Apol Lo

APOLLO

0051

Service ManualVersion 17 July 2006 (Rev. 4)

APOLLO

0051

Service ManualThis Manual belongs to Apollo equipment serial No. Version 17 July 2006 (Rev. 4)

SERVICE MANUAL Revision history

Revision historyRev. 0 1 Date 14.01.05 29.03.05 Page/s 6-2, 6-14, 6-44, 17-5, from 22-129 to 22-145 Modification description Document approval. A14 Control desk CPU PCB layout and wiring diagram update. Parameter 74 update in Inverter setting. Description of basement grubs regulation.(Ref. RDM 6040, RDM 6078, RDM 6092)

2

27.04.05

4-6, 4-11, 6-44, 7-1, 8-1, 8-3, 9-2, 11-10, 11-13, 11-16, 11-25, 11-26, 13-6, 13-10, da 22-9 a 22-45, 22-49, da 22-69 a 22-77, da 22-81 a 22-95

Change of min and max height of compressor cone with respect to table top. Release of SW Version 1.03 (correcting some minor bugs and introducing some improvements). Wiring diagrams and Drawings update.(Ref. RDM 6008, RDM 6103, RDM 6104)

3

14.04.06

All

Release of "All Digital" version. Release of "C-CSA-US" version. Release flat tabletop version. Software parameters updating. Release of SW version 1.05 (HOLD function active message on the display, collimator additional filter function, Table Top double height possibilities from floor). Wiring diagrams and Drawings update. Spare Parts chapter added.(Ref. RDM 6292, RDM 6340, RDM 6360)

4

17.07.06

from 4-2 to 4-6, 4-8, 8-1, 11-14, 11-16, 11-21, 11-25, 11-37, 11-42, 14-4, 18-3, 20-3, 22-3, from 22-9 to 22-45, 22-49, from 22-81 to 22-95, 22-129, 22-131, from 22-155 to 22-159, 23-6

Release of SW version 1.06 on cabinet CPU board and SW version 1.04 on console CPU board (4 Tomo speed, SID and Layers displayed in inch, compression force displayed in lbs, 43x35 cassette division 4:1). Additional Collimator Filters board A16 (optional) added. Table Top Control board A17 added.(Rif. RDM 6414, RDM 6467)

(Rev. 4)

APOLLO

SERVICE MANUAL Revision history

THIS PAGE IS INTENTIONALLY LEFT BLANK

APOLLO

(Rev. 3)

SERVICE MANUAL Contents

Contents1 INTRODUCTION1.1 1.2

1-1

Symbols used in this manual .............................................................. 1-1 How to contact VILLA SISTEMI MEDICALI technical service ................ 1-2

2

SAFETY ASPECTS2.1 2.2 2.3 2.4

2-1

Warnings ............................................................................................. 2-2 Radioprotection warnings .................................................................... 2-5 Environmental risks and disposal........................................................ 2-8 Used symbols ...................................................................................... 2-9

3

DESCRIPTION3.13.1.1 3.1.2

3-1

ID labels .............................................................................................. 3-1ID labels "CE" version.......................................................................3-2 ID labels "CE" plus "C-CSA-US" version ............................................3-3

3.2

Description .......................................................................................... 3-4

4

TECHNICAL DATA4.1 4.2 4.3 4.4 4.5

4-1

Technical features ............................................................................... 4-1 Formats division table in centimeters .................................................. 4-8 Formats division table in inches .......................................................... 4-9 Standards and regulations................................................................. 4-10 Dimensions ....................................................................................... 4-11

5

PRE-INSTALLATION5.1 5.2 5.3 5.4

5-1

Space requirements ............................................................................. 5-3 Electrical provisions ............................................................................ 5-6 Adaptation to the mains voltage........................................................... 5-7 Environmental conditions.................................................................... 5-7

6

INSTALLATION6.1 6.2 6.3 6.4 6.5

6-1

Base positioning with beam and column.............................................. 6-2 Assembly of the Tube support arm ...................................................... 6-5 Spot Film Device assembly .................................................................. 6-6 Left- and right-hand tabletop support arm assembly ......................... 6-10 Machine cable connection.................................................................. 6-12

(Rev. 3)

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APOLLO


6.6

Image intensifier installation.............................................................. 6-236.6.1 6.6.2 6.6.3 9-12 fixed Image Intensifier (I.I.) installation.................................. 6-24 16" fixed Image Intensifier (I.I.) installation (Toshiba model) ............ 6-26 Image Intensifier (I.I.) with lift installation....................................... 6-28 6.6.3.1 9 with lift Image Intensifier (I.I.) installation ................. 6-29 6.6.3.2 12 Image Intensifier (I.I.) with lift installation ............... 6-31 6.6.3.3 16 Image Intensifier (I.I.) with lift installation ............... 6-33

6.7 6.8 6.9

Installation of the Tube - Collimator group......................................... 6-35 Mounting the covers .......................................................................... 6-39 Tabletop assembly ............................................................................. 6-456.9.1 6.9.2 Curved tabletop assembly .............................................................. 6-45 Flat tabletop assembly ................................................................... 6-47

6.10 Final verifications .............................................................................. 6-49

7

THE FUNCTIONING LOGIC OF THE TABLE7.17.1.1 7.1.2

7-1

Functioning sequences ........................................................................ 7-3Powering up and initialisation sequence ........................................... 7-3 Activation sequence for a movement ................................................. 7-4 Generation of a condition alarm ....................................................... 7-6 Generation of a operating alarm ....................................................... 7-6 Generation of an alarm caused by the power circuit.......................... 7-7

7.2

Fault Conditions .................................................................................. 7-67.2.1 7.2.2 7.2.3

8

IN/OUT INTERFACE CONNECTION8.1 8.2

8-1

Output signals from the Apollo table.................................................... 8-1 Input signals towards the Apollo table ................................................. 8-3

9 10

CONFIGURATION ACCESS AND DESCRIPTION OF THE DATA GROUPS ACCESS AND ADJUSTMENT OF GROUP 100 DATA10.1.1 10.1.2 10.1.3 10.1.4

9-1 10-1

10.1 Potmeter adjustment ......................................................................... 10-4Cell data and list............................................................................ 10-5 ANGULATION potmeter adjustment (cells 101 102) ...................... 10-8 SCAN potmeter adjustment (cells 103 104)................................... 10-9 MAIN BEAM and MIDDLE BEAM potmeter adjustment (cells 105 108)........................................................................... 10-10 10.1.5 TRANSVERSAL TABLETOP potmeter adjustment (cells 111 112) 10-14 10.1.6 SOURCE TO FILM DISTANCE potmeter adjustment (cells 113 114) ........................................................................... 10-15 10.1.7 WIDTH COLLIMATOR potmeter adjustment (cells 117 118) ........ 10-16 10.1.8 HEIGHT COLLIMATOR potmeter adjustment (cells 119 120)...... 10-17 10.1.9 IRIS COLLIMATOR (optional accessory) potmeter adjustment (cells 121 122) ........................................................................... 10-18 10.1.10 COMPRESSION FORCE potmeter adjustment (cells 123 124) ..... 10-19APOLLO

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(Rev. 3)


10.1.11 GRID potmeter adjustment (cells 125 126) ................................. 10-20 10.1.12 CASSETTE CLOSE potmeter adjustment (cells 127 128) ............. 10-21 10.1.12.1 CASSETTE TIGHTENING switch adjustment ............... 10-22 10.1.13 CROSS SUBDIVISION potmeter adjustment (cells 129 130) ........ 10-24 10.1.14 SHUTTER potmeter adjustment (cells 131 132) .......................... 10-25 10.1.15 I.I. lift microswitches adjustment (Optional) (cell 133) ................... 10-26

11

ACCESS AND DATA FUNCTION OF ALL GROUPS (EXCEPT GROUP 100)11.1.1 11.2.1 11.2.2 11.3.1 11.3.2 11.3.3 11.3.4

11-1

11.1 Group 200 Installation data ............................................................ 11-3Function of the parameters of group 200 ........................................ 11-3 Theory of functioning of an axis with PID control .......................... 11-17 Motors check data function .......................................................... 11-21 Range of runs carried out by movements with potmeter feedback .. 11-24 Equipment mechanical dimensions............................................... 11-27 Data relative to single fault potmeter controls ............................... 11-31 Spot Film Device cassette and shutters run .................................. 11-35 11.3.4.1 Calculation of the cassette run.................................... 11-36 11.3.4.2 Calculation of the shutters run ................................... 11-41 Safety aspects for PDI-controlled movements ................................ 11-43

