AGRICULTURAL SPRAYING DEVICE, INTEGRATED TRACTOR SYSTEM, AND METHOD FOR CROP TREATMENT

Abstract

ABSTRACT Agricultural Spraying Device, Integrated Tractor System, and Method for Crop Treatment The present disclosure introduces an agricultural spraying device, integrated tractor system, and method for crop treatment 100 designed to enhance precision in crop treatment. The device features a modular spraying device 102 for customizable setups and a spray nozzle system 104 with variable rate technology. Integrated sensors 110, 112, and 114 monitor soil moisture, weather conditions, and crop health, while the data analytics platform 128 processes this data to provide actionable insights and predictive analytics. The automated calibration system 124 ensures accurate spray settings, supported by geospatial mapping technology 126 for field-specific treatment. The tractor integration system 120 facilitates compatibility, with the advanced engine management system 122 optimizing energy efficiency. Additional components are multi-crop treatment capability 132, eco-friendly chemical dispensing mechanism 140, chemical consumption tracking system 142, integrated IoT and connectivity features 134, drone integration features 138, and a training and support system 144.

Specification

Description:Agricultural Spraying Device, Integrated Tractor System, and Method for Crop Treatment
TECHNICAL FIELD
[0001] The present innovation relates to advanced agricultural equipment, including a spraying device, integrated tractor systems, and methodologies for precise and sustainable crop treatment.

BACKGROUND

[0002] Agriculture faces significant challenges in achieving precision, efficiency, and sustainability in crop treatment. Traditional methods for applying pesticides, herbicides, and fertilizers often result in uneven distribution, overuse, or underuse, leading to chemical runoff, soil degradation, increased costs, and reduced crop health. Farmers have typically relied on manual spraying tools or conventional tractor-mounted systems, which lack the precision needed to adapt to varying crop types and field conditions. While these systems are cost-effective and readily available, they often lead to operational inefficiencies, wastage of agrochemicals, and adverse environmental impacts, including water pollution and loss of biodiversity.

[0003] Modern advancements, such as GPS-guided machinery and remote sensing technologies, offer precision agriculture solutions. However, these options are expensive, require extensive training, and may not be compatible with small or medium-scale farming operations. Additionally, many existing agricultural spraying devices are not modular, limiting their adaptability across different crops or terrains, and they often lack integrated data-driven features for real-time decision-making.

[0004] The present invention addresses these gaps by introducing a novel agricultural spraying device and integrated tractor system that combines modularity, precision, and sustainability. The device includes a variable-rate nozzle system, integrated sensor technologies, and geospatial mapping capabilities to ensure precise chemical application tailored to crop and field-specific needs. Its compatibility with a wide range of tractors and existing farm management software allows seamless integration into existing operations. The invention emphasizes sustainability through eco-friendly methodologies, such as integrated pest management (IPM) and reduced chemical usage, while incorporating advanced features like automated calibration, real-time feedback, and predictive analytics.

[0005] The innovation's novelty lies in its comprehensive approach-offering modularity, real-time adaptability, and sustainability features in a cost-effective system. It empowers farmers to enhance productivity, minimize environmental impact, and reduce operational costs, addressing the critical challenges of modern agriculture.

OBJECTS OF THE INVENTION

[0006] The primary object of the invention is to enhance precision in crop treatment by providing a modular spraying device with real-time adaptability to varying field conditions and crop types.

[0007] Another object of the invention is to reduce environmental impact by incorporating sustainable application techniques, such as variable rate nozzles and integrated pest management (IPM) methodologies.

[0008] Another object of the invention is to minimize chemical wastage and runoff through advanced sensor technologies that optimize the application of agrochemicals based on real-time data.

[0009] Another object of the invention is to improve operational efficiency by offering compatibility with a wide range of tractors and seamless integration with existing farm management software.

[00010] Another object of the invention is to reduce labor intensity and increase ease of use through an automated calibration system and a user-friendly control interface accessible via mobile devices.

[00011] Another object of the invention is to promote sustainability by incorporating features like energy-efficient operation, regenerative agriculture support, and eco-friendly chemical dispensing mechanisms.

[00012] Another object of the invention is to provide farmers with actionable insights through advanced data analytics and predictive algorithms, enhancing crop health and yield.

