Hach AS950 AWRS Basic Installation And Maintenance

DOC026.98.80492

AS950 Portable Sampler

06/2016, Edition 5

Basic Installation and Maintenance

Grundlegende Installation und Wartung

Installazione e manutenzione base

Installation de base et maintenance

Instalación y mantenimiento básicos

Instalação e Manutenção Básica

Základy instalace a údržby

Standaard installatie en onderhoud

Podstawowa instrukcja montażu i konserwacji

Основен монтаж и поддръжка

Alapvető telepítés és karbantartás

Informaţii generale despre instalare şi întreţinere

Базовая установка и обслуживание

Temel Kurulum ve Bakım

Základná inštalácia a údržba

Osnovna namestitev in vzdrževanje

Osnovne upute za ugradnju i održavanje

Βασική εγκατάσταση και συντήρηση

Grundläggande Installation och Underhåll

English..............................................................................................................................3

Deutsch.......................................................................................................................... 25

Italiano............................................................................................................................ 49

Français......................................................................................................................... 72

Español.......................................................................................................................... 96

Português.................................................................................................................... 119

Čeština......................................................................................................................... 142

Nederlands................................................................................................................. 165

Polski............................................................................................................................ 188

български................................................................................................................... 212

Magyar......................................................................................................................... 236

Română....................................................................................................................... 260

Русский........................................................................................................................283

Türkçe...........................................................................................................................308

Slovenský jazyk......................................................................................................... 330

Slovenski..................................................................................................................... 353

Hrvatski........................................................................................................................ 375

Ελληνικά...................................................................................................................... 397

Svenska....................................................................................................................... 421

2

Table of contents

Specifications on page 3 Startup on page 17

General information on page 5 Maintenance on page 18

Installation on page 9 Troubleshooting on page 23

Additional information

Additional information is available on the manufacturer's website.

Specifications

Specifications are subject to change without notice.

AS950 portable sampler

Specification Standard base Compact base Composite base

Dimensions Diameter: 50.5 cm (19.9 in.)

Height: 71.6 cm (28.2 in.)

Diameter: 44.1 cm (17.4 in.)

Height: 63.8 cm (25.1 in.)

Diameter: 50.28 cm

(19.9 in.)

Height: 79.75 cm

(31.4 in.)

Weight 15 kg (35.6 lb) with 1-L (33.8 oz)

polyethylene bottles (24x)

14.8 kg (32.6 lb) with 10-L (2.5 gal)

polyethylene bottle (1x)

12.2 kg (27 lb) with 575-mL

(19.44 oz) polyethylene

bottles (24x)

12.9 kg (28.3 lb) with 10-L

(2.5 gal) polyethylene bottle

(1x)

15 kg (36 lb) with 950-

mL (32.12 oz) glass

bottles (12x)

Enclosure Impact-resistant ABS, 3-section construction; double-walled base with 2.54 cm (1 in.)

insulation—direct bottle contact with ice.

Sample

temperature

0–60 °C (32–140 °F)

Strainers 316 stainless steel in standard size, high velocity or low profile for shallow depth applications

and Teflon

®

or 316 stainless steel in standard size.

Sample bottle

capacity

1-L (33.8 oz) polyethylene and/or

350-mL (11.83 oz) glass bottles

(24x)

2.3-L (0.6 gal) polyethylene and/or

1.9-L (0.5 gal) glass bottles (8x)

3.8-L (1 gal) polyethylene and/or

3.8-L (1 gal) glass bottles (4x)

3.8-L (1 gal) polyethylene and/or

3.8-L (1 gal) glass bottles (2x)

21-L (5.5 gal) or 15-L (4 gal)

polyethylene composite bottle or 20-

L (5.25 gal) polyethylene or 10-L

(2.5 gal) polyethylene or 10-L

(2.5 gal) glass (1x)

575-mL (19.44 oz)

polyethylene bottles (24x)

950-mL (32.12 oz) glass

bottles (8x)

10-L (2.5 gal) polyethylene

bottle (1x)

10-L (2.5 gal) glass bottle

(1x)

21-L (5.5 gal)

polyethylene bottle (1x)

English 3

AS950 controller

Specification Details

Dimensions (W x H x D) 31.1 x 18.9 x 26.4 cm (12.3 x 7.4 x 10.4 in.)