11.2 Group 300 PDI controlled motor data............................................ 11-17

11.3 Group 400 / 500 / 600 Dimensions and runs .............................. 11-24

11.3.5

11.4 Position 701 EEprom copy ............................................................ 11-45 11.5 Position 711 Clock settings and reset alarm memory .................... 11-46 11.6 Position 721 Test Spot Film Device and table life .......................... 11-4711.6.1 11.6.2 Spot Film Device test.................................................................... 11-48 Table test ..................................................................................... 11-50

11.7 Position 731 Remote service function ............................................ 11-52 11.8 Position 751 Alarms memory......................................................... 11-53 11.9 Position 850 Table cycles memory ................................................. 11-61

12 13

SINGLE FAULT OPERATING LOGIC FUNCTIONALITY13.1.1 13.1.2

12-1 13-1

13.1 Collision ............................................................................................ 13-1Anticollision barrier........................................................................ 13-5 Anti entrapment device................................................................... 13-6

13.2 Compressor ....................................................................................... 13-7 13.3 Collimator.......................................................................................... 13-8 13.4 Table automatic positioning............................................................. 13-11

(Rev. 3)

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APOLLO


14

OPERATING MODE14.1.1 14.1.2 14.2.1 14.2.2

14-1

14.1 Spot Film Device ................................................................................ 14-1"Standard radiography" performance block diagram........................ 14-2 "Rapid sequence" block diagram ..................................................... 14-3 "Standard tomography" block diagram............................................ 14-5 "Sequential tomography" block diagram.......................................... 14-6

14.2 Standard tomographic ....................................................................... 14-4

14.3 Direct................................................................................................. 14-7 14.4 Digital ................................................................................................ 14-814.4.1 14.5.1 14.5.2 14.6.1 "Digital radiography" block diagram................................................ 14-9 "Digital tomography" block diagram .............................................. 14-11 "Digital tomography" block diagram .............................................. 14-12 "Stepping angio" block diagram .................................................... 14-14

14.5 Digital Tomography.......................................................................... 14-10

14.6 Angiographic.................................................................................... 14-13

15 16

EMERGENCY END RUN HARDWARE ADJUSTMENT16.1.1 16.1.2

15-1 16-1

16.1 A3 output PCB................................................................................... 16-1Collimator axle speed adjustment ................................................... 16-1 Adjustment of collimator axle torque gain (armature reaction) ......... 16-3

16.2 Compressor PCB................................................................................ 16-4

17

THREE-PHASE INVERTER

17-1

17.1 Inverter input/output functions......................................................... 17-2 17.2 Inverter hardware setting................................................................... 17-3 17.3 Inverter software parameters setting .................................................. 17-317.3.1 17.3.2 Parameters with data modified by Villa Sistemi Medicali ................. 17-4 Parameters that maintain the default settings................................. 17-6

17.4 Access to parameters for writing ........................................................ 17-7 17.5 Procedure for restoring the default parameters .................................. 17-8

18 19

FUNCTION OF THE OUTPUTS PCB LEDS CHECKING THE RADIOGRAPHIC EXPOSURE RESULTS19.1.1 19.1.2 19.1.3 19.2.1

18-1 19-1

19.1 Spot Film Device adjustment ............................................................. 19-1Checking the longitudinal positioning of the cassette ...................... 19-2 Checking the transversal positioning of the cassette ....................... 19-3 Checking the positioning of the shutters......................................... 19-3 Alignment of the X-ray beam with collimator diaphragm ................. 19-4

19.2 Centering the collimator, checking the X-ray field.............................. 19-4 19.3 Alignment of X-ray beam with light beam .......................................... 19-6 19.4 Collimator adjustment ....................................................................... 19-8APOLLO

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(Rev. 3)


20

DIAGNOSTICS AND TROUBLESHOOTING

20-1

20.1 Troubleshooting for displayed diagnoses............................................ 20-3 20.2 Troubleshooting for faults or malfunctions not recognised by the processor ................................................................................... 20-3920.2.1 20.2.2 20.2.3 Table............................................................................................ 20-39 Spot Film Device (not available on All Digital version) ................. 20-41 Collimator .................................................................................... 20-44

21

MAINTENANCE AND CLEANING

21-1

21.1 Maintenance the operator can carry out ............................................ 21-2 21.2 Maintenance that can be carried out by the Authorised Technician ... 21-3

22

WIRING DIAGRAMS AND DRAWINGS

22-1

22.1 List of wiring diagrams and drawings ................................................ 22-2

23

SPARE PARTS

23-1

No part of this publication may be reproduced, transmitted, transcribed or translated without the prior written consent of Villa Sistemi Medicali. This manual is the English translation of the Italian original manual version.(Rev. 3)

v

APOLLO



APOLLO

vi

(Rev. 3)

SERVICE MANUAL Introduction

1

INTRODUCTION

G

NOTE: This manual has been updated to reflect the state of the product with which it is sold, to provide a proper reference while troubleshooting and repair operations, commonly carried out by the service engineer, are being performed. The manual might not reflect variations to the product if they do not affect how it works. The remote controlled table Apollo is an X-ray equipment that allows to perform general X-ray examinations. In particular, because of its connected accessories, the equipment is an optimal solution for examinations where the use of contrast liquids is required. The present manual provides the user with instructions for a safe and efficient use of the equipment. The equipment must be used in accordance with the procedures contained in the manual and shall never be used for other purposes than those provided by the manual itself. Apollo is an electromedical equipment and, as such, it can be used solely under the supervision of a physician or of highly qualified personnel with the necessary competence in matter of protection from X-rays. The user is responsible for the fulfilment of the legal requirements regulating the installation and the functioning of the equipment itself.

1.1

Symbols used in this manual

G

Indicates a NOTE; please pay particular attention when reading the topics identified by such symbol.

Indicates a WARNING; topics identified by this symbol refer to the patient and/or operator safety aspects.

(Rev. 3)

1-1

APOLLO

SERVICE MANUAL Introduction

1.2

How to contact VILLA SISTEMI MEDICALI technical serviceFor any technical queries please contact the following: Telephone number +39 02 488591 Fax number +39 02 48859222 E-mail: [email protected]

APOLLO

1-2

(Rev. 3)

SERVICE MANUAL Safety aspects

2

SAFETY ASPECTSWARNING: All information contained in the present chapter must be carefully read and, where provided, must be applied in order to avoid damage to the equipment or to people. Villa Sistemi Medicali designs and manufactures equipment in compliance with safety requirements; moreover, it provides all necessary information for an appropriate use and warnings about the dangers associated with X-ray generators. Villa Sistemi Medicali does not take any responsibility for: the use of Apollo equipment different from the one it was originally designed for damages to the equipment, to the operator, to the patient caused by both wrong installation and maintenance not in conformity with the procedures contained in the equipment's user and maintenance manuals, and by incorrect operating techniques mechanical and/or electrical modifications performed during or after installation.

Only Villa Sistemi Medicali authorised personnel can provide technical assistance for the equipment. Only authorised personnel may remove the protections of the electrical cabinet and of the equipment, and access the parts under tension and the moving parts.

(Rev. 3)

2-1

APOLLO


2.1

WarningsApollo is suited for use in hospital, therefore the line connection may not be carried out in buildings with domestic-type power supply lines. The equipment was not designed to be used in the presence of vapours, anaesthetic mixtures inflammable when in contact with air, oxygen or nitrous oxide. In order to prevent risks of short-circuit and corrosion, avoid the infiltration of water of other liquids in the equipment. Before cleaning the equipment, always ensure it is disconnected from the line. All movements are controlled by a powerful and sophisticated electronic microprocessor system. Speeds, positions, starts and stops of these movements are controlled and managed by the equipment's logic. Safety aspects are fundamental in this logic in order to ensure the maximum safety both for the patient and the operator. Nevertheless, the operator MUST ALWAYS PAY CLOSE ATTENTION when a movement is activated. Press the EMERGENCY red buttons located on the control console and on the front side of the equipment in case of danger. These buttons will immediately stop any movement and function. They are a valid instrument for the operator in addition to the intrinsic safety devices of the equipment. Before activating motorised parts, such as the tilting, the tabletop, or the angulation, ensure that the patient is correctly positioned and that their legs and arms are positioned within the shape of the tabletop. If possible, use the support handgrips. During the motorised movements, no objects interfering with the movements should be in proximity of the table. Pay close attention to people in the X-ray room. Although Apollo was designed with a high degree of protection from electromagnetic interference, the equipment must be installed at a certain distance from the electrical energy transformation cabins, from static uninterruptible power supplies, from walkie-talkies and cellular phones. The latter two may only be used at the distances from any element of the equipment reported in the following page.