[00013] Another object of the invention is to ensure safety during operation by including protective shields, automatic shut-off mechanisms, and compliance with industry safety standards.

[00014] Another object of the invention is to enhance adaptability and efficiency in agricultural practices by enabling multi-crop treatment capability and geospatial mapping integration for targeted applications.

[00015] Another object of the invention is to empower farmers with educational resources and training programs, ensuring effective adoption of innovative agricultural techniques and data-driven decision-making.

SUMMARY OF THE INVENTION

[00016] In accordance with the different aspects of the present invention, agricultural spraying device, integrated tractor system, and method for crop treatment is presented. The invention relates to a modular agricultural spraying device, integrated tractor system, and crop treatment method that enhance precision, efficiency, and sustainability in agriculture. It features advanced variable-rate nozzles, integrated sensors, and a user-friendly control interface for real-time, data-driven chemical application. The system minimizes chemical waste, reduces environmental impact, and supports sustainable farming practices like integrated pest management (IPM). Its compatibility with various tractors and existing farm management software ensures seamless integration into diverse agricultural operations. This innovative solution empowers farmers to optimize crop health, improve yields, and promote environmentally responsible agriculture.

[00017] Additional aspects, advantages, features and objects of the present disclosure would be made apparent from the drawings and the detailed description of the illustrative embodiments constructed in conjunction with the appended claims that follow.

[00018] It will be appreciated that features of the present disclosure are susceptible to being combined in various combinations without departing from the scope of the present disclosure as defined by the appended claims.

BRIEF DESCRIPTION OF DRAWINGS
[00019] The summary above, as well as the following detailed description of illustrative embodiments, is better understood when read in conjunction with the appended drawings. For the purpose of illustrating the present disclosure, exemplary constructions of the disclosure are shown in the drawings. However, the present disclosure is not limited to specific methods and instrumentalities disclosed herein. Moreover, those in the art will understand that the drawings are not to scale. Wherever possible, like elements have been indicated by identical numbers.

[00020] Embodiments of the present disclosure will now be described, by way of example only, with reference to the following diagrams wherein:

[00021] FIG. 1 is component wise drawing for agricultural spraying device, integrated tractor system, and method for crop treatment.

[00022] FIG 2 is working methodology of agricultural spraying device, integrated tractor system, and method for crop treatment.

DETAILED DESCRIPTION

[00023] The following detailed description illustrates embodiments of the present disclosure and ways in which they can be implemented. Although some modes of carrying out the present disclosure have been disclosed, those skilled in the art would recognise that other embodiments for carrying out or practising the present disclosure are also possible.

[00024] The description set forth below in connection with the appended drawings is intended as a description of certain embodiments of agricultural spray device, tractor, tools and method for crop treatment and is not intended to represent the only forms that may be developed or utilised. The description sets forth the various structures and/or functions in connection with the illustrated embodiments; however, it is to be understood that the disclosed embodiments are merely exemplary of the disclosure that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimised to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.

[00025] While the disclosure is susceptible to various modifications and alternative forms, specific embodiment thereof has been shown by way of example in the drawings and will be described in detail below. It should be understood, however, that it is not intended to limit the disclosure to the particular forms disclosed, but on the contrary, the disclosure is to cover all modifications, equivalents, and alternatives falling within the scope of the disclosure.

[00026] The terms "comprises", "comprising", "include(s)", or any other variations thereof, are intended to cover a non-exclusive inclusion, such that a setup, or system that comprises a list of components or steps does not include only those components or steps but may include other components or steps not expressly listed or inherent to such setup or system. In other words, one or more elements in a system or apparatus preceded by "comprises... a" does not, without more constraints, preclude the existence of other elements or additional elements in the system or apparatus.

[00027] In the following detailed description of the embodiments of the disclosure, reference is made to the accompanying drawings and which are shown by way of illustration-specific embodiments in which the disclosure may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the disclosure, and it is to be understood that other embodiments may be utilized and that changes may be made without departing from the scope of the present disclosure. The following description is, therefore, not to be taken in a limiting sense.

[00028] The present disclosure will be described herein below with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the description with unnecessary detail.

