HID ESH400-K Installation Guide

EDGE EVO

®

15370 Barranca Parkway
Irvine, CA 92618-2215
USA

Standard Networked Controller

EH400-K / ESH400-K

InstallatIon GuIde

82000-921, Rev D.1

October 2012

© 2009 - 2012 HID Global Corporation. All rights reserved.

EDGE EVO is the next evolution in access control hardware solutions. A true IP solution that meets the demands of open architecture,
IP-centric environments, EDGE EVO provides fully distributed intelligence and decision making right to the door, leveraging the IT
infrastructure to the maximum extent possible. Leveraging Power-over-Ethernet (PoE), EDGE EVO reduces door installation costs by not
requiring a separate local power supply under many circumstances.

The Standard Networked Controller is a fully integrated single-door controller offering discrete I/O and Wiegand/Clock-and-Data interfaces
to readers. Additionally, connect native Hi-O devices (readers, locks, pushbuttons) and EDGE EVO Hi-O Modules to the Hi-O bus,
providing secure communication around the door. Hi-O involves devices with built-in intelligence and a CANbus that links all the devices

together. Password protect or encrypt Hi-O CANbus data trafc. Each Hi-O device (such as the REX switch, electric strike, card reader and

door operator) is connected to the CANbus by a single, four-wire cable. Two of the wires supply power and the other two are used for data
communication.

Specifications

CONDITIONS VOLTAGE DC (VDC)

+12VDC 0.18Amp 2.16

DC Input (NSC)

DC Input (MAX)

Supervised inputs

(AC, Batt, REX, Door Mon) (MAX)

Data 1/CLK , Data 0 / Data (MAX) 0-+5VDC Reference N/A N/A

Input

GRN LED, RED LED, Beep,
Hold (MAX)

External Tamper (MAX) +5VDC (NOM) 0.02 0.100

CAN DC
Output

(MAX)

Reader
DC PWR

Output

(MAX)

Strike***

/ AUX
Relays

NC or NO
DC Output

(MAX)

Output

NSC = Normal Standby Condition
* Combined output rating not to exceed V*I = W

1.2 Amp (+24VDC AUX Input, 28.8 W)

1.2 Amp (+12VDC AUX Input, 12.96 W)

AUX 12 / 24VDC Input +10.8 to +24VDC 1.2Amp * 28.80

PoE Input + 24VDC (NOM) 0.4Amp * 9.60

AUX 12 VDC +9.8 to +12.25VDC 0.32Amp * 3.92

AUX 24VDC +9.8 to +12.25VDC 0.60Amp * 7.35

PoE Input +9.8 to +12.25VDC 0.58Amp * 7.11

AUX 12VDC

Input

AUX 24VDC

Input

PoE Input

AUX / PoE

Input

Unregulated (Wet)

Jumpers

Unregulated (Wet)

Jumpers

Regulated (Wet)
Jumpers - 12VDC

Unregulated (Wet)

Jumpers

Regulated (Wet)
Jumpers - 12VDC

Jumpers Set

to Dry

+24VDC 0.14Amp 3.36

PoE

(+48VDC NOM)

+12VDC 1.5Amp 18.00

+24VDC 1.5Amp 36.00

PoE

(+48VDC NOM)

0-+5VDC Reference

0-+5VDC reference

+10 to +12VDC 0.70Amp * 8.40

+23 to +24VDC 0.70Amp * 16.80

+10 to +12VDC 0.70Amp * 8.40

+16.5 to +24VDC 0.36Amp * 8.64

+10 to +12VDC 0.58Amp * 6.96

+12 to +24VDC

External

** Each relay
*** Shared between relays.

CURRENT
(Amp)

.085Amp 4.08

0.3Amp 14.40

0.005Amp
(sink)

0.005Amp
(sink)

2.00Amp ** 48.00

POWER (W)

0.025

0.025

OPERATING
TEMPERTURE

32° - 122°F

(0° - 50° C)

CABLE LENGTH

Hi-O CAN Bus Total Length 100 ft (30 m) -

22 AWG ● 0.65mm ● 0.33mm

Maximum between drops
30 ft (10 m)

22 AWG ● 0.65mm ● 0.33mm

RJ45 328 ft (100 m) - Category 5 K

X1 = K for Black

G for Gray

X2 = N for non-Solo

S for Solo

UL REF
NUMBER

2

KE400CX1X2N

2

Standard Networked Controller

Wi

n

D

o

o

r

P

S

M

a

g

ted

n

e

EH400-K

0.4 Amp (PoE Input, 9.6 W)

82000-921, D.1

1

Power Analysis

Before starting installation, determine which components will be used in the system and analyze the power requirements to avoid

over-loading the EDGE EVO Hi-O Networked Controller & Reader (EH400-K).

