We are actively engaged in offering to our customer’s supreme quality range of Anti Insect Net. The offered net is appreciated in the market for dispatching a defect free range.it is use for poly house all side cover and Shade Net house to be Covered.
If you have insect netting on hand, consider staking it around a plant or two for added protection from bad weather. A large garden with a variety of plants and flowers is always appealing, but don’t neglect some of your hardier perennials—particularly if you live in an area with extreme weather like heavy winds or hail.
The plastic mesh allows air and sunlight through but protects your plants from natural elements that might otherwise damage them. Just remember to leave enough slack so that you can get your hands into each row. You should also bring along garden clippers just in case any snags need repair while you’re out there working.
HDPE Monofilament 40 Mesh Insect Netting
|Material||PVC, Nylon, Plastic|
|Width||3, 4.2 , 5 , 5.5 , 6.2 MTR.|
|Thickness||90 Gsm / 100 Gsm / 120 Gsm|
|Minimum Order Quantity||1000 Sqm.|
|Delivery Time||Same Day|
|Port of Dispatch||Jodhpur|
|Production Capacity||50,000 Sqm.|
|Packaging Details||Large Bag’s|
|Packing Qty||1 Roll|
|Payment Mode||RTGS / NEFT / IMPS|
Use of Polyhouses in organic farming:
Polyhouses can be an effective tool for organic farmers to control and maintain optimal growing conditions for their crops. Here is a stepwise description of how polyhouses can be used in organic farming:
Step 1: Selecting the right location – Organic farmers must carefully select the location for their Polyhouse. The site should have good soil quality, access to water, and plenty of sunlight. They should also consider the wind direction and potential for pest infestations.
Step 2: Choosing the proper structure – Once the location is finalized, farmers need to choose the right type of Polyhouse structure that suits their crop and climate conditions. The system should be sturdy enough to withstand weather conditions and have good ventilation to maintain optimal temperature and humidity levels.
Step 3: Preparing the soil – The soil inside the Polyhouse must be prepared before planting. Farmers must ensure that the soil is free of pests, diseases, and weed seeds. They can use organic soil amendments like compost, manure, and organic fertilizers to enrich the soil and promote healthy plant growth.
Step 4: Planting the crop – After preparing the soil, farmers can plant their crops inside the Polyhouse. They need to ensure that the plants have enough space to grow, adequate irrigation, and proper trellising and support systems. They should also use organic pest management strategies like crop rotation, companion planting, and natural predators to control pests and diseases.
Step 5: Monitoring and managing the environment – The environment inside the Polyhouse needs to be monitored and managed regularly. Farmers should use sensors to measure temperature, humidity, and soil moisture levels. They should also adjust ventilation, shading, and irrigation systems to maintain optimal growing conditions for the crop.
Step 6: Harvesting and post-harvest management – When the crop is ready for harvest, farmers can pick and store the produce inside the Polyhouse. They should use organic post-harvest management practices like cleaning, grading, and packaging to ensure that the produce is high quality and free from contaminants.
By following these steps, organic farmers can successfully use polyhouses to grow crops and achieve higher yields with fewer inputs while also maintaining the principles of organic farming.
Impact of polyhouses on crop yields and quality:
Polyhouses can have a significant impact on crop yields and quality. Here is a stepwise description of how polyhouses can affect crop yields and quality:
Step 1: Enhanced growing conditions – Polyhouses provide a controlled environment allowing farmers to create optimal crop growth conditions. The use of polyhouses can protect crops from harsh weather conditions, pests, and diseases. The controlled environment also allows for extended growing seasons, which can result in higher yields.
Step 2: Increased yields – With the use of polyhouses, farmers can grow crops in conditions that are otherwise unsuitable for cultivation. The controlled environment enables the farmers to provide adequate irrigation, fertilization, and pest management, which can lead to higher yields than traditional farming methods.
Step 3: Improved crop quality – Polyhouses can also improve crop quality. The controlled environment allows for eliminating external factors that can negatively affect crop growth and quality. As a result, the crops grown in polyhouses are generally more uniform in size, shape, and color, which can increase their market value.
Step 4: Reduced water consumption – Polyhouses can help in reducing water consumption as the controlled environment inside the Polyhouse can prevent water evaporation. Moreover, the irrigation systems inside the Polyhouse can be designed to provide the required amount of water directly to the crops, reducing water wastage.
Step 5: Reduced use of pesticides – With the controlled environment of polyhouses, farmers can use integrated pest management strategies that minimize the use of pesticides. This results in healthier crops, better soil quality, and lower levels of pesticide residues in the produce.
Step 6: Higher economic returns – The increased yields and improved crop quality resulting from Polyhouse farming can lead to higher financial returns for farmers. In addition, this makes Polyhouse agriculture a profitable venture and can be a way for small farmers to increase their income.
Using polyhouses can significantly impact crop yields and quality by creating a controlled environment that enables optimal crop growing conditions.
Cost-benefit analysis of polyhouses:
A cost-benefit analysis can be a helpful tool for farmers to evaluate the financial feasibility of investing in polyhouses. Here is a stepwise description of how to conduct a cost-benefit analysis of polyhouses in agriculture:
- Step 1: Identify the costs – Farmers need to identify all the costs associated with setting up and maintaining a Polyhouse. This includes the cost of the structure, irrigation systems, heating and cooling systems, labor, seeds, fertilizers, and other inputs.
- Step 2: Identify the benefits – Farmers need to identify all the benefits that polyhouses can provide. Further, this includes increased yields, improved crop quality, reduced water consumption, and reduced use of pesticides.
- Step 3: Estimate the financial impact – Farmers need to estimate the financial impact of the costs and benefits. This includes estimating the increased revenue from higher yields and improved crop quality and the savings from reduced water consumption and reduced use of pesticides. They also need to factor in the costs of labor and other inputs.
- Step 4: Calculate the net present value – Farmers need to calculate the net current value (NPV) of the investment in polyhouses. This involves calculating the present value of the future cash flows resulting from the investment and subtracting the initial investment.
Step 5: Evaluate the results – Farmers need to evaluate the results of the cost-benefit analysis and determine whether the investment in polyhouses is financially feasible. They can use the results of the analysis to make informed decisions about whether to proceed with the investment.
- Step 6: Monitor and adjust – Once the investment in polyhouses is made, farmers need to monitor and adjust their operations based on the results. Further more, this includes tracking yields, quality, and costs and adjusting their operations accordingly to optimize their returns.
By conducting a cost-benefit analysis, farmers can make informed decisions about whether to invest in polyhouses and optimize their returns from their investments.