Weight 4.6 kg (10 lb) maximum

Enclosure PC/ABS blend, NEMA 6, IP68, corrosion and ice resistant

Pollution degree/installation

category

3, II

Protection class II

Display ¼ VGA, color

Power requirements 15 VDC supplied by a 8754500 power supply (110–120 or 230 VAC, 50/60Hz);

12 VDC supplied by an external battery

Overload protection 7 A, DC line fuse for the pump

Operating temperature 0 to 50 °C (32 to 122 °F)

Storage temperature –30 to 60 °C (–22 to 140 °F)

Storage/operating humidity 100% condensing

Pump Peristaltic high speed with spring-mounted Nylatron rollers

Pump enclosure Polycarbonate cover

Pump tubing 9.5 mm ID x 15.9 OD mm (

3

/

8

-in. ID x

5

/

8

-in. OD) silicone

Pump tubing life 20,000 sample cycles with: 1 L (0.3 gal) sample volume, 1 rinse, 6-minute

pacing interval, 4.9 m (16 ft) of

3

/

8

-in. intake tube, 4.6 m (15 ft) of vertical lift,

21 °C (70 °F) sample temperature

Vertical sample lift 8.5 m (28 ft) for 8.8 m (29 ft) maximum of

3

/

8

-in. vinyl intake tube at sea level at

20 to 25 °C (68 to 77 °F)

Pump flow rate 4.8 L/min (1.25 gpm) at 1 m (3 ft) vertical lift with

3

/

8

-in. intake tube typical

Sample volume Programmable in 10-mL (0.34 oz) increments from 10 to 10,000 mL (3.38 oz to

2.6 gal)

Sample volume repeatability

(typical)

±5% of 200 mL sample volume with: 4.6 m (15 ft) vertical lift, 4.9 m (16 ft)

of

3

/

8

-in. vinyl intake tube, single bottle, full bottle shut-off at room temperature

and 1524 m (5000 ft) elevation

Sample volume accuracy

(typical)

±5% of 200 mL sample volume with: 4.6 m (15 ft) vertical lift, 4.9 m (16 ft)

of

3

/

8

-in. vinyl intake tube, single bottle, full bottle shut-off at room temperature

and 1524 m (5000 ft) elevation

Sampling modes Pacing: Fixed Time, Fixed Flow, Variable Time, Variable Flow, Event

Distribution: Samples per bottle, bottles per sample and time based (switching)

Run modes Continuous or non-continuous

Transfer velocity (typical) 0.9 m/s (2.9 ft/s) with: 4.6 m (15 ft) vertical lift, 4.9 m (16 ft) of

3

/

8

-in. vinyl intake

tubing, 21 °C (70 °F) and 1524 m (5000 ft) elevation

Liquid detector Ultrasonic. Body: Ultem

®

NSF ANSI standard 51 approved, USP Class VI

compliant. Contacting liquid detector or optional non-contact liquid detector

Air purge An air purge is done automatically before and after each sample. The sampler

automatically compensates for different intake tube lengths.

Tubing Intake tubing: 1.0 to 30.0 m (3.0 to 99 ft) length, ¼-in. or

3

/

8

-in. ID vinyl or

3

/

8

-in.