[00029] Referring to Fig. 1, agricultural spraying device, integrated tractor system, and method for crop treatment 100 is disclosed in accordance with one embodiment of the present invention. It comprises of modular spraying device 102, spray nozzle system with variable rate technology 104, chemical tank 106, adjustable mounting frame 108, integrated soil moisture sensors 110, weather monitoring sensors 112, crop health sensors 114, user-friendly control system 116, mobile connectivity interface 118, tractor integration system 120, advanced engine management system 122, automated calibration system 124, geospatial mapping technology 126, data analytics platform 128, safety features 130, multi-crop treatment capability 132, integrated iot and connectivity features 134, advanced machine learning algorithms 136, drone integration features 138, eco-friendly chemical dispensing mechanism 140, chemical consumption tracking system 142 and training and support system 144.

[00030] Referring to the present disclosure, the invention provides details of an agricultural spraying device, integrated tractor system, and method for crop treatment 100, designed to enhance precision, efficiency, and sustainability in farming practices. It optimizes the application of agrochemicals through features like modular spraying device 102, variable rate spray nozzle system 104, and integrated soil moisture sensors 110, enabling targeted and eco-friendly treatments. In one embodiment, the invention may include key components such as a user-friendly control system 116, automated calibration system 124, and geospatial mapping technology 126, facilitating real-time monitoring and efficient resource use. The system incorporates advanced engine management system 122 for energy-efficient operation and safety features 130 for operator protection. It also features a data analytics platform 128 to provide actionable insights and predictive analytics, along with multi-crop treatment capability 132 for diverse farming needs. Additional components such as drone integration features 138 and eco-friendly chemical dispensing mechanism 140 further enhance precision and adaptability in modern agriculture.

[00031] Referring to Fig. 1, agricultural spraying device 100 is provided with modular spraying device 102, which serves as the foundation of the system. It allows for customizable setups tailored to specific crop types and field conditions. The modular design enables easy integration with other components like spray nozzle system 104 and adjustable mounting frame 108, ensuring flexibility and efficiency. By accommodating interchangeable parts, it supports diverse farming applications and facilitates seamless maintenance. This component enhances adaptability, making it suitable for both small-scale and large-scale agricultural operations.

[00032] Referring to Fig. 1, agricultural spraying device 100 is provided with spray nozzle system with variable rate technology 104, which optimizes the delivery of agrochemicals. It adjusts the spray pattern and flow rate in real-time based on input from integrated soil moisture sensors 110 and crop health sensors 114. This feature minimizes overspray and reduces chemical wastage, ensuring precise application. The nozzle system interworks with automated calibration system 124 to ensure accurate settings for different crops and environmental conditions. It provides a key sustainability feature by reducing runoff and environmental impact.

[00033] Referring to Fig. 1, agricultural spraying device 100 is provided with chemical tank 106, which stores agrochemicals and ensures consistent supply to the spray nozzle system 104. Designed for durability, the tank supports various chemical formulations and integrates with the automated calibration system 124 to maintain the correct dosage during operation. The chemical consumption tracking system 142 monitors the volume used, providing actionable data for optimizing resource usage. This component is essential for maintaining uniform application and reducing operational downtime.

[00034] Referring to Fig. 1, agricultural spraying device 100 is provided with adjustable mounting frame 108, which enables the spraying device to attach securely to a wide range of tractors. The frame ensures stability during operation and works in conjunction with the tractor integration system 120 for easy attachment and detachment. It facilitates quick transitions between agricultural tasks and supports compatibility with geospatial mapping technology 126 for targeted applications. This feature enhances versatility and operational efficiency in diverse field conditions.

[00035] Referring to Fig. 1, agricultural spraying device 100 is provided with integrated soil moisture sensors 110, which monitor real-time soil conditions to optimize agrochemical application. These sensors provide input to the spray nozzle system 104, ensuring that chemical application is tailored to the specific needs of the soil. They also interact with the data analytics platform 128 to generate insights for improved crop management strategies. By reducing overwatering and chemical wastage, this component supports sustainable agricultural practices.

[00036] Referring to Fig. 1, agricultural spraying device 100 is provided with weather monitoring sensors 112, which measure environmental conditions such as temperature, humidity, and wind speed. These sensors work closely with spray nozzle system 104 to adjust spray patterns and flow rates based on weather data, ensuring precise and efficient application. They also integrate with the user-friendly control system 116 to provide farmers with real-time alerts about optimal spraying times. This feature helps minimize chemical drift and ensures maximum efficacy of crop treatment under varying weather conditions.

