Smart Watering Advanced Settings – Orbit Community (2024)

Welcome to B-hyve Advanced Settings. This is the perfect place to learn how Smart Watering works, discover ways to save even more water, and achieve the best possible results for your landscape.

Most of the Advanced Settings can be changed using the standard Smart Watering Settings, but two settings – Efficiency and Management Allowed Depletion – can only be changed here in Advanced Settings.

Only four Advanced Settings actually affect the total amount of water used during a season, and these deserve the greatest understanding, focus and effort in order to optimize both plant performance and water conservation:

  • Application Rate (AR)
  • Efficiency (E)
  • Plant Factor (KP)
  • Microclimate Factor (KMC)

The remaining Advanced Settings simply affect how often or how long watering occurs in a given day or cycle. Adjusting them may affect plant performance, but will not change the total amount of water used in a season.

Editable Settings

Application Rate (AR)
The amount of water applied per hour and expressed as inches per hour. Application rates for nozzles and emitters vary widely depending on the type, brand and installation parameters so it is important to evaluate your unique system. The most reliable way to measure Application Rate is to perform a catch cup test. The more cups used in the test the more accurate the measurement, but even a test with just a few cups will improve scheduling efficiency. Changing the Sprinkler Type setting will change this value. Performing a catch cup test will also change this value and will override the Sprinkler Type default setting with the more accurate data.

  • increase: Decreases the total runtime per dayand total water used; may also decrease the number of watering cycles depending on Maximum Runtime.
  • decrease: Increases the total runtime per dayand total water used; may also increase the number of watering cycles depending on Maximum Runtime.

Efficiency (E)
Efficiency measures the ability of an irrigation system to apply water efficiently and uniformly to a zone, and it is one of the most important factors in water conservation. Causes of low water application efficiency include overwatering, evaporation, wind drift, and poor application uniformity. Application uniformity is a measure of the variation in water applied to locations within a zone. A simple catch cup test performed in a zone will identify opportunities to improve uniformity. By making equipment adjustments to reduce water in cups with abnormally high volumes and to increase water in cups with abnormally low volumes, measurable improvements in uniformity and overall efficiency can be achieved. Target Efficiency is 75% for sprays and rotors and 95% for drip. This value can only be changed in Advanced Settings.

  • increase: Decreases the total runtime per dayand total water used; may also decrease the number of watering cycles depending on Maximum Runtime.
  • decrease: Increases the total runtime per dayand total water used; may also increase the number of watering cycles depending on Maximum Runtime.

Plant Factor (KPor KC)
The fraction of Reference Evapotranspiration (ETo) required for acceptable plant appearance. When multiplied by Reference Evapotranspiration, the Plant Factor and Microclimate Factor estimate the depth of water required by plants. Typical plant factors are 0.8 for cool season turf and annual flowers, 0.7 for humid-climate perennials, shrubs and trees, 0.6 for dry-climate perennials, shrubs and trees, 0.6 for warm season turf and 0.3 for desert plants. In zones with plants having more than one Plant Factor, best management practice is to schedule according to the plant with the highest factor. Changing the Plant Type setting will change this value.

  • increase: Increases the total runtime per dayand total water used; may also increase the number of watering cycles depending on Maximum Runtime.
  • decrease: Decreases the total runtime per dayand total water used; may also decrease the number of watering cycles depending on Maximum Runtime.

Microclimate Factor (KMC)
Site-specific environmental factors such as buildings, pavement, and trees create unique sunlight and temperature variations which in turn affect the rate at which plants in a zone use water. When multiplied by Reference Evapotranspiration, the Plant Factor and Microclimate Factor estimate the depth of water required by plants. Full sun means the zone receives sun all day long. Part shade means the zone receives less than six hours of direct sun. Full shade means the zone receives little or no direct sun. Typical microclimate factors are 1.00 for full sun, 0.75 for part shade, and 0.50 for full shade. Where a zone gets too much water, adjust the Microclimate Factor down incrementally to create shorter runtimes. When a zone is too dry, increase the Microclimate Factor to increase the amount of water applied to the zone. Changing the Sun/Shade setting will change this value.

  • increase: Increases the total runtime per dayand total water used; may also increase the number of watering cycles depending on Maximum Runtime.
  • decrease: Decreases the total runtime per dayand total water used; may also decrease the number of watering cycles depending on Maximum Runtime.

Management Allowed Depletion (MAD)
The soil water content deficit percentage at the time of next watering. The B-hyve will water before this percentage of Plant Available Water is depleted from the soil, unless water restrictions are in place which prevent watering. Adjusting Management Allowed Depletion is a helpful way to increase or decrease intervals between watering days. 50% is a smart allowed depletion for most soil types. Sandy soils could be as high as 60%. Clay soils could be as low as 40%. This value can only be changed in Advanced Settings.

  • increase: Increases the intervals between watering days and increases the total runtime per day; may also increase the number of watering cycles depending on Maximum Runtime.
  • decrease: Decreases the intervals between watering days and decreases the total runtime per day; may also decrease the number of watering cycles depending on Maximum Runtime.