APOLLO

2-2

(Rev. 3)


R.F. source power 10 mW 100 mW 1W 10 W 100 W

Distance (m) 0.3 1 3 8 30

Instruments or systems used in close proximity to Apollo must be in compliance with the Electromagnetic Compatibility regulations. Noncompliant instruments, with known scarce immunity to electromagnetic fields, must be installed at a distance of at least 3 mt (9.84 feet) from Apollo and must be powered through a dedicated electric line. Apollo is suited for use in the following electromagnetic environment:Electromagnetic emissions Irradiated and conducted emissions CISPR 11 Conformity A class EMC usage environment Apollo can be connected to a power supply line different from the domestic line. Apollo generates Radio Frequency energy only for internal functioning. The generated R.F. level does not cause interference with the electrical devices used nearby. Apollo can be connected to a power supply line different from the domestic line. Apollo can be connected to a power supply line different from the domestic line. Apollo can be connected to a power supply line different from the domestic line.

Group I

Emitted harmonic EN 61000-3-2 Flicker EN 61000-3-3 tension/emission fluctuations EN 60601-1-2 immunity (EN 61000-4-2 /3 /4 /5 /6 /8 /11)

Complying

Complying

Complying

In case of line voltage dips that last longer than what can be sustained by the table electronic control system, the examination in progress may be cancelled. As a consequence, the tabletop and scan movements, as well as the angulation, that may cause damage to the patient become inhibited. The Spot Film Device will be initialised and, in case the cassette is loaded, on the display a warning will ask the operator to remove it before proceeding.

(Rev. 3)

2-3

APOLLO


Apollo cannot be installed in operating theatres. Apollo must be powered off when using the electrosurgery cutter or similar devices. Clean and, when necessary, disinfect the parts that may come into contact with the patient by following the procedures provided in the chapter 21.

APOLLO

2-4

(Rev. 3)


2.2

Radioprotection warningsVilla Sistemi Medicali designs and manufactures equipment in compliance with safety requirements; moreover, it provides all necessary information and warnings about the dangers associated with equipment connected to X-ray generators. The personnel authorised to perform X-ray examinations must observe all regulations regarding the protection against ionizing radiation as reported below: Use dedicated protections (leaded clothing) to protect the patient from X-rays diffused in the areas adjacent to the one to be X-rayed. During X-ray examinations, only the patient is allowed to stay in the room. Medical and paramedic personnel or specifically authorised personnel, if required by the examination, may also be present only if wearing radioprotective clothing. The personnel in the room, during the examination in progress, must stay in the areas indicated in the figures below.

8 7 6 5 4 3 Occupation area (see Figure 2-2)

2 1

Figure 2-1: Horizontal table, front view

G

NOTE: The front view shows a 600x600x2000 mm (23.6"x23.6"x78.7") occupation area as specified by the applied regulations. In reality, because the I.I. Spot Film Device, tube group has an excursion of 1600 mm (62.9"), the total occupation zone is the one showed in Figure 2-2. Such area takes into account the above-mentioned excursion.

(Rev. 3)

2-5

APOLLO


Occupation area 600x2380 mm (23.6"x93.7") H = 2000 mm (78.7")

Figure 2-2: Horizontal table, plan view

Occupation area (see Figure 2-4)

G F E D C B A1400 mm (55.1")

Figure 2-3: Vertical table, front view

APOLLO

2-6

(Rev. 3)


450 mm (17.7")

Occupation area 600x600 mm (23.6"x23.6") H = 1700 mm (66.9")

Figure 2-4: Vertical table, plan view The maximum values of the radiation diffused in the indicated areas are reported in the following table. Such values have been detected as reported in the safety regulation IEC 601-1-3 and, in particular, for technique factors of 120 kV, 3 mA continuative emission.Figure 1 1 1 1 1 1 1 1 3 3 3 3 3 3 3 Ref. 1 2 3 4 5 6 7 8 A B C D E F G H from the ground 350 mm (13.8") 600 mm (23.6") 1000 mm (39.4") 1200 mm (47.2") 1400 mm (55.1") 1600 mm (63.0") 1800 mm (70.9") 2000 mm (78.7") 350 mm (13.8") 600 mm (23.6") 1000 mm (39.4") 1200 mm (47.2") 1400 mm (55.1") 1600 mm (63.0") 1700 mm (66.9") Dosage 0.06 mGy/h 0.09 mGy/h 2.75 mGy/h 10.5 mGy/h 13.9 mGy/h 13.4 mGy/h 9.6 mGy/h 6.2 mGy/h 1.1 mGy/h 1.9 mGy/h 3.3 mGy/h 4.1 mGy/h 4.4 mGy/h 4.1 mGy/h 3.5 mGy/h

(Rev. 3)

2-7

APOLLO


2.3

Environmental risks and disposalSome of Apollo components contain material and liquid that, at the end of the equipment life-cycle, must be disposed of at the recycling centres appointed by the Local Health Units. In particular, the equipment contains the following materials and/or components: Reducers: lubricating oil, steel, aluminium Motor: iron, copper, hard plastic material casings Electric cabinet: iron, aluminium, copper, non-biodegradable plastics, vetronite for printed circuits.

APOLLO

2-8

(Rev. 3)


2.4

Used symbols

Symbol

Description Equipment with Type B applied parts Some components contain material and liquid that, at the end of the equipment life-cycle, must be disposed of at the recycling centres appointed by the Local Health Units

N R S T

Alternating current Neutral conductor connection point Three-phase line conductors connection point Ground-fault protection Warning: consult the accompanying documentation Dangerous voltage

(Rev. 3)

2-9

APOLLO



APOLLO

2-10

(Rev. 3)

SERVICE MANUAL Description

33.1

DESCRIPTIONID labels

7 3 4

5 2 1b

(Rev. 3)

3-1

APOLLO


3.1.1

ID labels "CE" version1a Apollo features label (located on the electric cabinet) 1b Apollo ID label (located on the equipment)

2 Spot Film Device features label

3 Collimator features label

4 "Total Filtration" label

5 "Mechanical moving parts" label

6 "Connect TV chain only" label (inside the electric cabinet)

7 Compression coupling ID label

APOLLO

3-2

(Rev. 3)


3.1.2

ID labels "CE" plus "C-CSA-US" version1a Apollo features label (located on the electric cabinet) 1b Apollo ID label (located on the equipment)

1c C-CSA-US certification plate (located on the electric cabinet) 2 Spot Film Device features label 3 Collimator features label

4 "Total Filtration" label

5 "Mechanical moving parts" label

6 "Connect TV chain only" label (inside the electric cabinet) 7 Compression coupling ID label

(Rev. 3)

3-3

APOLLO


3.2

DescriptionThe remote controlled Apollo table is the latest development of remote controlled tables produced by Villa Sistemi Medicali. Apollo table is available in the traditional configuration with a Spot Film Device or in the "All Digital" version, where the Spot Film Device is not present and the table necessarily has to be completed by Digital Image acquisition system. The most recent features applied to this type of table have been incorporated and further improved. In particular: the mechanical construction the cassette's loading/unloading inside the SFD the removal of components' numerous supporting frames, so that the components become "self-supporting". The fundamental functional concepts of the Apollo table are: smallest possible space occupied patient coverage simply through the longitudinal movement of the U arc elevating tabletop with parts rotation system as opposed to sliding system modern, concept winning appearance and design operator's rear access without barriers towards the patient reduced skin-to-film distance or skin-to-I.I. entrance distance in the "All Digital" version carbon fibre or plastic tabletop, with slight curvature or flat surface and integrated accessories holder profiles reduced I.I.-film distance to avoid the parallax correction reduced-dimension console with new functional concepts. Movements and complex functions are controlled by the remote-control console located in the protected X-ray area. The main table movements are replicated on the control panel on the side of the table. All electric and electronic control and logic elements, except for the console, are grouped in a single electric cabinet, which also houses the control modules for the system accessories. The Apollo table, in its traditional configuration, is equipped with a Spot Film Device that permits the use of commonly used cassettes of any type. The format division program is very complete and is described in another paragraph.