[00037] Referring to Fig. 1, agricultural spraying device 100 is provided with crop health sensors 114, which analyze crop conditions to detect signs of stress, pest infestation, or nutrient deficiency. These sensors supply critical data to the data analytics platform 128, enabling tailored agrochemical application strategies. They work in conjunction with geospatial mapping technology 126 to identify specific areas in need of treatment. By promoting targeted interventions, crop health sensors 114 help enhance yield and minimize unnecessary chemical use, supporting sustainability goals.

[00038] Referring to Fig. 1, agricultural spraying device 100 is provided with user-friendly control system 116, which allows farmers to monitor and control the spraying process remotely via mobile connectivity interface 118. The system provides real-time updates on sensor data, device performance, and chemical usage. It integrates seamlessly with farm management software and supports automated calibration system 124 to simplify operation. This component enhances usability by offering intuitive controls, real-time alerts, and centralized management of spraying activities.

[00039] Referring to Fig. 1, agricultural spraying device 100 is provided with mobile connectivity interface 118, which enables wireless communication between the spraying device and external systems. It allows farmers to access data from integrated sensors 110, 112, and 114 and adjust settings via smartphones or tablets. This interface works with the data analytics platform 128 to deliver actionable insights, ensuring timely and efficient crop treatment. By providing remote access and monitoring, it improves operational flexibility and responsiveness.

[00040] Referring to Fig. 1, agricultural spraying device 100 is provided with tractor integration system 120, which facilitates secure attachment of the spraying device to a variety of tractors. The system is designed for compatibility with compact and large-scale tractors, ensuring versatility across farming operations. It interacts with adjustable mounting frame 108 to enable quick setup and transition between tasks. By incorporating advanced engine management system 122, it also optimizes fuel efficiency and reduces greenhouse gas emissions.

[00041] Referring to Fig. 1, agricultural spraying device 100 is provided with advanced engine management system 122, which enhances energy efficiency during operation. This component reduces fuel consumption while maintaining optimal power output for the spraying device. It integrates with tractor integration system 120 and supports eco-friendly chemical dispensing mechanism 140 by ensuring consistent performance. This feature aligns with sustainability goals by lowering operational costs and minimizing environmental impact.

[00042] Referring to Fig. 1, agricultural spraying device 100 is provided with automated calibration system 124, which adjusts spray settings automatically based on data from integrated sensors 110 and 114. This system eliminates the need for manual calibration, ensuring precise application of agrochemicals. It works in conjunction with spray nozzle system 104 and geospatial mapping technology 126 to adapt to varying crop types and field conditions. This component enhances accuracy and saves time, making operations more efficient.

[00043] Referring to Fig. 1, agricultural spraying device 100 is provided with geospatial mapping technology 126, which creates detailed field maps highlighting areas requiring specific treatment. This technology integrates with crop health sensors 114 and data analytics platform 128 to deliver precise application strategies. It also supports multi-crop treatment capability 132, enabling farmers to manage diverse fields effectively. By localizing chemical application, it minimizes waste and optimizes resource use.

[00044] Referring to Fig. 1, agricultural spraying device 100 is provided with data analytics platform 128, which processes real-time and historical data from integrated sensors 110, 112, and 114. The platform provides actionable insights, predictive analytics, and post-application feedback to improve future treatments. It interacts with mobile connectivity interface 118 to ensure farmers have access to critical information on-the-go. This component enhances decision-making and supports long-term agricultural planning.

[00045] Referring to Fig. 1, agricultural spraying device 100 is provided with safety features 130, which include automatic shut-off mechanisms and protective shields to minimize operator exposure to chemicals. These features are integrated with user-friendly control system 116 to provide real-time alerts and ensure safe operation. By complying with industry safety standards, this component enhances user confidence and promotes responsible chemical handling.

[00046] Referring to Fig. 1, agricultural spraying device 100 is provided with multi-crop treatment capability 132, which allows simultaneous application of different agrochemicals to manage diverse crop types or field sections. This capability integrates with geospatial mapping technology 126 and automated calibration system 124 to ensure precise treatment. It reduces operational time and enhances efficiency, making it suitable for large-scale agricultural operations.