Field Capacity (FC)
Percentage soil water content in the Root Zone after gravity drainage is complete. In sandy soils the larger pores drain quickly and gravity drainage may take just a few hours. In clay soils gravity drainage may take two to three days. Smart Watering refills soil water content to a maximum of Field Capacity which minimizes wasted water due to gravity drainage. The percentage of soil water content at Field Capacity is generally 10 to 20% for sandy soils, 20 to 30% for loam soils, and 30 to 40% for clay soils. Changing the Soil Type setting will change this value.

  • increase: Increases the intervals between watering days and increases the total runtime per day; may increase the number of watering cycles depending on Maximum Runtime.
  • decrease: Decreases the intervals between watering days and decreases the total runtime per day; may decrease the number of watering cycles depending on Maximum Runtime.

Permanent Wilting Point (PWP)
Percentage soil water content in the Root Zone when the plant irreversibly loses internal pressure.. Typical soil water content at Permanent Wilting Point is 5 to 10% for sandy soils, 10 to 15% for loam soils, and 15 to 30% for clay soils. Clay has higher moisture content at Permanent Wilting Point because water holds tightly to fine soil particles. Smart Watering ensures that watering occurs far enough above Permanent Wilting Point that plants do not experience undue stress. Changing the Soil Type setting will change this value.

  • increase: Decreases the intervals between watering days and decreases the total runtime per day; may decrease the number of watering cycles depending on Maximum Runtime.
  • decrease: Increases the intervals between watering days and increases the total runtime per day; may increase the number of watering cycles depending on Maximum Runtime.

Root Zone (RZ)
Effective root depth which is generally considered the top 50% of the maximum root depth. Typical Root Zone is 4-6 inches for annual flowers and ground covers, 4-8 inches for cool season turf, 6-12 inches for shrubs and warm season turf, and 12-24 inches for trees. In the case of new plants with undeveloped root zones, it often makes sense to set the Root Zone at a “target” depth which encourages roots to expand downward. Changing the Plant Type setting will change this value.

  • increase: Increases the intervals between watering days and increases the total runtime per day; may also increase the number of watering cycles depending on Maximum Runtime.
  • decrease: Decreases the intervals between watering days and decreases the total runtime per day; may also decrease the number of watering cycles depending on Maximum Runtime.

Allowable Surface Accumulation (ASA)
Free standing water which forms on top of the soil surface by application rates that exceed soil intake rates that is generally restrained from running off by the combined effects of surface detention and the presence of the crop canopy, thatch layer, or accumulated plant waste. Allowable Surface Accumulation decreases as the amount of slope of the landscape increases and typically ranges from 0.1 to 0.4. Changing the Slope setting will change this value.

  • increase: Increases the Maximum Runtime for a zone which decreases the number of watering cycles per day, increasing the risk of runoff.
  • decrease: Decreases the Maximum Runtime for a zone which increases the number of watering cycles per day, decreasing the risk of runoff.

Basic (Steady) Infiltration Rate (BIR)
A measurement of the depth of the water layer that can enter the soil in one hour. In dry soil, water infiltrates rapidly. This is the initial infiltration rate. As more water replaces the air in the pores the water from the soil surface infiltrates more slowly and eventually reaches a steady rate. This is the Basic Infiltration Rate (BIR). The Basic Infiltration Rate depends on soil texture (the size of the soil particles) and soil structure (the arrangement of the soil particles). Typical basic infiltration rates range from 0.1 for clay soils to 0.6 for sandy soils. Changing the Soil Type setting will change this value.

  • increase: Increases the Maximum Runtime for a zone which decreases the number of watering cycles per day, increasing the risk of runoff.
  • decrease: Decreases the Maximum Runtime for a zone which increases the number of watering cycles per day, decreasing the risk of runoff.

Computed Non-Editable Settings

Available Water (AW)
Total inches of water per inch of soil between Field Capacity and Permanent Wilting Point. AW = FC – PWP

Field Capacity Depth (FCD)
Total inches of water in the Root Zone after gravity drainage. FCD = FC x RD

Permanent Wilting Point Depth (PWPD)
Total inches of water in the Root Zone when the plant irreversibly loses internal pressure. PWPD = PWP x RD

Plant Available Water (PAW)
Total inches of Available Water in the Root Zone. PAW = FCD – PWPD or AW x RZ

Readily Available Water (RAW)
Total inches of water readily available to the plant at Field Capacity. As soil water content decreases osmotic pressure decreases and water becomes less and less available to the plant. Readily Available Water is Management Allowed Depletion expressed in inches of water. RAW = PAW x MAD

Refill Point (RP)
Total inches of soil water content at which Readily Available Water is fully depleted. In the absence of water restrictions next watering will occur at or above this point so that the plants do not experience stress. RP = FC – RAW