ID Teflon

™

-lined polyethylene with protective outer cover (black or clear)

4 English

Specification Details

Wetted materials Stainless steel, polyethylene, Teflon, Ultem, silicone

Memory Sample history: 4000 records; Data log: 325,000 records; Event log:

2000 records

Communications USB and optional RS485 (Modbus)

Electrical connections Power, auxiliary, optional sensors (2x), USB, distributor arm, optional rain

gauge

Analog outputs AUX port: none; optional IO9000 module: Three 0/4–20 mA outputs to

supply the recorded measurements (e.g., level, velocity, flow and pH) to

external instruments

Analog inputs AUX port: One 0/4–20 mA input for flow pacing; optional IO9000 module:

Two 0/4–20 mA inputs to receive measurements from external instruments

(e.g., third-party ultrasonic level)

Digital outputs AUX port: none; optional IO9000 module: Four low voltage, contact closure

outputs that each supply a digital signal for an alarm event

Relays AUX port: none; optional IO9000 module: Four relays controlled by alarm

events

Certifications CE, cETLus

General information

In no event will the manufacturer be liable for direct, indirect, special, incidental or consequential

damages resulting from any defect or omission in this manual. The manufacturer reserves the right to

make changes in this manual and the products it describes at any time, without notice or obligation.

Revised editions are found on the manufacturer’s website.

Safety information

N O T I C E

The manufacturer is not responsible for any damages due to misapplication or misuse of this product including,

without limitation, direct, incidental and consequential damages, and disclaims such damages to the full extent

permitted under applicable law. The user is solely responsible to identify critical application risks and install

appropriate mechanisms to protect processes during a possible equipment malfunction.

Please read this entire manual before unpacking, setting up or operating this equipment. Pay

attention to all danger and caution statements. Failure to do so could result in serious injury to the

operator or damage to the equipment.

Make sure that the protection provided by this equipment is not impaired. Do not use or install this

equipment in any manner other than that specified in this manual.

Use of hazard information

D A N G E R

Indicates a potentially or imminently hazardous situation which, if not avoided, will result in death or serious injury.

W A R N I N G

Indicates a potentially or imminently hazardous situation which, if not avoided, could result in death or serious

injury.

C A U T I O N

Indicates a potentially hazardous situation that may result in minor or moderate injury.

English 5

N O T I C E

Indicates a situation which, if not avoided, may cause damage to the instrument. Information that requires special

emphasis.

Precautionary labels

Read all labels and tags attached to the instrument. Personal injury or damage to the instrument

could occur if not observed. A symbol on the instrument is referenced in the manual with a

precautionary statement.

This is the safety alert symbol. Obey all safety messages that follow this symbol to avoid potential

injury. If on the instrument, refer to the instruction manual for operation or safety information.

This symbol indicates a potential pinch hazard.

Electrical equipment marked with this symbol may not be disposed of in European domestic or public

disposal systems. Return old or end-of-life equipment to the manufacturer for disposal at no charge to

the user.

Certification

Canadian Radio Interference-Causing Equipment Regulation, IECS-003, Class A:

Supporting test records reside with the manufacturer.

This Class A digital apparatus meets all requirements of the Canadian Interference-Causing

Equipment Regulations.

Cet appareil numérique de classe A répond à toutes les exigences de la réglementation canadienne

sur les équipements provoquant des interférences.

FCC Part 15, Class "A" Limits

Supporting test records reside with the manufacturer. The device complies with Part 15 of the FCC

Rules. Operation is subject to the following conditions:

1. The equipment may not cause harmful interference.

2. The equipment must accept any interference received, including interference that may cause

undesired operation.

Changes or modifications to this equipment not expressly approved by the party responsible for

compliance could void the user's authority to operate the equipment. This equipment has been tested

and found to comply with the limits for a Class A digital device, pursuant to Part 15 of the FCC rules.

These limits are designed to provide reasonable protection against harmful interference when the

equipment is operated in a commercial environment. This equipment generates, uses and can

radiate radio frequency energy and, if not installed and used in accordance with the instruction

manual, may cause harmful interference to radio communications. Operation of this equipment in a

residential area is likely to cause harmful interference, in which case the user will be required to

correct the interference at their expense. The following techniques can be used to reduce

interference problems:

1. Disconnect the equipment from its power source to verify that it is or is not the source of the

interference.