APOLLO

3-4

(Rev. 3)


An automatic collimator, controlled by a central logic, sets the limits for the irradiated area. The collimator can be of square-rectangular collimation type or iris type, which has circular field collimation in addition to square rectangular collimation. The "All Digital" version is equipped always with an iris type collimator. To meet the requirements of fluoroscopic modality and image acquisition by means of digital systems, the table is setup to accept image intensifiers from a minimum of 9" (nominal) maximum input field up to a maximum of 16" (nominal). The intensifier is fixed by default by docking it to the Spot Film Device or to an equivalent support in the "All Digital" version, by means of an upper mount anchor plate. As an option, a device called "elevating I.I." is available. This allows to raise the input surface of the I.I. closer to the patient when the cassette is not in the exposure position. In "All Digital" version, the II is located closer to table top, consequently I.I. lift is not available in this configuration. All movement controls are of "dead man" type. Apollo was designed and built in compliance with European directives for obtaining the CE mark as specified in the European Directive 93/42 for Medical Devices, guaranteeing the highest safety for both the operator and the patient. Apollo is a universal table for radiological diagnosis, built to satisfy all needs. It can be employed for the examination of the digestive tract, of the cranium, and of the skeleton, urographies, myelographies, vascular and lungs examinations, bronchography. When fitted with a digital acquisition system, it can also be used for angiographies. The ID code of the equipment varies according to the type of collimator and to the voltage. Apollo is available with both standard and optional accessories. The following table lists all the accessories and divides them as standard, i.e. those usually coming with the equipment, and optional accessories, which must be specifically requested when ordering the equipment.

(Rev. 3)

3-5

APOLLO


Ref. A B C D E F

Description Block patient footrest Headrest Patient support handgrip (N. 2 pieces) Leg support (N. 2 pieces) Band-tensioner with compression band Lateral cassette holder

Type of accessory Standard Standard Standard Optional Optional Optional

B C A F E

D

Figure 3-1: Curved Tabletop accessories

B A

C

F D EFigure 3-2: Flat Tabletop accessories All accessories are easily applied as they are mounted directly on the tabletop's profile.

APOLLO

3-6

(Rev. 3)

SERVICE MANUAL Technical data

44.1

TECHNICAL DATATechnical features

General features Type of equipment Manufacturer Type of equipment and classification in compliance with IEC 60601-1 standard regulation Grade of protection in compliance with IEC 60529 standard regulation Operating mode Use Apollo Villa Sistemi Medicali S.p.A. 20090 Buccinasco (MI) Italy class I with Type B applied parts equipment non protected against penetration of liquids continuous functioning equipment not suitable for use in presence of inflammable anaesthetic mixtures

Electric features Available voltage Frequency Maximum current Fuses on safety isolating transformer Equipment protection Power Line impedance Load voltage drop 3N~ 380-400 Vac 10% 3N~ 415-480 Vac 10% 50-60 Hz 7 A @ 380-400 Vac 10% 6 A @ 415-480 Vac 10% 8 AT @ 380-400 Vac 7 AT @ 415-480 Vac 8 A with magnetothermic 6 kVA < 1.0 @ 380-400 Vac 10% < 1.0 @ 415-480 Vac 10% < 2 % @ 380-400 Vac 10% < 2 % @ 415-480 Vac 10%

(Rev. 3)

4-1

APOLLO


Mechanical features Weight Height vertical table Height horizontal table and max SID Width from the front end of the Spot Film Device to the rear end of the main beam Total width completely retracted Length (horizontal table) Total length with +90 /-90 max SID Setup for I.I. I.I. max size Minimum curved tabletop height from the ground (with Spot Film Device) 895 Kg (1973 lbs) SFD version 830 kg (1830 lbs) All Digital 2500 mm (98.4") 3180 mm (125.2") 1590 mm (62.6") 1920 mm (75.6") 2420 mm (95.3") 4960 mm (195.3") standard fixed mount optional lift 16 inch CENTRE minimum 600 mm (23.6") with 9" I.I. 600 mm (23.6") with 12" I.I. 695 mm (27.4") with 16" I.I. 775 mm (35.0") minimum 618 mm with 9" I.I. 618 mm with 12" I.I. 713 mm with 16" I.I. 793 mm minimum with 9" I.I. with 12" I.I. with 16" I.I. Minimum flat tabletop height from the ground (All Digital version) minimum with 9" I.I. with 12" I.I. with 16" I.I. CENTRE 600 mm (23.6") 600 mm (23.6") 637 mm (25.1") 717 mm (28.2") 618 mm 618 mm 655 mm 735 mm

Minimum flat tabletop height from the ground (with Spot Film Device)

EDGE 668 mm (26.3") 668 mm (26.3") 763 mm (30.0") 843 mm (33.2") (24.3") (24.3") (28.1") (31.2") EDGE 668 mm (26.3") 668 mm (26.3") 705 mm (27.7") 785 mm (30.9") (24.3") (24.3") (25.8") (28.9")

Minimum curved tabletop height from the ground (All Digital version)

Max height tabletop centre from the ground Distance tabletop centre upper side beam Distance upper tabletop edge upper side beam

1400 mm (55.1") curved tabletop 1418 mm (55.8") flat tabletop 185 mm (7.3") curved tabletop 203 mm (7.9") flat tabletop 117 mm (4.6")

APOLLO

4-2

(Rev. 4)


Mechanical features Distance rear side beam internal tabletop edge (with centered tabletop) Distance rear side beam internal tabletop edge (with internal tabletop end run) Electric cabinet containing all electric and electronics controls, including the TV-chain control or the digital module Max patient weight with all movements Runs Tilting Lift Longitudinal tabletop Transversal tabletop Scan Source-to-film distance Angulation Compressor (cone run in X-ray field) Tube rotation I.I. lift Speed Tilting Lift Transversal tabletop Scan slow 4.5 /sec fast 6.5 /sec (adjustable) 25 mm/sec (1"/sec) (adjustable) 50 mm/sec (2"/sec) 10% (fixed) from 30 mm/sec (1.2"/sec) to 200 mm/sec (7.9"/sec) (adjustable) with speeding step for small or wide movements 25 mm/sec (1"/sec) 10% (fixed) 11.2 /sec (adjustable) 25 mm/sec (1"/sec) (adjustable) 40 mm/sec (1.6"/sec) 20% (fixed) + 90 / - 90 800 mm (31.5") fixed 320 mm (12.6") 1600 mm (62.9") 1000 - 1500 mm (39.4" 59.1") + 40 / - 40 250 mm (9.8") + 180 / - 90 38 mm (1.5") 765 mm (30.1") 605 mm (23.8")

520 x 550 x 1950 mm (20.4" x 21.6" x 76.8") 284 kg (626.1 lbs)

Source-to-film distance Angulation Compressor I.I. lift (optional)

(Rev. 4)

4-3

APOLLO


Features data and measures Distance X-ray field centre / table head extremity Distance X-ray field centre / table feet extremity Skin-to-film distance Film-to-fixed I.I. distance Skin-to-I.I. distance with fixed I.I. (SFD versions) Skin-to-I.I. distance with fixed I.I. (All Digital versions) Skin-to-I.I. distance with I.I. lift completely lowered Skin-to-I.I. distance with I.I. lift completely lifted 390 mm (15.4") 390 mm (15.4") 65 mm (2.6") for curved tabletop 83 mm (3.3") for flat tabletop 19 mm (0.7") (without parallax correct.) 84 mm (3.3") for curved tabletop 102 mm (4.0") for flat tabletop 26 mm (1.0") for curved tabletop 44 mm (1.7") for flat tabletop 84 mm (3.3") for curved tabletop 102 mm (4.0") for flat tabletop choice of 45-65 mm (1.7"-2.5") for curved tabletop choice of 63-83 mm (2.5"-3.3") for flat tabletop 138 mm (5.4") for curved tabletop 133 mm (5.2") for flat tabletop 388 mm (15.3") for curved tabletop 383 mm (15.1") for flat tabletop from 3 kg (6.6 lbs) to 15 kg (33.1 lbs) with 0.5 kg (1.1 lbs) step