[00047] Referring to Fig. 1, agricultural spraying device 100 is provided with integrated IoT and connectivity features 134, which facilitate seamless data sharing and system monitoring. These features enable communication with external devices such as drones and farm management systems. They interact with mobile connectivity interface 118 to enhance operational visibility and real-time control. This component supports a comprehensive agricultural ecosystem for improved collaboration and efficiency.

[00048] Referring to Fig. 1, agricultural spraying device 100 is provided with advanced machine learning algorithms 136, which analyze real-time and historical data to refine application strategies. These algorithms integrate with data analytics platform 128 to optimize agrochemical usage and improve treatment effectiveness. By continuously learning from previous applications, this component adapts to changing conditions and enhances system performance over time.

[00049] Referring to Fig. 1, agricultural spraying device 100 is provided with drone integration features 138, which enable aerial assessments and applications in large or inaccessible fields. These features work in conjunction with geospatial mapping technology 126 to identify areas requiring treatment and guide precise interventions. This component enhances the system's versatility and precision, making it suitable for diverse agricultural landscapes.

[00050] Referring to Fig. 1, agricultural spraying device 100 is provided with eco-friendly chemical dispensing mechanism 140, which ensures low-volume, targeted application of agrochemicals. This mechanism integrates with spray nozzle system 104 and automated calibration system 124 to minimize waste and environmental impact. It supports sustainable farming practices by reducing chemical runoff and supporting the use of organic inputs.
[00051] Referring to Fig. 1, agricultural spraying device 100 is provided with chemical consumption tracking system 142, which monitors the volume of agrochemicals used during each application. This system integrates with data analytics platform 128 to provide detailed usage reports and identify optimization opportunities. By tracking consumption patterns, this component helps reduce costs and ensure efficient resource use.

[00052] Referring to Fig. 1, agricultural spraying device 100 is provided with training and support system 144, which equips farmers with best practices for using the device and interpreting data. This system integrates with user-friendly control system 116 to provide tutorials, troubleshooting support, and operational guidance. By empowering users with knowledge, it ensures effective adoption and sustainable farming practices.

[00053] Referring to Fig 2, there is illustrated method 200 for agricultural spraying device, integrated tractor system, and method for crop treatment 100. The method comprises:
At step 202, method 200 includes user attaching the modular spraying device 102 to the tractor using the adjustable mounting frame 108 and tractor integration system 120;
At step 204, method 200 includes the user activating the advanced engine management system 122 to ensure energy-efficient operation of the tractor and spraying device 102;
At step 206, method 200 includes weather monitoring sensors 112 and soil moisture sensors 110 collecting real-time environmental and field data;
At step 208, method 200 includes crop health sensors 114 analyzing crop conditions to detect stress levels, pest infestations, or nutrient deficiencies;
At step 210, method 200 includes the collected data from sensors 110, 112, and 114 being processed by the data analytics platform 128 to determine optimal application rates and areas;
At step 212, method 200 includes user accessing the control system 116 via mobile connectivity interface 118 to review application recommendations and make adjustments if needed;
At step 214, method 200 includes automated calibration system 124 adjusting spray nozzle system 104 settings based on real-time data and environmental conditions;
At step 216, method 200 includes spray nozzle system 104 applying agrochemicals stored in the chemical tank 106 with precise flow rates to targeted areas identified by geospatial mapping technology 126;
At step 218, method 200 includes chemical consumption tracking system 142 monitoring the volume of agrochemicals used during the application and updating the data analytics platform 128 for future optimization;
At step 220, method 200 includes safety features 130 ensuring operator safety during spraying operations by activating protective shields and automatic shut-off mechanisms when necessary;
At step 222, method 200 includes multi-crop treatment capability 132 enabling simultaneous application of multiple agrochemicals to different crop types or field sections;
At step 224, method 200 includes drone integration features 138 conducting aerial assessments of treated fields to verify application accuracy and identify areas needing further attention;
At step 226, method 200 includes eco-friendly chemical dispensing mechanism 140 minimizing chemical runoff and supporting sustainability goals during application;
At step 228, method 200 includes post-application feedback from the data analytics platform 128 being shared with the user via control system 116 for continuous improvement in crop treatment strategies;
At step 230, method 200 includes training and support system 144 guiding the user on best practices for data interpretation and optimizing future spraying operations.
At step 232, method 200 includes integrated IoT and connectivity features 134 facilitating seamless data sharing between sensors 110, 112, 114, and external devices, enabling enhanced real-time monitoring and control;
At step 234, method 200 includes advanced machine learning algorithms 136 analyzing historical and real-time data from the data analytics platform 128 to refine future application strategies and optimize chemical usage;
[00054] The invention finds application in modern agricultural practices by enhancing precision, efficiency, and sustainability in crop treatment. It is particularly beneficial for optimizing the application of agrochemicals such as pesticides, herbicides, and fertilizers, thereby reducing waste and minimizing environmental impact. By integrating components like the modular spraying device 102 and spray nozzle system 104, the invention ensures targeted and precise chemical application tailored to specific crop and field conditions. Features such as the automated calibration system 124 and integrated sensors 110, 112, and 114 enable real-time decision-making, ensuring that chemicals are applied only where needed. Additionally, components like the data analytics platform 128 and geospatial mapping technology 126 provide actionable insights and field-specific treatment strategies, further improving resource utilization. The eco-friendly chemical dispensing mechanism 140 and safety features 130 contribute to sustainability and operator safety, aligning with responsible farming practices. The invention's adaptability, supported by the tractor integration system 120 and multi-crop treatment capability 132, makes it suitable for diverse farming operations, ensuring higher yields, reduced operational costs, and better environmental stewardship.

