ENTRETIEN

Câble de commande de traction

1.Vider le réservoir d’essence. Basculer la souffleuse à neige sur l’avant du carter de vis sans fin.

AVERTISSEMENT : Vidanger l’essence à l’extérieur, à l’écart de feu ou de flammes.

2.Desserrer les boulons (A, Figure 28) de chaque côté du panneau inférieur (B).

3.Déposer le panneau inférieur.

4.Dégager la gaine de câble (A, Figure 29) de la ferrure de réglage de câble (B).

5.Enfoncer le bas du câble de commande de traction (C) dans la ferrure de réglage de câble jusqu’à pouvoir dégager le crochet en « Z » (D).

6.Sortir le crochet en « Z » de la ferrure de réglage de câble. Placer le crochet en « Z » dans le trou de réglage suivant.

7.Tirer le câble de commande de traction vers l’arrière de la ferrure de réglage de câble.

8.Remettre la gaine de câble sur la ferrure de réglage de câble.

9.Pour vérifier le réglage, serrer le levier de commande et observer la longueur du ressort de commande (A, Figure 30). Lorsque le réglage est correct, la longueur du ressort est de 76 mm (3 pouces) minimum à 85 mm (3-3/8 pouces) maximum.

10.Poser le panneau inférieur (B, Figure 28).

11.Serrer les boulons (A) de chaque côté du panneau inférieur.

A

B

A

C

D

B

Câble de commande de traction

Figure 29

“A”

 

 

A

Pour vérifier le réglage

Figure 30

Réglage du câble de commande de traction

Figure 28

25

Page 56 Page 58
Page 57
Image 57
Murray 1737920, 1695722 manual Câble de commande de traction
Page 56 Page 58

1737920, 1695722 specifications

Murray 1737920 and 1695722 represent two significant advancements in the realm of smart technology, particularly in the area of home automation and energy management. These devices integrate cutting-edge features designed to enhance user experience while optimizing energy efficiency.

One of the main characteristics of Murray 1737920 is its intelligent energy management system, which utilizes real-time data analytics to monitor energy consumption patterns. The device employs machine learning algorithms to intelligently predict energy requirements, allowing users to reduce waste and lower their utility bills. Additionally, it has a user-friendly interface that provides insights into energy usage, enabling homeowners to make informed decisions about their consumption.

Murray 1695722, on the other hand, focuses more on home automation and security. With built-in Wi-Fi connectivity, it allows users to control various appliances remotely through a dedicated mobile application. This feature not only enhances convenience but also allows for enhanced security by enabling users to monitor their homes in real-time. The device is equipped with motion sensors and alert systems that can notify homeowners of any unusual activity, adding an extra layer of protection.

Both devices integrate seamlessly with existing smart home ecosystems, supporting popular communication protocols such as Zigbee and Z-Wave. This compatibility allows users to expand their systems by adding other smart devices, creating a fully integrated home automation experience.

In terms of installation, both Murray models are designed to be user-friendly. They typically come with comprehensive instructions, and many features can be accessed with minimal technical knowledge. The focus on ease of use extends to their maintenance, with straightforward troubleshooting and support available through the manufacturers.

Another important feature of both devices is their commitment to sustainability. By helping families monitor and manage their energy consumption, they play a crucial role in promoting more eco-friendly practices within households. Combined, Murray 1737920 and 1695722 stand out as leaders in smart home technology, emphasizing efficiency, security, and user-centric design principles that cater to the evolving needs of modern homeowners. These innovations represent a significant step forward in creating energy-conscious and secure living environments.
Top Page Image Contents