Minimum distance compressor cone tabletop Max distance compressor cone tabletop Compression force Tabletop Size

2379 x 750 mm (93.7" x 29.5") for curved tabletop 2356 x 738 mm (92.7" x 29.0") for flat tabletop 2214 x 650 mm (87.2" x 25.6") for curved tabletop 2214 x 554 mm (87.2" x 21.8") for flat tabletop policarbonate carbon fibre with Rohacell filler < 0.5 mm Al eq @ 100 kVp SEV 2.7 mm Al < 0.3 mm Al eq @ 100 kVp SEV 2.7 mm Al integrated smooth with curvature smooth flat 4-4(Rev. 4)

Radio-transparent area size

Standard material Optional material (for curved tabletop only) Filtration for standard model Filtration for carbon fibre model (for curved tabletop only) Accessories holder guides SurfaceAPOLLO


Accessories for curved tabletop Footrest (standard) Headrest and shoulder rest (standard) Handgrips (standard) Compression band (optional) Legs support (optional) Lateral cassette holder (optional) Accessories for flat tabletop Footrest (standard) Headrest and shoulder rest (standard) Handgrips (standard) Compression band (optional) Legs support (optional) Lateral cassette holder (optional) support surface 300 x 550 mm (11.8" x 21.6") ca with shoulder stoppers ergonomic with winder adjustable adjustable for lateral projections support surface 400 x 600 mm (15.7" x 23.6") ca with cushions and shaped shoulder stoppers integrated ergonomic with winder adjustable adjustable for lateral projections

Spot Film Device (NOT present on All Digital version) Accepted cassette sizes Divisions on a line Crossed divisions Spot Film Device movement Operating mode Minimum fluoro-to-exposure switching time Maximum fluoro-to-exposure switching time Average speed in rapid sequence Leaded shutters Grid Head I.I. fixing AEC from 13x18 (5"x7") to 35x43 (14"x17") from 1 to 4 in 4 and in 6 with feed belts without tray standard program and rapid sequence 0.8 sec 1.2 sec 2 im/sec integrated vibrating, parkable pre-set pre-set

(Rev. 4)

4-5

APOLLO


Collimator 2 axis collimator rectangular and square 3 axis collimator rectangular, square and iris Additional filtration (optional) for both with additional filters movement models (2 mm Al / 1 Al + 0.1 mm Cu / 1 Al + 0.2 mm Cu) manual or motorized automatic Limitation manual: by means of joystick on console and buttons on collimator Operating mode automatic with / without Hold mode manual Light for centering with timed 100W lamp (min 160 lux @ 1 m) or with on-demand switching off Minimum dimension X-ray field @ 1m < 1 cm2 (0.39 inch2) X-ray field coverage @ 1 m > 43 cm2 (17 inch2) Stray radiation 45 mR/h @ 150 kVp 350W Total filtration rectangular collimator 0.5 mm Al eq @ 100 kVp SEV 2.7 mm Al Total filtration iris collimator 1.0 mm Al eq @ 100 kVp SEV 2.7 mm Al Tomography Type Layer max height Layer increment Layer automatic increment Speed Angles Tomography exposure times (sec) semiarc / plane with electronic algorithm 350 mm (13.8") with 1 mm (0.04") step selectable with automatic increment depending on the tomo angle 11.2 22.4 /sec (adjustable) 7 - 20 - 30 - 45 1st 2nd 3rd 4th Grades speed speed speed speed 7 0.6 0.5 0.4 0.3 20 1.8 1.3 1.0 0.9 30 2.6 2.0 1.6 1.3 45 4.0 3.0 2.4 2.0 from right to left or vice versa (adjustable) sequential program with forward and back exposures until divisions are completed with continuous layer automatic increment and return to the vertical position at the end of each exposure without stops tomography is allowed for variable scan positions depending on the selected angle and layer

Direction Sequential tomography

Scan movement range

APOLLO

4-6

(Rev. 4)


Stepping angio (optional) Modality Automatic only with digital acquisition system

step length: depending on the selected I.I. manual: adjustable with 1 mm step

Direction Interface Controls Console movements Console functions User interface Controls type Safety on movements Environmental conditions Operating conditions

selectable integrated with digital generator and scan

controls with joystick on table side with buttons controls with graphic display, function keys and LED signalling "Dead man" single fault on the HW chain driving movement and feedback

Temperature: Humidity: Pressure: Temperature: Humidity: Pressure:

from +10 to +40 from 30 to 75 % from 700 to 1060 hPa from -20 to +70 95% non condensing > 630 hPa

Conditions for transport and storage

(Rev. 3)

4-7

APOLLO


4.2

Formats division table in centimeters

13x18

18x13

18x24

9x24

9x12

24x18

12x18

24x24

12x24

12x12

24x30

12x30

30x24

15x24

15x12

10x24

10x12

30x30

15x30

10x30

18x43

43x18

21x18

14x18

15x40

40x15

20x15

13x15

10x15

20x40

10x40

40x20

20x20

13x20

10x20

30x35

15x35

10x35

35x30

17x30

12x30

30x40

15x40

10x40

40x30

20x30

13x30

10x30

35x35

17x35

12x35

35x43

17x43

12x43

43x35

21x35

14x35

11x35

GAPOLLO

NOTE: The first number of the format refers to the tabletop transversal direction (patient right-to-left). The measure indicated on the various divisions is nominal.

4-8

(Rev. 4)


4.3

Formats division table in inches

5x7

7x5

8x10

4x10

4x5

10x8

5x8

10x12

5x12

12x10

6x10

6x5

4x10

4x5

9.5x9.5

4.7x9.5

3x9.5

7x17

17x7

8.5x7

5.7x7

4.3x7

11x14

5.5x14

3.7x14

14x11

7x11

4.7x11

3.5x11

14x14

7x14

4.7x14

14x17

7x17

4.7x17

17x14

8.5x14

5.7x14

G

NOTE: The first number of the format refers to the tabletop transversal direction (patient right-to-left). The measure indicated on the various divisions is nominal.

(Rev. 3)

4-9

APOLLO


4.4

Standards and regulationsApollo was designed and built in compliance with the following regulations: IEC/EN 60601-1 Medical Electrical Equipment Part 1: General requirements for safety 1: collateral standard: safety requirements for Medical Electrical Systems IEC/EN 60601-1-2 Medical Electrical Equipment Part 1: General requirements for safety 2: collateral standard: electromagnetic compatibility requirements and test IEC/EN 60601-1-3 Medical Electrical Equipment Part 1: General requirements for safety collateral standard: general requirements for radiation protection in diagnostic X-ray equipment IEC/EN 60601-2-32 (with exclusion of clause 22.4.5) Medical Electrical Equipment Part 2: Particular requirements for the safety of associated equipment of X-ray equipment.

0051

The EC symbol certifies the conformity of Apollo to Directive 93/42/EEC.

Versions C-CSA-US, knowable by the identification code with last digit "1" (ex 9784xxxxx1), are produced in compliance, more than above listed standards, also with as indicated below: CFR 21 Code Federal Regulation. Sub Chapter J CAN/CSA C22.2 No 60601-1-M90 Safety of Medical Electrical Equipment, Part 1, General requirements for safety UL Std No 60601-1 (2nd edition) Safety of Medical Electrical Equipment, Part 1, General requirements for safety.

