Penetrations
[Fig. 9.4.4] (P.4)
<A> Inner wall (concealed) | <B> Outer wall |
<C> Outer wall (exposed) | <D> Floor (waterproofing) |
<E> Roof pipe shaft
<F> Penetrating portion on fire limit and boundary wall
A Sleeve | B Heat insulating material | ||
C Lagging | D Caulking material | ||
E | Band | F | Waterproofing laye |
G | Sleeve with edge | H | Lagging material |
IMortar or other incombustible caulking
JIncombustible heat insulation material
When filling a gap with mortar, cover the penetration part with steel plate so that the insulation material will not be caved in. For this part, use incombustible materi- als for both insulation and covering. (Vinyl covering should not be used.)
•Insulation materials for the pipes to be added on site must meet the following specifications:
| Pipe size | ||
| ø6.35 ~ 25.4 mm | ø28.58 ~ 38.1 mm | |
| [1/4 to 1 in] | ||
|
|
| |
Thickness | 10 mm min. | 15 mm min. | |
[13/32 in min] | [19/32 in min] | ||
| |||
Temperature Resistance | 100 °C [212 °F] min. | ||
|
|
| |
*Installation of pipes in a
*When certain specifications presented by the client must be met, ensure that they also meet the specifications on the chart above.
10. Wiring
GB
10.1. Caution
1Follow ordinance of your governmental organization for technical standard re- lated to electrical equipment, wiring regulations and guidance of each electric power company.
2Wiring for control (hereinafter referred to as transmission line) shall be (5 cm or more [2 in or more]) apart from power source wiring so that it is not influenced by electric noise from power source wiring. (Do not insert transmission line and power source wire in the same conduit.)
3Be sure to provide designated grounding work to heat source unit.
4Give some allowance to wiring for electrical part box of indoor and heat source units, because the box is sometimes removed at the time of service work.
5Never connect the main power source to terminal block of transmission line. If connected, electrical parts will be burnt out.
6Use
7Only the transmission line specified should be connected to the terminal block for heat source unit transmission.
(Transmission line to be connected with indoor unit : Terminal block TB3 for
transmission line, Other : Terminal block TB7 for centralized control) Erroneous connection does not allow the system to operate.
8In the case of connecting with an upper class controller or to conduct group operation in different refrigerant systems, the control line for transmission is required between the heat source units.
Connect this control line between the terminal blocks for centralized control.
When conducting group operation in different refrigerant systems without con- necting to the upper class controller, replace the insertion of the short circuit connector from CN41 of one heat source unit to CN40.
9Group is set by operating the remote controller.
10.2.Control box and connecting position of wiring
1.Connect the indoor unit transmission line to transmission terminal block (TB3), or connect the wiring between heat source units or the wiring with the central control system to the central control terminal block (TB7).
When using shielded wiring, connect shield ground of the indoor unit transmis-
sion line to the ground screw (
) and connect shield ground of the line be- tween heat source units and the central control system transmission line to the
shield (S) terminal of the central control terminal block (TB7) shield (S) termi- nal. In addition, in the case of heat source units whose power supply connector CN41 has been replaced by CN40, the shield terminal (S) of terminal block
(TB7) of the central control system should also be connected to the ground
screw (
).
Fix the wiring securely in place with the cable strap at the bottom of the termi- nal block so that the external force if not applied to the terminal block. External force applied to the terminal block may damage the block and
[Fig. 10.2.1] (P.4)
A Power source | B Transmission line |
CGround screw
2.Conduit mounting plates (ø27 mm
3.Fix power source wiring to terminal box by using buffer bushing for tensile force (PG connection or the like).
4.Narrow the opening by using a conduit to keep small animals out.
10.3. Wiring transmission cables
1Types of control cables
1. Wiring transmission cables
•Types of transmission cables: Shielding wire CVVS or CPEVS or MVVS
•Cable diameter: More than 1.25 mm2 [AWG16]
•Maximum wiring length: Within 200 m [656 ft]
•Maximum length of transmission lines for centralized control and indoor/out- door transmission lines (Maximum length via indoor units): 500 m [1640 ft]
MAX
The maximum length of the wiring between power supply unit for transmission lines (on the transmission lines for centralized control) and each outdoor unit and system controller is 200 m [656 ft].
2. Remote control cables
•M-NET Remote Controller
Kind of remote control cable | Sheathed | |
Cable diameter | 0.3 to 1.25 mm2 [AWG22 to 16] | |
(0.75 to 1.25 mm2 [AWG18 to 16])* | ||
| ||
| When 10 m [32 ft] is exceeded, use cable with | |
Remarks | the same specifications as 1. Wiring transmis- | |
| sion cables. | |
• MA Remote Controller |
| |
|
| |
Kind of remote control cable | Sheathed | |
Cable diameter | 0.3 to 1.25 mm2 [AWG22 to 16] | |
(0.75 to 1.25 mm2 [AWG18 to 16]))* | ||
| ||
Remarks | Within 200 m [656 ft] |
*Connected with simple remote controller.
2Wiring examples
•Controller name, symbol and allowable number of controllers.
Name | Symbol | Allowable number of controllers |
Heat source unit controller | OC |
|
Indoor Unit Controller | IC | One to twenty four controllers for one OC |
Remote Controller | RC | Maximum of two per group |
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