2. If the equipment is connected to the same outlet as the device experiencing interference, connect

the equipment to a different outlet.

3. Move the equipment away from the device receiving the interference.

4. Reposition the receiving antenna for the device receiving the interference.

5. Try combinations of the above.

6

English

Product overview

D A N G E R

Chemical or biological hazards. If this instrument is used to monitor a treatment process and/or

chemical feed system for which there are regulatory limits and monitoring requirements related to

public health, public safety, food or beverage manufacture or processing, it is the responsibility of the

user of this instrument to know and abide by any applicable regulation and to have sufficient and

appropriate mechanisms in place for compliance with applicable regulations in the event of malfunction

of the instrument.

C A U T I O N

Fire hazard. This product is not designed for use with flammable liquids.

The portable sampler collects liquid samples at specified intervals and keeps the samples in bottles.

Use the sampler for a wide variety of aqueous sample applications and also with toxic pollutants and

suspended solids. Set up the sampler with different retainers or bottles. Refer to Figure 1.

Figure 1 Product overview

1 Compact base 7 Pump

2 Standard insulated base 8 Controller

3 Center section 9 Liquid detector

4 Power source 10 Non-contacting liquid detector

5 Top cover 11 Composite insulated base for one 21-L (5.5 gal)

bottle

6 Controller connections

Close the cover

To close the cover, align the latch plates as shown in Figure 2 and close the latches.

English

7

Figure 2 Latch plates alignment

Product components

Make sure that all components have been received. Refer to Figure 3. If any items are missing or

damaged, contact the manufacturer or a sales representative immediately.

Figure 3 Product components

1 Base (Standard, compact or composite) 7 AC power supply (optional)

2 Components for a single-bottle option (bottle and

support can change)

8 Strainer

3 Center section with controller 9 Intake tubing, vinyl or Teflon-lined

4 Battery (optional) 10 Components for a multiple-bottle option (bottles

and retainers can change)

5 Top cover 11 Tubing coupler

1

6 Battery charger (optional)

1

Supplied with controllers with the non-contacting liquid detector only.

8 English

Installation

D A N G E R

Multiple hazards. Only qualified personnel must conduct the tasks described in this section of the

document.

Confined space precautions

D A N G E R

Explosion hazard. Training in pre-entry testing, ventilation, entry procedures, evacuation/rescue

procedures and safety work practices is necessary before entering confined spaces.

The information that follows is supplied to help users understand the dangers and risks that are

associated with entry into confined spaces.

On April 15, 1993, OSHA's final ruling on CFR 1910.146, Permit Required Confined Spaces, became

law. This standard directly affects more than 250,000 industrial sites in the United States and was

created to protect the health and safety of workers in confined spaces.

Definition of a confined space:

A confined space is any location or enclosure that has (or has the immediate potential for) one or

more of the following conditions:

• An atmosphere with an oxygen concentration that is less than 19.5% or more than 23.5% and/or a

hydrogen sulfide (H

2

S) concentration that is more than 10 ppm.

• An atmosphere that can be flammable or explosive due to gases, vapors, mists, dusts or fibers.

• Toxic materials which upon contact or inhalation can cause injury, impairment of health or death.

Confined spaces are not designed for human occupancy. Confined spaces have a restricted entry

and contain known or potential hazards. Examples of confined spaces include manholes, stacks,

pipes, vats, switch vaults and other similar locations.

Standard safety procedures must always be obeyed before entry into confined spaces and/or

locations where hazardous gases, vapors, mists, dusts or fibers can be present. Before entry into a

confined space, find and read all procedures that are related to confined space entry.

Site installation guidelines

D A N G E R

Explosion hazard. The instrument is not approved for installation in hazardous locations.

This instrument is rated for an altitude of 2000 m (6562 ft) maximum. Although the use of this

equipment above the 2000 m altitude does not show any substantial safety concern, the

manufacturer recommends that users with concerns contact technical support.

