5 inverter/converter cooling design, 1 temperature rise within the control panel – Yaskawa Varispeed 626M5 User Manual

15.5 Inverter/Converter Cooling Design

15 -23

15.5 Inverter/Converter Cooling Design

If the Inverter/Converter is built into the panel, be sure to mount it vertically for effective cooling, and make

sure there is sufficient space to both the sides, and top and bottom, in consideration of maintenance and ventila-

tion, as shown in Fig. 2.9 and Fig. 2.10. (Refer to 2.3 CLEARANCES for details.) There are two Inverter/Con-

verter models: External heatsink cooling models for the fully-enclosed control board mounting, and models

mounted inside the panel, which house the whole unit in the control panel. The external heatsink cooling model

cools the majority of generated loss from the unit using external air directly, so the generated loss in the control

panel is reduced.
The maximum operating temperature of the Inverter/Converter is 55_C. Design the cooling system so that the

average temperature rise within the control panel is 10 K (10°C (50°F)) max., taking the maximum control pan-

el ambient temperature to be 40°C (103°F). Consequently, heat caused by the generated loss of the Inverter must

be discharged using forced air currents and a heat exchanger. For the calorific value and cooling air speed of

each Inverter/converter by capacity, refer to 14.1.5 Calorific Value and Cooling Air Speed.

15.5.1 Temperature Rise within the Control Panel

Taking the calorific value within the panel P (W), rate of heat conduction of the metal plate k (W/m

2

⋅

°C),

and control panel surface area in contact directly with the external air A (m

2

), temperature rise within the

control panel ∆T (K) can be expressed using the following formula.

∆T

=

P

k × A

(K)

The value of k changes according to the conditions as shown below.

D

With no internal circulation fan: 4 (W/m

2

⋅

°C)

D

With internal circulation fan: 6 (W/m

2

⋅

°C)

D

Cooling air duct with forced air current (with internal circulation fan): 9 (W/m

2

⋅

°C)

The internal temperature rise ∆T (K) when using a heat exchanger can be expressed using the following

formula.

∆T

=

P

k × (A − B) + qh

qh:

Heat exchanger cooling ability (W/°C)

B:

Heat exchanger surface area (m

2

)

AIR

Air

duct

Fig 15.27 Configuration of Control Panel with Air Duct

15