Farming Fund project co-funded by the Foundation for Arable Research and LandWISE.

LandWISE cropping trials have often found yield limitations where legacy compaction is not removed prior to establishing a new crop. A study was undertaken to see if a soil moisture – density gauge can give a valid measure of soil density in cropping fields, whether soil density is altered by cultivation practices and if it affects yield.

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Fig.1 Top view of Troxler Moisture-Density Meter

A Troxler 3440 soil moisture density gauge was used to assess soil at sites in Gisborne, Manawatu and Hawke’s Bay. One key advantage of the gauge is that measurements are completed quickly (a couple of minutes) in the field. Conventional sampling requires large samples to be taken, dried for several days in a lab, and then weighed to determine density and moisture.

Results showed the Troxler can give valid measures of soil density but must be calibrated for each soil type and depth. Some physical cores must be taken and processed to allow this.

The calibration curves for two Hawke’s Bay soils are shown in Figure 2. These show the relationship between gauge soil density ‘estimates’ and soil density measured by removing, drying and weighing soil cores.

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Figure 2. Relationship between estimated soil density obtained using individually calibrated Troxler measurements and soil core measured density for Twyford and Mangateretere soils.

Once calibrated, the Troxler offers the advantage of quickly collecting a large number of soil compaction measurements at different depths, without the cost of laborious soil sampling.  A draft protocol was prepared for calibration purposes.

Project details here>

Stay up to date with RSS Feeds

You’ll see that our website offers “Feeds”. A wee search engine checks our site each day for new material and lets you know if it finds any.
The steps below show you how to have Page Bloomer Feeds set as a favourite on your web browser.

Subscribe via RSS

RSS feeds set a favourites link in your web browser. The RSS feed collects our updates for you. When you look at your feeds, it contains items put on our website. You get the information, but you have to remember to look regularly yourself.

How do you subscribe to RSS feeds?

1. Look for this icon  RSSFeeds

It tells you the website offers feeds. On the PageBloomer site, you’ll find it on the right, just below the Search the Site box

2. Click on Subscribe via RSS

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 • A special PageBloomer page will come up showing all the latest content.

At the top of the page is a box in which you’ll find a link to set up the subscription.

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3. Click on Subscribe to this feed

• A pop-up Subscribe to this feed asks if you want to subscribe to LandWISE

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4. Click Subscribe and a Feed called PageBloomer will be added to your favorites

5. Check your favorite feed regularly for Page Bloomer Associates updates or to quickly search our postings. You can search here by categories too.

Latest News

We have just updated our website and are now using postings as well as static pages. We have introduced the ability for readers to post comments and hope you’ll use the site for discussion.  One key hope is that this will help improve the quality of resources we provide here. 

As always, let us know of glitches or other problems.