Refer to the guidelines that follow for the site location evaluation.

• Obey all the safety precautions if the sampler is installed in a confined space. Refer to Confined

space precautions on page 9.

• Make sure that the temperature at the location is in the specification range. Refer to Specifications

on page 3.

• Install the sampler on a level surface or hang the sampler with the suspension harness, the

support bracket or the spanner bar. Refer to Install the sampler in a manhole on page 10 and to

the applicable installation documentation.

• Install the sampler as near the sample source as possible. Refer to Plumb the sampler

on page 12.

• For limitations on transport velocity and maximum vertical lift, refer to Specifications on page 3.

English

9

Mechanical installation

Install the sampler in a manhole

Install the sampler above the sample water in a manhole. Install the sampler with a spanner bar or a

support bracket. Install the spanner bar inside the manhole. The spanner bar is supported by

pressure against the walls. The support bracket has the same width as the manhole cover. Install the

support bracket directly below the cover for support.For the accessories, refer to the expanded

manual on the manufacturer's website. Refer to the documentation supplied with the accessories to

install the sampler.

Prepare the sampler

Clean the sample bottles

Clean the sample bottles and caps with a brush, water and a mild detergent. Flush the sample

bottles with fresh water followed by a distilled water rinse.

Install a single bottle

When a single bottle is used to collect one composite sample, do the steps that follow. When multiple

bottles are used, refer to Install the first bottle for multiple sample collections on page 10.

When the bottle is full, the full bottle shut-off stops the sample program. Install the sample bottle as

shown in Figure 4.

Figure 4 Single bottle installation

1 Polyethylene bottle, 10 L (2.6 gal) 6 Polyethylene bottle, 21 L (5.5 gal)

2 Glass bottle, 10 L (2.6 gal) 7 Compact base

3 Support for standard base and 10 L (2.6 gal) glass

bottle

8 Standard insulated base

4 Polyethylene bottle, 15 L (4 gal) 9 Composite insulated base for 21 L (5.5 gal) bottle

5 Polyethylene bottle, 19 L (5 gal)

Install the first bottle for multiple sample collections

Use multiple bottles to collect samples into separate bottles or into more than one bottle. The

distributor moves the sample tube above each bottle. Install the bottles in the sampler base as shown

in Figure 5. Install the first sample bottle (number 1) below the label in the sampler base. Install the

remaining bottles in increasing numbers in the direction shown by the label. Refer to Figure 6

on page 12 for a diagram of necessary components.

10

English

Figure 5 Bottle number 1 installation

1 Bottle number 1 location (compact base) 6 Elastic straps

2 Bottle number 1 location for 24 bottles 7 Composite insulated base for 21 L (5.5 gal) bottle

3 Bottle number 1 location for 8 bottles 8 Standard insulated base

4 Bottle number 1 location for 2 or 4 bottles 9 Compact base

5 Retainer

Install multiple bottles

When multiple bottles are installed, a distributor arm moves the sample tube over each bottle.

Sample collection automatically stops when the specified number of samples have been collected.

1. Install the first sample bottle (number 1) below the label in the sampler base. Refer to Install the

first bottle for multiple sample collections on page 10.

2. Assemble the sample bottles as shown in Figure 6. For eight or more bottles, make sure that the

first bottle goes next to the bottle one indicator in the clockwise direction.

3. Put the bottle assembly in the sampler. For eight or more bottles, align the wires in the slots in the

bottom tray.