APOLLO

4-10

(Rev. 3)


4.5

Dimensions

A: with IB 9 min. 600mm (23.6") max 1400mm (55.1") with IB 12 min. 695mm (27.4") max 1400mm (55.1") with IB 16 min. 775mm (30.5") max 1400mm (55.1") B: with IB 9 min. 1880mm (74.8") max 2680mm (105.5") with IB 12 min. 1975mm (77.8") max 2680mm (105.5") with IB 16 min. 2055mm (80.9") max 2680mm (105.5")

Figure 4-1

(Rev. 3)

4-11

APOLLO



APOLLO

4-12

(Rev. 3)

SERVICE MANUAL Pre-installation

5

PRE-INSTALLATIONThe instructions on the following pages guarantee that the installation performed will ensure the remote-controlled Apollo table will work properly. The Manufacturer can provide any technical consultancy and assistance necessary right from the pre-installation stage (if requested, to check the positioning of the equipment inside the X-ray room). The room should be prepared for the installation of the Apollo table according to the choice of the most suitable floor plate (Figure 5-1 and Figure 5-2). The standard floor fixing plate (Figure 5-1) is suitable for slabs with a bearing capacity of more than 2400kg/m2 (499lbs/feet2) (weight of machine fitted with 16" IB and considering a patient of 150kg / 330.7lbs = 1160kg / 2557.5lbs on a support surface of 0.48m2 / 5.16feet2).

G

NOTE: The "All Digital" version is only slightly lighter than the Spot Film Device version so its not convenient to differentiate the calculation of the bearing capacity needed for installation. Remove the surface of the floor in an area measuring 420x1310 mm (16.5"x51.6") until you reach the concrete of the slab, so that the top surface of the plate is flush with the floor. The concrete surface of the slab, under the plate, must be rough enough to ensure the concrete to be poured adheres properly. Position the plate and carefully level it so that the surface obtained is as level as possible. The plate already has threaded holes and M16 bolts for the anchorage of the base; these holes must be protected (e.g. by inserting the fixing bolts) so that they are not blocked up during installation; pour the concrete with a cement/sand ratio of 1:2.5, remove the surplus and let it dry for six hours.

Figure 5-1: Standard floor fixing plate(Rev. 3)

5-1

APOLLO


If the bearing capacity of the slab is not sufficient (less than 2400 kg/m2 / 499 lbs/feet2), a weight distribution plate is available and must be requested at the time of the order (purchase code 5584902500 Figure 5-2).

Figure 5-2: Weight distribution plate This plate can be installed on the floor in two different ways: 1. Sunk into the floor 2. Fixed to the floor. In the first case (1) follow the instructions given above for a plate of a smaller size and be sure to remove the upper surface of the floor over an area of 2700x1600 mm (106.3"x63"). In the second case (2), the plate must be fixed to the floor taking advantage of the relative fixing holes and masked through the construction of raised section that covers the structure of the plate itself.

G

NOTE: The weight distribution plate is not symmetrical, so its important to position it in the correct way (Figure 5-2).

APOLLO

5-2

(Rev. 3)


5.1

Space requirements

G

NOTE: In order to unload the main body of the device from the truck, it is necessary either that the truck has an elevating lift or to use an elevating fork cart. When performing the overview of the location (installation room, aisles, doors ecc.) please remind that the main body of the device after having removed the wood box has dimensions given in Figure 5-3.

Figure 5-3 The minimum height of the installation room must be greater than 2550 mm (100.4"); operating room on the front is advised to be 1000 mm (39.4"); on the sides leave room as detailed in Figure 5-5.

(Rev. 3)

5-3

APOLLO


Under floor conducts (Figure 5-4) must meet the following requirements: C: suggested section: 20x10 cm (7.9"x3.9") / max distance between the pit and the cabinet: 9 m (29.53 feet). D: suggested section: 10 cm (3.9") / max distance between the cabinet and the control panel 14 m (45.93 feet).

G

NOTE: If distances are larger than those indicated above (C and D) ask adequate length of connecting cables at order. WARNING: The electrical cabinet is fitted with two wheels so that the rear can be more easily accessed during installation and maintenance.

(*)

The minimum distance with cabinets in position A (inside the Apollo tilting area) = 800 mm (31.5") The minimum distance with cabinets in position B (outside the Apollo tilting area) = 600 mm (23.6")

Figure 5-4: Minimum dimensions necessary for Apollo installation without any limit on table movementsAPOLLO

5-4

(Rev. 3)


Figure 5-5: Minimum dimensions necessary for Apollo installation with Chest Stand without any limit on table movements

(Rev. 3)

5-5

APOLLO


5.2

Electrical provisions POWER SUPPLY FREQUENCY ABSORBED POWER (table only) ABSORBED CURRENT (table only) APPARENT LINE RESISTANCE

380-400Vac 3 phase +Ground 415-480Vac 3 phase +Ground 50-60Hz 5kVA 7A < 1

G

NOTE: Generally the power required for the fitting out of one complete X-ray room including the Apollo table equals 25-30kVA. WARNING: The equipment can be connected directly to the mains or in cascade with the ray generator, a preferable alternative because, when the generator is powered down, the table and the accessories connected to it (e.g. the image capturing system or chest stand) are turned off as well. In both cases the wires of the three-phase power supply must have a crosssection of at least 4.0 mm. Connection directly to the mains: Make provision for an automatic switch with fuse as per the current regulations in the country of installation. Connection to the generator: Check the generator manual to make sure that the connection points are right for the load and insulation values. The general grounding must respond to the standards in force. If the grounding of the equipment is not good enough, it might jeopardise the safety of the operator and/or cause the malfunctioning of the electronic equipment.

APOLLO

5-6

(Rev. 3)


5.3

Adaptation to the mains voltageThe insulation and power feed transformer (T1) of the Apollo table is fitted with two sets of (R S T) primary winding power supply terminals. One group is for connecting the 380V power supply, the other 400V. The equipment can be supplied with provision for a 380V or 400V connection. This pre-disposition must be specified on ordering and will be incorporated in the factory before shipment. Before powering up the equipment, make sure that the mains voltage corresponds with the predisposition of the equipment by checking that: the rating plate shows the right voltage (the position of the rating plate is described in paragraph 3.1) the primary main power supply insulation transformer T1 connection corresponds with the mains voltage.

5.4

Environmental conditionsThe data in paragraph 4.1 must be complied with for the environmental operating and transport/storage conditions.

(Rev. 3)

5-7

APOLLO



APOLLO

5-8

(Rev. 3)

SERVICE MANUAL Installation

6

INSTALLATIONWARNING: During the mechanical installation of the equipment and the electrical connection described below, the safety regulations in force must be respected and the precautions described below must be taken: wear accident prevention clothing (boots, gloves, goggles when necessary) always work in conditions of utmost safety and avoid carrying out procedures that put you or others at risk make sure that no electricity is supplied to the equipment unless the installation is completed or said electricity is required for installation purposes. when the unit is ready to be powered up and while the installation is in the final phases of completion, make sure the power supply is cut off by means of a switch before accessing any of the parts that can be a danger.

G

NOTE: The instructions present on this chapter are referred to a standard unit versions (with Spot Film Device). For "All Digital" versions, all instructions relevant to SFD must be intended to the I.I. support frame assy. This I.I. support frame has mechanical characteristics equal to the SFD one, but any devices for cassettes, grid and shutters are not present. For delivery, handling and assembly purposes, the machine is broken down into units that must be put together: Base with beam and column (Assembly 1) Tube and collimator support arm (Assembly 2) Spot Film Device (Assembly 3) Left- and right-hand tabletop support arm (Assembly 4) Tabletop (Assembly 5)

v v v v v

Assemble the units by following the instructions below.

(Rev. 3)

6-1

APOLLO


6.1

Base positioning with beam and columnThe base assembly with beam and column are shipped in a crate as shown in Figure 6-1. WARNING: Before positioning the assembly on the anchorage plate, check that this is flat with respect to both axes. Do not use the grubs positioned on the left side of the basement to achieve horizontal alignment of the table; these grubs may be used in the final stages of installation to correct possible elastic deformations of the basement when the table is loaded (see paragraph 6.5).

G

NOTE: The operations described below require the use of a transpallet. 1. Remove lid "A" and walls "B" of the crate. 2. Remove the wooden beams "C" holding the pallets together, from the pallet. 3. Remove bolts "D" and "E" holding the base assembly to the pallets.

A

B

B

D E B C

C D B

Figure 6-1APOLLO

6-2

(Rev. 3)


4. Position the transpallet under one of the 2 side pallets "D", raise the base assembly and remove the central pallet "E". Lower the transpallet. 5. Referring to Figure 6-2, insert the transpallet centrally under the base assembly and lift it to free the two side pallets "D". Rest one side of the base on two supports (e.g. the pallets positioned on the corner) leaving the centre part free; suspend the other side, inserting one of the two main beams "C" parallel to the transpallet fork, allowing the side of the base to protrude as much as possible.