[00055] In the description of the present invention, it is also to be noted that, unless otherwise explicitly specified or limited, the terms "fixed" "attached" "disposed," "mounted," and "connected" are to be construed broadly, and may for example be fixedly connected, detachably connected, or integrally connected, either mechanically or electrically. They may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

[00056] Modifications to embodiments of the present disclosure described in the foregoing are possible without departing from the scope of the present disclosure as defined by the accompanying claims. Expressions such as "including", "comprising", "incorporating", "have", "is" used to describe and claim the present disclosure are intended to be construed in a non- exclusive manner, namely allowing for items, components or elements not explicitly described also to be present. Reference to the singular is also to be construed to relate to the plural where appropriate.

[00057] Although embodiments have been described with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More particularly, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the present disclosure, the drawings and the appended claims. In addition to variations and modifications in the component parts and/or arrangements, alternative uses will also be apparent to those skilled in the art.

, Claims:WE CLAIM:
1. An agricultural spraying device, integrated tractor system, and method for crop treatment 100 comprising of
modular spraying device 102 to provide the foundation for customizable crop treatment setups;
spray nozzle system 104 to enable precise and adjustable application of agrochemicals; chemical tank 106 to store agrochemicals for consistent supply during operation;
adjustable mounting frame 108 to securely attach the spraying device to various tractor models;
soil moisture sensors 110 to monitor real-time soil conditions for optimized application; weather monitoring sensors 112 to collect environmental data for adjusting spraying parameters;
crop health sensors 114 to analyze crop conditions and detect stress or deficiencies;
user-friendly control system 116 to facilitate easy monitoring and control of spraying operations;
mobile connectivity interface 118 to enable remote access and real-time system adjustments;
tractor integration system 120 to ensure compatibility with different tractors and easy attachment;
advanced engine management system 122 to optimize fuel efficiency and reduce emissions;
automated calibration system 124 to adjust spray settings automatically for precise application;
geospatial mapping technology 126 to create field-specific maps for targeted treatment;
data analytics platform 128 to process real-time and historical data for actionable insights;
safety features 130 to protect the operator during spraying operations;
multi-crop treatment capability 132 to allow simultaneous application of different agrochemicals;
integrated iot and connectivity features 134 to facilitate seamless data sharing and system monitoring;
advanced machine learning algorithms 136 to refine application strategies based on real-time and historical data;
drone integration features 138 to conduct aerial assessments and improve application accuracy;
eco-friendly chemical dispensing mechanism 140 to minimize chemical runoff and environmental impact;
chemical consumption tracking system 142 to monitor and optimize the use of agrochemicals; and
training and support system 144 to provide guidance on best practices and data interpretation.

