OPERATION

WARNING

Under normal usage the grass catcher material is subject to deterioration and wear, and should be frequently checked for wear or damage. Replace with a genuine Rover grass catcher if found to be damaged.

Installing the grass catcher- refer figure 3

Move the throttle control lever to the stop position and wait till the blades have come to a complete stop

Raise the rear flap of the mower with one hand and with the other hand raise and position the grass catcher against the rear of the mower.

Locate the two hooks on the front of the grass catcher frame into the slots on either side of the rear flap and over the rear flap pivot rod.

Flap rod

Slot in flap

Slot in flap

Hook

Hook

Grass catcher handle

Figure 3. Grass catcher fitment

Removing the grass catcher– refer figure 3

Move the throttle control lever to the stop position and wait till the blades have come to a complete stop

Raise the flap of the mower with one hand and with the other hand lift the grass catcher up and away from the rear of the mower.

Lower the rear flap against the rear of the mower.

WARNING

The grass catcher should only be fitted or removed when the engine is stopped. Never raise the rear flap when the engine is running

4

Page 5
Image 5
Rover 10124 Operation, Installing the grass catcher- refer figure, Removing the grass catcher- refer figure, Hook

10124 specifications

The Rover 10124 is a versatile and innovative robotic platform designed for a variety of applications ranging from industrial automation to research and development. This compact robot combines advanced technology with rugged construction, making it suitable for both indoor and outdoor environments.

One of the standout features of the Rover 10124 is its high mobility. It is equipped with all-terrain wheels, allowing it to traverse various surfaces including gravel, grass, and even uneven terrain. This characteristic makes it ideal for tasks that require agility and adaptability, such as surveying, inspection, and delivery in challenging locations.

The Rover 10124 is powered by a state-of-the-art electric propulsion system, ensuring not only high efficiency but also low operational noise. This energy-efficient system allows for extended run times and minimizes the need for frequent recharging, making it practical for long-duration tasks. Additionally, the robot features regenerative braking, which helps in conserving battery life during operations.

In terms of technology, the Rover 10124 incorporates a sophisticated array of sensors that enhance its navigational capabilities. These include LiDAR, ultrasonic sensors, and cameras, enabling the robot to create detailed maps of its surroundings and detect obstacles in real-time. This suite of sensing technology supports autonomous navigation, allowing the Rover to adapt to its environment without human intervention.

User-friendliness is also a hallmark of the Rover 10124. It comes with an intuitive control interface that can be operated remotely via a mobile application or a desktop computer. The interface provides users with real-time feedback and control over the robot’s movements and operations. Furthermore, programmable APIs allow developers to customize the Rover's functionalities for specific applications, promoting user innovation.

Robustness is another key characteristic of the Rover 10124. With its durable chassis and protective casing, the robot is designed to withstand rough handling and exposure to various weather conditions. This resilience is essential for use in fields such as construction, agriculture, and disaster response, where reliability is paramount.

Overall, the Rover 10124 stands out as a dynamic and capable robotic solution. Its combination of mobility, advanced technology, user-friendly interface, and durability makes it a valuable asset across multiple industries, paving the way for increased automation and improved operational efficiency.