Main beam C

Figure 6-2 6. Referring to Figure 6-3, remove the transpallet and position it on the side of the base assembly. Exert leverage on the shoulder and lift the base assembly enough to remove the central pallet "C" and reposition it under the base, in such a way that it is parallel to the long side of the base and subsequently allows the transpallet to be inserted to lift the group. Lower the transpallet.

Main beam C

Figure 6-3(Rev. 3)

6-3

APOLLO


7. Leaving the transpallet in its present position, slide it under the base in such a way that it is possible to lift the assembly and free the two supports. With the greatest of care, suspend the base assembly on the central main beam "C"; slide the transpallet in completely under the base. 8. Bring the base assembly into the room and follow the above procedure in reverse, positioning the transpallet perpendicularly to the base assembly. Take the base assembly to the fixing plate and try to align the base-plate fixing holes as well as possible. 9. Position the two main wood beams "C" at the side of the base, parallel to the transpallet forks. Lower the base assembly and remove the transpallet. 10. Exerting leverage on one of the two side iron brackets, raise the base assembly enough to remove one of the wooden beams. Gently lower the base assembly until it is resting on the ground. Repeat the operation to remove the remaining wooden beam. 11. Check that the holes in the base assembly line up perfectly with those in the anchorage plate. If it is necessary, to move the base assembly to align the fixing holes, use the transpallet.

G

NOTE: Moving the base while it is resting on the ground by applying leverage to the structure is not advised under any circumstances. This operation could damage the actuators.

12. Close the two fixing holes on head side, 2 grubs are present to adjust the base position in order to avoid interferences during trendelenbourg movement, between middle beam and plastic guides present on the base. Unlock the 2 grubs and fix the base on the floor plate. The grubs adjustment is explained on paragraph 6.5 , items from 10 to 15. At this moment only it is allowed to remove the transport wood frame and lateral iron plate for main beam.

APOLLO

6-4

(Rev. 3)


6.2

Assembly of the Tube support arm1. Remove the front plate from the column stand. 2. Move the tube support arm towards the top of the column and, at the same time, position the front plate in such a way that the nine fixing holes on the parts to assemble (front plate tube support arm column section) are aligned (Figure 6-4). 3. Make sure that the tube support arm is aligned properly with the column before tightening the fixing screws. 4. Position on the frontal part of the X-ray tube arm the microswitch for 0 position setting it in such a way that it is not activated when the X-ray tube rotation pin reaches position 0.

Column section Tube support arm Front plate Micro 0

Figure 6-4

(Rev. 3)

6-5

APOLLO


6.3

Spot Film Device assemblyWARNING: A plate is provided with the Spot Film Device. This must be assembled with the four Spot Film Device support wheels and it will constitute a tool necessary for the installation of the Image Intensifier (paragraph 6.6). The Spot Film Device is fitted on the relevant adjustable supports and fitted with wheels to make it easier to move and position. 1. Position the Spot Film Device assembly mounted on the transport pallet, near the machine. 2. Free the four Spot Film Device supports from the safety blocks fixing them to the transport pallet. 3. Remove the Spot Film Device from the pallet being careful to pay the utmost attention not to damage it. 4. Remove all screws fixing the Spot Film Device, the two safety rods holding the inclination motor support on the end wall and remove the protection of the inclination potmeter (Figure 6-5). Remove the two top hooks from the Spot Film Device (one per side) (Figure 6-6) so that positioning can be carried out.

Safety rod

Protection of the inclination potmeter

Safety rod

Figure 6-5

APOLLO

6-6

(Rev. 3)


5. Position the Spot Film Device assembly near the end wall and make sure that it is possible to align the fixing holes on the shoulders and on the inclination motor support. If it is necessary to lift or lower the Spot Film Device to align the fastening holes, use the adjustable supports while being careful to avoid forcing the Spot Film Device on the angulation motor's fusion attachment (Figure 6-6). 6. Once the alignment of the holes on both the fixing shoulders has been checked, it is possible to fix, without tightening, the Spot Film Device assembly with the twenty-two bolts supplied (eleven bolts per side). If the Spot Film Device is imagined as a plane, it must be at right angles to the end wall where it is fixed. Check that the two elements are at right angles to each other using a bubble level. If it is necessary to make an adjustment to obtain perfect right angles between the Spot Film Device and the end wall, adjust the adjustable supports of the Spot Film Device support until the position required is reached (Figure 6-6). 7. Insert the two centering pins into their holes (Figure 6-6), one on each side, taking care that the threaded part can be accessed from outside, and then tighten the twenty-two fastening screws. Remount the two top hooks removed at point "4" above.

Centering pin

90

Top hook

Figure 6-6 8. Remove the four Spot Film Device assembly adjustable supports.(Rev. 3)

6-7

APOLLO


9. Carry out the Spot Film Device wiring pre-arranged on the right-hand side of the end wall. The wiring must be routed using the relevant cable clips to be found on the right-hand wall of the Spot Film Device. The wires must be routed in such a way that they are parallel to and not on top of each other (Figure 6-7). The X16 wire, fixed to an anchoring plate, must be placed on the right-hand wall of the Spot Film Device, interfacing with the flat cable (X16) installed in the factory. The following table is an aid in the identification of the cables and where they must be connected (see also Figure 6-7).Connector/Cable X101 X68 X44 X19 X14 X16 Ground cable Nr 8 A.E.C. chamber cable Point of connection Spot Film Device PCB A10 Spot Film Device PCB A10 Spot Film Device PCB A10 Spot Film Device PCB A10 Spot Film Device PCB A10 Interface connector X16 A10 PCB fixing plate A.E.C. chamber cable

X68 X14 X19 X44 X101 X16 Cable clip

Ground cable

Figure 6-7APOLLO

6-8

(Rev. 3)


G

NOTE: The automatic exposimeter device is an optional and consequently the A.E.C. chamber cable is only present when the automatic exposimeter chamber is fitted to the Spot Film Device. 10. Position the front panel of the Spot Film Device and fix it with the hinge on the left-hand wall. Connect the free end of the flat cable (X16) to the PCB of the key pad fitted on the machine A8. Loosen the fixing screws of the hinge on the Spot Film Device's lefthand wall; shut the panel and do up the bolts on both sides (Figure 6-8).

X16

Figure 6-8

(Rev. 3)

6-9

APOLLO


6.4

Left- and right-hand tabletop support arm assemblyThe tabletop support arms are different from each other with regard to the table fixing pin position and the reference lines for fixing the respective belts. For this reason there are two labels indicating the lefthand and right-hand arms.

G

NOTE: Both the table top support arms are fitted with blocking bolts for the transport. Remove these blocks only after the arms have been assembled, the relative belts have been tensioned and before mounting the tabletop and moving the arms. Right-hand arm assembly (Figure 6-9): 1. 2. 3. 4. Remove the beam side protection used for transport purposes. Remove the small plate from the beams. Loosen the three external attachment fixing bolts. Place the arm into its seat in such a way as to allow the assembly of the belt on the relative pulleys, following the route indicated in the figure. Check that the phasing reference lines marked above the belts of the arm and the co-ordinator correspond; otherwise correct the position of the belt of the arm. 5. Position the arm in such a way as to be able screw up the small plate removed at point "2" using the three bolts. At this point the belt is properly tensioned.Belt aligment reference

Arm belt

Coordination belt Outside support

Small plate

Beam side protection

Figure 6-9

APOLLO

6-10

(Rev. 3)


6. Do up all the six arm blocking bolts. 7. Remove the blocking bolts used to immobilise the arm during transport. For the assembly of the left-hand arm proceed as for the assembly of the right-hand arm.

(Rev. 3)

6-11

APOLLO


6.5

Machine cable connectionThe machine is partially factory wired, while the rest of the wires are provided separately; all have to be wired up to the machine as described below.

G

NOTE: The wire chains "A" and "B" (Figure 6-10) are made in such as way that they can be opened to permit the wires to be inserted. Take care to note when opening the chains the location of the individual covers. As these are not all the same, they will have to be put back properly when the chains are closed. At this stage only the machine wires can be set up so as to permit powering the table and to make the remaining installation process stage easier, or the system wires can also be connected (high tension cables, anode, etc.). How to proceed in this regard is a matter for the installer's own discretion. When you decide also to connect the system wires it is advisable to refer to paragraph 6.7 for tube-collimator group installation.