English

11

Figure 6 Multiple bottle installation

1 Retainer/Positioner for 8 950-mL glass bottles 8 Bottle set, 4 3.8-L (1-gal) poly or glass

2 Retainer for 8 or 24 glass or poly bottles 9 Bottle set, 8 1.9-L (0.5-gal) glass or 8 2.3-L (0.6-gal)

poly

3 Retainer for 4 3.8-L (1 gal) glass or poly bottles 10 Bottle set, 24 1-L (0.26 gal) poly

4 Retainer for 24 350-mL (11.83 oz) glass bottles 11 Bottle set, 24 350-mL (11.83 oz) glass

5 Bottle set, 8 950-mL (32.12 oz) glass 12 Compact base

6 Bottle set, 24 575-mL (19.44 oz) poly 13 Standard base

7 Bottle set, 2 3.8-L (1-gal) poly or glass

Plumb the sampler

Install the strainer in the middle of the sample stream (not near the surface or the bottom) to make

sure that a representative sample is collected. Refer to Figure 7.

1. Connect the tubing to the sampler as shown in Figure 8.

Note: When Teflon-lined tubing is used, use the tubing connection kit for Teflon-lined PE tubing.

2. Install the intake tube and strainer in the main stream of the sample source where the water is

turbulent and well-mixed.

• Make the intake tube as short as possible. Refer to Specifications on page 3 for the minimum

intake tubing length.

• Keep the intake tube at a maximum vertical slope so that the tube drains completely between

samples.

Note: If a vertical slope is not possible or if the tube is pressurized, disable the liquid sensor. Calibrate the

sample volume manually.

• Make sure that the intake tube is not pinched.

12

English

Figure 7 Instrument installation

1 Strainer 3 Intake tube

2 Vertical lift

Figure 8 Intake tube installation

Electrical installation

Connect the sampler to power

D A N G E R

Electrocution hazard. If this equipment is used outdoors or in potentially wet locations, a Ground Fault

Circuit Interrupt (GFCI/GFI) device must be used for connecting the equipment to its main power

source.

English 13

D A N G E R

Fire hazard. Install a 15 A circuit breaker in the power line. A circuit breaker can be the local power

disconnect, if located in close proximity to the equipment.

D A N G E R

Electrocution hazard. Protective Earth Ground (PE) connection is required.

W A R N I N G

Electrocution hazard. Make sure that there is easy access to the local power disconnect.

Connect the sampler to a battery (8754400) or an AC power supply (8754500US, 8754500EU or

8754500UK). Refer to Figure 9.

Figure 9 Connect the sampler to power

Controller connections

W A R N I N G

Electrical shock hazard. Externally connected equipment must have an applicable country safety

standard assessment.

Figure 10 shows the electrical connectors on the controller.

14

English

Figure 10 Controller connections

1 Sensor 2 port (optional) 5 Rain gauge/RS485 port (optional)

2 Power supply port 6 Auxilliary I/O port

3 Sensor 1 port (optional) 7 Distributor arm/Full bottle shut-off port

4 USB connector

Connect a Sigma 950 or FL900

If sample pacing is flow based, supply the controller with a flow input signal (pulse or 4–20 mA).

Connect a Sigma 950 or an FL900 Flow Logger to the AUX I/O port.

As an alternative, connect a flow sensor to a sensor port. Refer to Connect a sensor on page 17.

Item to collect: Multi-purpose auxiliary full cable, 7 pin

1. Connect one end of the cable to the flow meter. Refer to the flow meter documentation.

2. Connect the other end of the cable to the AUX I/O port on the controller.

Connect a non-Hach flow meter

To connect a non-Hach flow meter to the AUX I/O port, do the steps that follow.

Items to collect: Multi-purpose auxiliary half cable, 7 pin

1. Connect one end of the cable to the AUX I/O port on the controller.

2. Connect the other end of the cable to the flow meter. Refer to Figure 11 and Table 1.

Note: In some installations, it is necessary to connect external equipment to the Pulse input, Special output

and/or Program Complete output with long cables. Since these are ground-referenced pulse interfaces, false

signaling can be caused by transient ground differences between each end of the cable. High ground

differentials are typical in heavy industrial environments. In such environments, it may be necessary to use

third-party galvanic isolators (e.g., optocouplers) in line with the affected signal(s). For the Analog input,

external ground isolation is typically not necessary because the 4–20 mA transmitter typically supplies isolation.

