Control cabinet air conditioning

The cabinet air conditioning or the housing air conditioning to the in cabinet built in the housing or electronic components from harmful environmental influences such as dust , moisture and temperature protection. The term is mainly used for heat dissipation measures.

Passive and active air conditioning

Passive air conditioning

Passive air conditioning is the natural heat dissipation without the aid of additional devices. When the housing is closed, the heat is dissipated through the housing walls. In the case of open housings, air is also exchanged through the air inlet and outlet openings ( natural convection , i.e. without the use of fans). The prerequisite for passive air conditioning is that the ambient temperature is lower than the desired internal temperature.

Examples of measures to improve passive air conditioning are

• Attachment of ventilation slots in the housing walls
• thermal coupling of hot components directly to the housing wall

Active air conditioning

If the passive air conditioning is not sufficient, the heat must be specifically dissipated from the housing using additional devices. For this purpose are used:

• Filter fan or roof fan
• Air / air heat exchanger
• Air / water heat exchanger
• Refrigerators

Air conditioning components

For the choice of components it is crucial whether the devices are open, i. H. breathable, or closed, d. H. are impermeable to air. While the heat in open devices can be dissipated via an air stream, in closed devices it is only possible through the housing walls or with the help of a heat exchanger. Whether a device is designed to be open or closed depends primarily on the degree of protection required in accordance with DIN EN 60 529: 2009-9.

Control cabinet surface

The heat dissipation through the closed control cabinet surface (passive air conditioning) depends on the type of installation of the cabinet, the heat transfer coefficient of the walls and the difference between the inside and outside temperature. The following formula is used for the estimation:

${\ displaystyle Q = U \ cdot A \ cdot (T_ {i} -T_ {u})}$

Q: heat emission of the cabinet surface (in W)

U: heat transfer coefficient (in W / (m ² K))

A: effective cabinet surface (in m ² )

${\ displaystyle T_ {i}}$: Internal housing temperature (in ° C)

${\ displaystyle T_ {u}}$: Outside temperature (in ° C)

This formula does not take into account the temperature and air flow distribution in the cabinet, it only uses an indoor and an outdoor temperature and a general value for the heat transfer coefficient. It is therefore only suitable for a general estimate. Methods of numerical flow simulation are used for more precise calculation of the temperature and air flow distribution in a control cabinet .

Heat transfer coefficients of common control cabinet walls:

• Painted sheet steel: U = 5.5 W / (m ² K)
• Stainless steel sheet: U = 4.5 W / (m ² K)
• Aluminum: U = 12.0 W / (m ² K)
• Double-walled aluminum: U = 4.5 W / (m ² K)
• Polyester: U = 3.5 W / (m ² K)

Effective control cabinet surface

The type of installation of the cabinet is taken into account with the effective control cabinet surface. A housing that is free on all sides in a room can give off more heat than a device that is set up on a wall or in a niche. The formulas for calculating the effective cabinet surface area are specified in DIN VDE 0660 Part 500.

Housing installation type according to DIN VDE 0660 part 500	Calculation formula for the effective control cabinet surface
Single housing free-standing on all sides	${\ displaystyle A = 1 {,} 8 \ cdot H \ cdot (B + T) +1 {,} 4 \ cdot B \ cdot T}$
Single housing for wall mounting	${\ displaystyle A = 1 {,} 4 \ cdot B \ cdot (H + T) +1 {,} 8 \ cdot T \ cdot H}$
Start-end housing free-standing	${\ displaystyle A = 1 {,} 4 \ cdot T \ cdot (H + B) +1 {,} 8 \ cdot B \ cdot H}$
Start-end housing for wall mounting	${\ displaystyle A = 1 {,} 4 \ cdot H \ cdot (B + T) +1 {,} 4 \ cdot B \ cdot T}$
Middle housing free-standing	${\ displaystyle A = 1 {,} 8 \ times B \ times H + 1 {,} 4 \ times B \ times T + T \ times H}$
Middle housing for wall mounting	${\ displaystyle A = 1 {,} 4 \ cdot B \ cdot (H + T) + T \ cdot H}$
Middle housing for wall mounting with covered roof area	${\ displaystyle A = 1 {,} 4 \ times B \ times H + 0 {,} 7 \ ​​times B \ times T + T \ times H}$
	B = switch cabinet width H = switch cabinet height T = switch cabinet depth

Examples

A free-standing, closed switch cabinet with steel walls, with the dimensions (height × width × depth) of 2.2 m × 0.6 m × 0.6 m, which is set up in a room with a temperature of 20 ° C and its middle Inside temperature is 40 ° C, it emits the following heat output through its walls:

${\ displaystyle Q = 5 {,} 5 \, \ mathrm {W / (m ^ {2} K)} \ cdot 5 {,} 256 \, \ mathrm {m} ^ {2} \ cdot (40 \, ^ {\ circ} \ mathrm {C} -20 \, ^ {\ circ} \ mathrm {C}) = 578 {,} 16 \, \ mathrm {W}}$

If the same cabinet is placed in the middle of a row of cabinets, its heat output is lower:

${\ displaystyle Q = 5 {,} 5 \, \ mathrm {W / (m ^ {2} K)} \ cdot 4 {,} 200 \, \ mathrm {m} ^ {2} \ cdot (40 \, ^ {\ circ} \ mathrm {C} -20 \, ^ {\ circ} \ mathrm {C}) = 462 {,} 00 \, \ mathrm {W}}$

Filter fan

Control cabinet with filter fan (at the bottom of the door)

The filter fans are a cost-effective option for active control cabinet air conditioning . The precondition for their use is that the control cabinet environment is relatively clean. The ambient temperature must be below the desired internal cabinet temperature.