2. The agricultural spraying device, integrated tractor system, and method for crop treatment 100 as claimed in claim 1, wherein the modular spraying device 102 is configured with a customizable design that allows for interchangeable components, enabling precise adaptation to varying crop types, field conditions, and operational requirements for enhanced versatility and efficiency.

3. The agricultural spraying device, integrated tractor system, and method for crop treatment 100 as claimed in claim 1, wherein the spray nozzle system 104 is configured with variable rate technology to dynamically adjust spray patterns and flow rates in real-time based on sensor input, ensuring precise agrochemical application and minimizing wastage and environmental impact.

4. The agricultural spraying device, integrated tractor system, and method for crop treatment 100 as claimed in claim 1, wherein integrated sensors 110, 112, and 114 are configured to monitor soil moisture, weather conditions, and crop health, providing real-time data for optimizing agrochemical application, reducing chemical usage, and improving crop yield.

5. The agricultural spraying device, integrated tractor system, and method for crop treatment 100 as claimed in claim 1, wherein the data analytics platform 128 is configured to process real-time and historical sensor data, generate actionable insights, and provide predictive analytics for field-specific treatment strategies, enhancing decision-making and operational efficiency.

6. The agricultural spraying device, integrated tractor system, and method for crop treatment 100 as claimed in claim 1, wherein the automated calibration system 124 is configured to adjust spray settings automatically based on real-time environmental and crop-specific data, ensuring precise and accurate agrochemical delivery without manual intervention.

7. The agricultural spraying device, integrated tractor system, and method for crop treatment 100 as claimed in claim 1, wherein geospatial mapping technology 126 is configured to create detailed field-specific maps, identifying targeted areas for treatment based on historical data and real-time conditions, enabling precise resource allocation and application.
8. The agricultural spraying device, integrated tractor system, and method for crop treatment 100 as claimed in claim 1, wherein multi-crop treatment capability 132 is configured to enable simultaneous application of multiple agrochemicals tailored to different crop types or field sections, improving efficiency and reducing operational time.

9. The agricultural spraying device, integrated tractor system, and method for crop treatment 100 as claimed in claim 1, wherein the eco-friendly chemical dispensing mechanism 140 is configured to deliver low-volume, targeted applications of agrochemicals, reducing chemical runoff and environmental impact while supporting sustainable farming practices.

10. The agricultural spraying device, integrated tractor system, and method for crop treatment 100 as claimed in claim 1, wherein method comprises of
sensor suite 102 attaching the modular spraying device 102 to the tractor using the adjustable mounting frame 108 and tractor integration system 120;
advanced engine management system 122 ensuring energy-efficient operation of the tractor and spraying device 102;
weather monitoring sensors 112 and soil moisture sensors 110 collecting real-time environmental and field data;
crop health sensors 114 analyzing crop conditions to detect stress levels, pest infestations, or nutrient deficiencies;
collected data from sensors 110, 112, and 114 being processed by the data analytics platform 128 to determine optimal application rates and areas;
user accessing the control system 116 via mobile connectivity interface 118 to review application recommendations and make adjustments if needed;
automated calibration system 124 adjusting spray nozzle system 104 settings based on real-time data and environmental conditions;
spray nozzle system 104 applying agrochemicals stored in the chemical tank 106 with precise flow rates to targeted areas identified by geospatial mapping technology 126;
chemical consumption tracking system 142 monitoring the volume of agrochemicals used during the application and updating the data analytics platform 128 for future optimization;
safety features 130 ensuring operator safety during spraying operations by activating protective shields and automatic shut-off mechanisms when necessary;
multi-crop treatment capability 132 enabling simultaneous application of multiple agrochemicals to different crop types or field sections;
drone integration features 138 conducting aerial assessments of treated fields to verify application accuracy and identify areas needing further attention;
eco-friendly chemical dispensing mechanism 140 minimizing chemical runoff and supporting sustainability goals during application;
post-application feedback from the data analytics platform 128 being shared with the user via control system 116 for continuous improvement in crop treatment strategies;
training and support system 144 guiding the user on best practices for data interpretation and optimizing future spraying operations;
integrated IoT and connectivity features 134 facilitating seamless data sharing between sensors 110, 112, 114, and external devices, enabling enhanced real-time monitoring and control;
advanced machine learning algorithms 136 analyzing historical and real-time data from the data analytics platform 128 to refine future application strategies and optimize chemical usage.

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