Figure 11 Auxiliary connector

English 15

Table 1 Half cable wiring information

Pin Signal Color

2

Description Rating

1 +12 VDC

power

output

White Power supply positive output.

Only use with pin 2.

Battery power to the IO9000 module: 12 VDC

nominal; Power supply to the IO9000 module:

15 at 1.0 A maximum.

2 Common Blue Negative return of power supply.

When the power supply is used,

pin 2 is connected to earth

ground

3

.

3 Pulse input

or Analog

input

Orange This input is a sample collection

trigger from the flow meter (pulse

or 4–20 mA) or a simple floating

(dry) contact closure.

Pulse input—Reacts to a positive pulse with

respect to pin 2. Termination (pulled low): pin 2

through a series 1 kΩ resistor and 10 kΩ

resistor. A 7.5 zener diode is in parallel with the

10 kΩ resistor as a protection device.

Analog input—Reacts to the analog signal that

enters pin 3 and returns on pin 2. Input burden:

100 Ω plus 0.4 V; Input current (internal limit):

40 to 50 mA maximum

4

Absolute maximum input: 0 to 15 VDC with

respect to pin 2.

Signal to make the input active: 5 to 15 V

positive-going pulse

5

with respect to pin 2,

50 millisecond minimum.

4 Liquid level

input or

Auxiliary

control

input

Black Liquid level input—Start or

continue the sampling program. A

simple float level switch can

supply input.

Auxiliary control input—Start a

sampler after the sampling

program on another sampler

ends. As an alternative, start a

sampler when a trigger condition

occurs. For example, when a

high or low pH condition occurs,

the sampling program starts.

Termination (pulled high): internal +5 V supply

through an 11 kΩ resistance with a series 1 kΩ

resistor and 7.5 V zener diode terminated to pin

2 for protection. Trigger: High to low voltage

with a low pulse of 50 milliseconds minimum.

Absolute maximum input: 0 to 15 VDC with

respect to pin 2. Signal to make the input

active: external logic signal with 5 to 15 VDC

power source. The drive signal must be

typically high. The external driver must be able

to sink 0.5 mA at 1 VDC maximum at the logic

low level.

A logic high signal from a driver with a power

source of more than 7.5 V will source current

into this input at the rate of: I = (V –

7.5)/1000 where I is the source current and V is

the power supply voltage of the driving logic.

Dry contact (switch) closure: 50 millisecond

minimum between pin 4 and pin 2. Contact

resistance: 2 kΩ maximum. Contact current:

0.5 mA DC maximum

5 Special

output

Red This output goes from 0 to

+12 VDC with respect to pin 2

after each sample cycle. Refer to

the Mode setting of the hardware

settings for the AUX I/O port.

Refer to the AS950 operations

documentation.

This output has protection against short circuit

currents to pin 2. External load current: 0.2 A

maximum

Active high output: 15 VDC nominal with AC

power to the AS950 controller or a 12 VDC

nominal with battery power to the

AS950 controller.

2

The wire color refers to the colors of multi-purpose cables (8528500 and 8528501).

3

All mains powered equipment that connects to the controller terminals must be NRTL listed.

4

Long-term operation in this state voids the warranty.

5

Source impedance of the driving signal must be less than 5 kΩ.

16 English

Table 1 Half cable wiring information (continued)

Pin Signal Color

2

Description Rating

6 Program

Complete

output

Green Typical state: open circuit. This

output goes to ground for

90 seconds at the end of the

sampling program.

Use this output to start another

sampler or to signal an operator

or data logger at the end of the

sampling program.

This output is an open drain output with 18 V

zener clamp diode for over-voltage protection.

The output is active low with respect to pin 2.

Absolute maximum ratings for the output

transistor: sink current = 200 mA DC maximum;

external pull-up voltage = 18 VDC maximum

7 Shield Silver The shield is a connection to

earth ground when AC power is

supplied to a sampler to control

RF emissions and susceptibility

to RF emissions.