The steps that follow illustrate sizing power requirements for the system.

Step 1 - Identify System Components

Identify the components that will be used in the system. A typical installation may include the following components:

• Door Position Switch – Detects when the door is open or closed.

• Magnetic Lock – Holds the door locked.

• Request to Exit (REX) Switch – Unlocks the door when exiting the secured area.

• EDGE EVO Hi-O Standard Networked Controller (EH400-K) – Provides access control and manages all

peripherals around the door.

• iCLASS Wiegand Reader – Provides entry into the secured area.

Step 2 - Create System Layout

Using the components identied in “Step 1 - Identify System Components” on page 2, create the system layout.

In this example, the EH400-K is connected to the remote server through an Ethernet connection and manages door
peripherals over the Hi-O bus. Controlling downstream door peripherals, the EH400-K is a fully integrated single-door
controller offering discrete I/O and Wiegand/Clock-and-Data interfaces to external readers. The EH400-K receives inputs
from the Door Position Switch and REX Switch to drive the Magnetic Lock output.

Unprotected

Area

Wiegand Ethernet Switch

ega

Wiegand Reader

Door Position

i

Switch

Magnetic Lock

Figure 1 - System Layout Example

Protected Area

REX Switch

Ethernet Data

EH400-K

Remote Area

Physical Access

Control Server

(real-time functions

not required )

INSTALLATION GUIDE

2

©2009 - 2012 HID Global Corporation. All rights reserved.

82000-921, D.1

Step 3 - Analyze Power Requirements

Standard Networked Controller

EH400-K

A - Door Peripheral Operational Currents

For the door peripherals identied in “Step 1 - Identify System Components” on page 2, consult the vendor data sheets
to determine the operational current draw. Typical operational current draw is provided below.

Note: See individual peripheral data sheets for actual operational current draw.

Device Conditions Typical Operational Current

Door Position Switch Vin = 12VDC 15mA

(For example, Securitron MSS) Vin = 24VDC 15mA

Mag Lock Vin = 12VDC 300mA

(For example, Securitron M32) Vin = 24VDC 150mA

REX Switch Vin = 12VDC 28mA

(For example, Securitron EEB) Vin = 24VDC 38mA

iCLASS Wiegand Reader Vin = 12VDC 150mA

B - Match I/O Requirements to the Hi-O Interface Device

For the door peripherals identied in “Step 1 - Identify System Components” on page 2, the system requires direct
connection to I/O interface and Wiegand/Clock-and-Data ports of the EH400-K. A separate Hi-O Interface Device is not

required.

C - Compute and Compare Overall Current Draw

Calculate the total current draw for all door peripherals and the attached Wiegand readers with the following equation,
adding terms as required.

I

= I

+ I

+ I

total

dps

mag

+ … + I

rex

iCLASS reader

The following calculations provide load current computations.

I

@ 12VDC = 15mA + 300mA + 28mA + 150mA = 493mA

total

I

@ 24VDC = 15mA + 150mA + 38mA + 150mA = 353mA

total

Compare the required current draw (I

select the EH400-K power scheme. The CAN DC PWR Output represents the entire power output capacity of the EH400-K.

Device Port Conditions Vout I out

Standard Networked Controller

(EH400-K)

In this example, the EH400-K provides sufcient power when operated with a PoE injector, or +12/24VDC auxiliary power

supplies.

Directly connect the door peripherals identied in “Step 1 - Identify System Components” on page 2 to the EH400-K I/O
ports per the “Specications” on page 1 for the selected input power scheme.

Ensure all door peripherals connected to the Strike/AUX relays and the Reader DC PWR Output or both do not exceed

1.2Amps (AUX Input) or 0.4Amps (PoE Input), combined. Alternatively, the door peripherals may be connected to the Strike/

AUX relays congured for Dry contact up to 2Amps per relay.

CAN DC PWR
Output (MAX)

) to the output current capacity of the EH400-K (see Specication table, pg 1) to

total

AUX 12-24VDC Input +10.8 to +24VDC 1.2Amp

PoE input

+24VDC (NOM) 0.4Amp

©2009 - 2012 HID Global Corporation. All rights reserved.

INSTALLATION GUIDE

3