Easy 4 Step Assembly

To view our “How to Assemble” demo, visit www.eureka.com/airspeed/assembly

 

STEP

 

 

1

 

 

Fig. 1

Alternate View

B

 

 

A

B

 

 

 

 

A

Fig. 2

 

 

 

B

 

 

A

 

Fig 1: With the back- bone (B) loosely on the base (A), rotate the backbone forward until the vaccum is locked in the upright position. Fig 2: stand as shown and push down on backbone (B) valve to snap into place. Pull up to ensure the backbone has locked properly.

STEP

STEP

STEP

2

3

4

C

Hose Retainer

B

Align so that the hose

Put dust cup (D) into

To attach hose con-

retainer on the handle

place on base. Push

nector, align tabs

(C) is facing the vacuum

cup handle toward

and lower hose onto

front. Lower the handle

backbone (B) to snap

connector. Turn clock-

(C) onto the backbone

into place.

wise to lock.

(B). Push down to snap

 

 

into place. Pull up to

 

 

ensure the handle has

 

 

locked properly.

 

 

Hose and Tool Storage

C

Hose

Retainer

E

Route hose (E)

through hose

retainer on front

of handle (C).

E

Put hose end (E) into hook at base of tool clips. Then push hose into clips.

G

Slide crevice tool

(F)into top of extension wand end (G). Place

into clips on

the side of the

vacuum.

H

Store dusting brush (H) on back of vacuum.

I

On some models:

Attach turbo

nozzle (I) to clip on handle (C).

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Eureka AS2030A manual Easy 4 Step Assembly, Hose Retainer

AS2030A specifications

The Eureka AS2030A is a state-of-the-art autonomous system designed for a variety of applications in the fields of surveillance, exploration, and data collection. Its advanced features and cutting-edge technologies set it apart in the rapidly evolving landscape of autonomous vehicles.

One of the standout features of the Eureka AS2030A is its robust navigation system. Equipped with a combination of GPS, LIDAR, and computer vision, this platform is capable of navigating complex environments with remarkable precision. The LIDAR technology allows for 360-degree scanning, creating detailed 3D maps of the surroundings, which is crucial for tasks such as obstacle detection and avoidance.

The vehicle's design also emphasizes durability. Built with lightweight yet strong materials, the AS2030A can withstand harsh environmental conditions, making it ideal for outdoor use. Its rugged construction does not compromise its agility, allowing it to maneuver through rough terrains with ease. This combination of strength and flexibility is particularly beneficial for agricultural surveys, geological exploration, and search-and-rescue operations.

Another significant characteristic of the Eureka AS2030A is its advanced data processing capabilities. With an onboard high-performance computing system, it can analyze the collected data in real-time, facilitating quick decision-making and responses to dynamic situations. This feature is especially useful in security and surveillance missions, where immediate analysis can lead to timely interventions.

The AS2030A is also designed with user-friendliness in mind. It comes with an intuitive interface that allows operators to easily control and configure the vehicle. Whether through manual operation or autonomous mission planning, users have the flexibility to customize settings according to their specific needs.

Moreover, the vehicle is equipped with multiple sensor integrations, including thermal and infrared cameras, which enhance its operational capabilities. This multi-sensor approach enables the AS2030A to perform effectively in low-light conditions and provides valuable data for diverse applications, from environmental monitoring to wildlife observation.

In terms of connectivity, the Eureka AS2030A supports various communication protocols, allowing seamless integration with other systems and devices. This feature enhances its utility in collaborative missions, where multiple units can share data and strategies in real time.

In conclusion, the Eureka AS2030A stands out with its blend of advanced navigation, robust construction, high data processing abilities, and user-oriented design. It represents a significant advancement in autonomous systems, poised to revolutionize how we approach exploration, surveillance, and data collection in various fields. Its cutting-edge technologies are set to drive innovation and efficiency in operations worldwide.