The shield is not a safety ground. Do not use

the shield as a current carrying conductor.

The shield wire of cables that are connected to

the AUX I/O port and are more than 3 m (10 ft)

should connected to pin 7.

Only connect the shield wire to earth ground at

one end of the cable to prevent ground loop

currents.

Connect a sensor

To connect a sensor (e.g., pH or flow sensor) to a sensor port, refer to Figure 12.

Figure 12 Connect a sensor

Startup

Set the instrument to on

Push and hold the Power key on the controller to set the instrument to on.

Preparation for use

The physical installation is now complete. Refer to the operations manual to complete the setup for

the first use.

English

17

Maintenance

D A N G E R

Multiple hazards. Only qualified personnel must conduct the tasks described in this section of the

document.

D A N G E R

Electrocution hazard. Remove power from the instrument before doing maintenance or service

activities.

W A R N I N G

Biohazard exposure. Obey safe handling protocols during contact with sample bottles and sampler

components.

W A R N I N G

Multiple hazards. The technician must make sure that the equipment operates safely and correctly

after maintenance procedures.

N O T I C E

Do not disassemble the instrument for maintenance. If the internal components must be cleaned or repaired,

contact the manufacturer.

Clean the instrument

C A U T I O N

Fire hazard. Do not use flammable agents to clean the instrument.

If water is not sufficient to clean the controller and the pump, disconnect the controller and move the

controller away from the sampler. Allow sufficient time for the controller and pump to dry before the

parts are re-installed and put back into service.

Clean the sampler as follows:

• Sampler enclosure—Clean the internal and external surfaces with a damp cloth and a mild

detergent. Do not use abrasive cleaners or solvents.

• Sample bottles—Clean the bottles with a brush and water and a mild detergent. Rinse with fresh

water and then with distilled water. Use an autoclave to clean glass bottles if necessary.

Replace the desiccant

A desiccant cartridge in the controller absorbs moisture and prevents corrosion. Monitor the

desiccant color through the window. Refer to Figure 13. Fresh desiccant is orange. When the color is

green, replace the desiccant.

1. Unscrew and remove the desiccant cartridge. Refer to Figure 13.

2. Remove the plug and discard the spent desiccant.

3. Fill the desiccant tube with fresh desiccant.

4. Install the plug.

5. Apply silicone grease to the O-ring.

6. Install the desiccant tube in the controller.

18

English

Figure 13 Desiccant cartridge

1 Plug 3 O-ring

2 Desiccant tube 4 Desiccant window

Pump maintenance

C A U T I O N

Pinch hazard. Remove power from the instrument before maintenance or service activities are done.

Replace the pump tubing

N O T I C E

Use of tubing other than that supplied by the manufacturer can cause excessive wear on mechanical parts and/or

poor pump performance.

Examine the pump tubing for wear where the rollers rub against the tubing. Replace the tubing when

the tubing shows signs of wear.

Pre-requisites:

• Pump tubing—pre-cut or bulk 4.6 m or 15.2 m (15 ft or 50 ft)

1. Disconnect the power to the controller.

2. If the bulk tubing is used, cut the tubing and add alignment dots. Refer to Figure 14.

3. Remove the pump tubing as shown in the illustrated steps that follow.

4. Clean the silicone residue from the interior of the pump housing and from the rollers.

5. Install the new pump tubing as shown in the illustrated steps that follow.

English

19

Figure 14 Pump tubing preparation

1 To intake tubing 4 Length for controller with standard liquid detector

2 Alignment dots 5 Length for controller with optional non-contacting

liquid detector

3 To fitting on sampler base 6 Length inside the pump

20 English

Sayfa yükleniyor ...

Hach AS950 AWRS Basic Installation And Maintenance

Hach AS950 AWRS Basic Installation And Maintenance

Diğer dillerde

İlgili Makaleler

Diğer Belgeler