Standard Runtime (STDRT)
Measurement of how long a zone must water in order to refill the soil water content from the Refill Point (0% Readily Available Water) to Field Capacity (100% Readily Available Water). STDRT = (RAW / AR) x SM (or divided by E if not using Scheduling Multiplier)

Maximum Runtime Before Runoff (MAXRT)
Measurement of how long a zone can water before runoff starts to occur. Runoff represents wasted water since it does not reach the intended Root Zone of the plants. To minimize runoff Smart Watering divides the total runtime equally into cycles that are shorter than the Maximum Runtime which is why a zone may water more than one time in a day. MAXRT = (60 x ASA) / (AR-BIR)

Reference Evapotranspiration (ETo)
Estimate of total water use for uniform surface of dense actively growing vegetation similar to clipped cool season turf, with approximate height of 0.12 meter, not short of water, and representative of a large expanse of same or similar vegetation.

Landscape Coefficient (KL)
Factor that represents the combined effect of Plant Factor and Microclimate Factor on the landscape water requirement. KL= KPx KMC.

Landscape Evapotranspiration (ETL)
Estimate of total water use for a specific plant type in a specific microclimate. ETL= ETOx KL.

Current Moisture Balance (MBC)
Soil water content in the Root Zone, expressed in inches of water, that is readily available for use by plants. Current Moisture Balance decreases between 09:00 and 21:00 local time at the rate of Landscape Evapotranspiration, reflecting the fact that most plant water use occurs during daylight hours. Between 21:00 and 09:00 any Effective Rainfall (RE) and Effective Irrigation (IE) which occurred during the past 24 hours are added to the Current Moisture Balance, establishing the Initial Moisture Balance for the new day (MBI). The soil moisture bubble in Smart Watering shows the Current Moisture Balance in percentage terms ranging from full (100% Readily Available Water) to empty (0% Readily Available Water). MBC= MBI– ETL+ RE+ IE

For information on how to adjust your smart watering schedule please clickhere

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Tags: advanced, advanced-settings, app, b-hyve, bhyvesmart-watering

Smart Watering Advanced Settings – Orbit Community (2024)

FAQs

How to adjust smart watering on B-hyve? ›

To enable/disable Watering Restrictions

From the “My B-hyve” screen press the “Devices” menu option. From the “Devices” screen select the Timer you want to set watering restrictions for. Unless otherwise enabled during the initial setup Watering Restrictions will be turned off.

What does smart watering mean on B-hyve? ›

Timer Smart Watering allows the controller to act on a rain delay based on predicted rain event using standard controller station programming.

How does smart watering work on a beehive? ›

For example, as long as your B-hyve timer is properly connected to the internet and the forecast for your timer's location is at a certain percentage toward rain, your timer will automatically receive a Rain Delay and delay any Smart Watering Programs from running during the specified Rain Delay.

What is the difference between B-hyve and B-hyve pro? ›

We created B-hyve Pro specifically for professionals' needs. Instead of cramming everything into the B-hyve app, we decided that professional irrigators deserve their own dedicated app tailored to their requirements.

What is the best watering schedule? ›

The best time to water is in the early morning hours. Allow 30 to 60 minutes between watering cycles so water has a chance to soak in the soil. The heavier the soil, the longer the soak time needed. As water needs increase, don't add time to the cycles, or you will get runoff.

How does a smart watering system work? ›

The smart technology uses local weather data or real-time sensors to adjust watering duration and amounts based on rainfall, temperature, humidity, or soil moisture.

How close should water be to beehives? ›

The best place for beehives is within 100 feet maximum of water. Bees don't prioritize water sources, so the closest source becomes THE source. Water is needed for consumption, mating, and temperature control. Water quality generally only matters if the water is contaminated with pesticides.

Will B-hyve work without WiFi? ›

Typically smart watering will create programs up to 2-weeks out, and can continue to run these created programs as long as the timer is not connected to WiFi. While your controller is offline, you will not be able to control it remotely from the app through WiFi.

What is the best watering system for bees? ›

Bees are small and drown easily, so using a shallow dish filled with rocks or marbles is ideal. Just keep the water line shallower than the rocks, so the bees have a place to land. It's equally important to make sure the dish of water you're putting out for thirsty bees hasn't been contaminated with pesticides.

How to turn rain delay off on B-hyve? ›

If you want to disable the Automatic Rain Delay feature for your B-hyve timer, then these steps will show you how to do that.
  1. Open the B-hyve application.
  2. Tap My “B-hyve”
  3. Tap “Devices”
  4. Select the timer you wish to remove Automatic Rain Delay From.
  5. Turn “Smart Watering” off, on Androids this will say “Weather Delays”

How do you cancel the rain delay on orbit? ›

To remove a rain delay, press and hold the dial for 3 seconds. The rain delay icon will turn off and your timer will resume its programmed watering schedule.

How do I set up a watering schedule? ›

How to Make a Watering Schedule
  1. Choose which plants you want to include on the schedule.
  2. Decide how often you want to water each plant.
  3. Write down the watering schedule.
  4. Hang the schedule up in a place where you'll see it often.
Dec 23, 2022

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