A

B

Figure 6-10 1. Fix the "B" chain to the upper locking bracket.

APOLLO

6-12

(Rev. 3)


G

NOTE: To easily identify the end to fix to the upper bracket, check as follow: on the external side of the link the code number is present. The end must be fixed on upper bracket is with 1 link code 157.150.100.1 and the following with code 158.150.100.1. The end must be fixed on lower bracket has all links with code 157.150.100.1. 2. To avoid cable-braiding, is suggested to position the cable chain as showed in Figure 6-10. House the group of cables leaving chain "A" in chain "B". Some of these wires are much shorter than others. The shorter ones should be connected to the A11 base connector board and the longer ones in the table's electrical cabinet and that of the generator if you wish also to connect up the system cables. 3. Before you start, chain "B" should be positioned as in Figure 6-11. 4. It is advisable at this stage not to close the wiring chain but just to install some covers so as to secure the wires inside them. Connect wires X20, X46, X75, X77, X88, X96, X97 and X98 to the A11 base connector board (Figure 6-12), threading them through "C" (Figure 6-11). The base connector board has a dust guard that has to be removed when connecting the wires and then replaced. Connect ground cables 5, 7, 8, 9 and 11 (lift I.I. - optional) to the ground bar (W2) in the base unit (Figure 6-13).

A

B

CFigure 6-11

5. Connect ground cable 10 between the ground connection W2 on the machine base unit and the ground rod (W1) in the cabinet.(Rev. 3)

6-13

APOLLO


6. Connect all the output cables in "C" and from chain "B" to the machine cabinet: X68, X19, X14, X16, X44, X101, X73, E4, X71, E2, X106 (lift I.I. optional), X70, E3, X20, X46, X99.5, X99.6, X74, E1, X99.1, X99.2, X105 and X45 as indicated in the following table (see also Figure 6-13). 7. Connect the console cable (X8) to the cabinet; connect the foot control (cable X41) to the console. 8. Connect the power cable to the R-S-T clamps on the insulation transformer inside the cabinet. Connect the ground cable to the rod (W1) in the cabinet. 9. Connect the system cables to the rest of the accessories when it is decided wire them up during the procedures described above.

G

NOTE: To avoid insurgence of an alarm condition at switch ON it is necessary to install the collimator (see paragraph 6.7) and connect it by cable X45 or simulate collimator presence; in this case it is possible for example to use a male CANNON 37 pin connector with two voltage partitions built by a resistor of 4.7k between pins X45-18 and X45-32, a resistor of 4.7k between pins X45-16 and X45-32, a resistor of 4.7k between pins X4519 e X45-33 and a resistor of 4.7k between pins X45-17 and X45-33. At this point the machine can be turned on and perform movements. In this stage the mechanical alignment of the moving beams with respect to the basement must be checked and possibly corrected. In order to do so proceed as follows: 10. Move de equipment up/down and tilt it in both directions; if the middle beam during same movements is in touch with parts of the basements, proceed as by the following step, otherwise will be not necessary other adjustments. 11. Release the two screws fixing the basement to the ground on the left side of the basement, i.e. close to the regulation grubs. 12. Act on the regulation grubs to correct deformations of the side wall of the basement: the process is of the trial and error type. Usually it is advisable to screw in the grub on the opposite side where the interference is present in the up-down movement of the beam. 13. Tight again the screws holding the basement to the ground. 14. Check again the movements following the procedure from step 10. 15. Make a few tilting movements to verify the correct situation and stop the procedure. This procedure should be repeated at the end of installation when the table is loaded with all its accessories (II, X-ray tube, table top, ecc.)

APOLLO

6-14

(Rev. 3)


Location on the Table

Table side cable code

Cabinet side cable code X34 X35 X36

Location on the Cabinet

Description Spot Film Device motor cable Spot Film Device motor cable Spot Film Device motor cable Spot Film Device motor cable Spot Film Device motor cable Spot Film Device motor cable

Spot Film Device PCB A10

X68 X37 X38 X39

Spot Film Device activation PCB A4

Spot Film Device PCB A10 Spot Film Device PCB A10 Button pad PCB A8 Spot Film Device PCB A10

X19 X14 X16 X44

X19 X14 X16 X44 X0.10

Input PCB A2 Input PCB A2 Input PCB A2 Cabinet connector PCB A12 Terminal block X0.10

Spot Film Device potmeter cable Spot Film Device cable Button Pad Cable Spot Film Device 24Vac power supply

Spot Film Device PCB A10

X101 X0.11 Terminal block X0.11

Emergency stop button cable

(Rev. 3)

6-15

APOLLO


Location on the Table Base unit connector PCB A11 Base unit connector PCB A11

Table side cable code X20 X46 X99.5

Cabinet side cable code X20 X46 X0.1 X0.2 X0.5

Location on the Cabinet Input PCB A2 Cabinet connector PCB A12 Terminal block X0.1

Description Machine potmeter cable PCB connection cable X46

Angulation connectors PCB A13 X99.6 Terminal block X0.2 Terminal block X0.5 Terminal block X0.6

SID motor cable

Angulation connector PCB A13

X74 X0.6 X99.1 X99.1 Compressor PCB A15 X99.2 X99.2 X105 X45 Cabinet connector PCB A12 Cabinet connector PCB A12

Emergency micro switch cable

Angulation connector PCB A13

Compressor motor cable

Angulation connector PCB A13 Collimator

X105 X45

PCB connection cable Collimator cable

APOLLO

6-16

(Rev. 3)


Location on the Table


Cabinet side cable code X8 X22 X0.7

Location on the Cabinet Cabinet CPU PCB A1 Input PCB A2 Terminal block X0.7

Description

Control panel - CPU PCB A14

X8 X0.8 X0.9 X0.10 X106.1 X0.3 X0.4 10 X70 X71 X72 Terminal block X0.8 Terminal block X0.9 Terminal block X0.10 Terminal block X0.3

Control panel

I.I. lift (optional) X106.2 Base unit ground rod (W2) Beam motor Angulation motor Middle beam motor 10 Terminal block X0.4 Cabinet ground rod (W1) Inverter box Inverter box Inverter box

Lift motor cable I.I.

Ground cables 10 Power supply cable Main beam motor Power supply cable Angulation motor Power supply cable Middle beam motor

(Rev. 3)

6-17

APOLLO


Location on the Table Scan motor Base unit ground rod (W2) Angulation motor Scan motor Main beam motor Middle beam motor


Cabinet side cable code X73

Location on the Cabinet Inverter box Cabinet ground rod (W1) Terminal block X0.E2 Terminal block X0.E4 Terminal block X0.E1 Terminal block X0.E3

Description Power supply cable Scan motor Ground cables 10 Angulation motor ground cable Scan moto ground cable Main beam motor ground cable Middle beam motor ground cable

10

10 E2 E4 E1 E3

APOLLO

6-18

(Rev. 3)


ANGULATION CONNECTOR CARD - A132 4 3 4 3 4 3

X891 2

1

2 1 4

X903

2 1 4

X853

2 1 4

X863 1

X1002

1

2 1

X912

2 1

X872

2 1

X82 X97

2

X105

X80

1

X79 V3

1

X76 V42

1

X742

1

1

X941 8

1

X95 X98 X99

1

BASE UNIT CONNECTOR CARD - A11X96 X20

2

1

X75

1

1

2

1

X83

1

2

V1

X77

1

2

X92

X84

1 2

1

2

X78

1

V2

2

X88

1

2

X93

X81

1

X46

1

2

X98

X97

2

Figure 6-12: Connector points diagram for machine connector board

(Rev. 3)

1

1

3

4

3

4

3

4

6-19

APOLLO


X20

X19

X14

X16

7X22X121 2

X21 X10 X11

X17

X15

X13

1 2

X4

X3A

INPUT CARD - A2X3BA2

X18

X12

5

9

1 2

X1 X2 X7

X4

A4

X341 2

8

X9

CPU CARD - A1 X8A1

X3B

SFD ACTIVATION CARD - A4

X70, X71, X72, X73

X3A

X35

4

3

2

1

X33

S1

X36 X39 X38 X37X25 X12X15A2 1

X6

X5B

X5A

X6

X5A

2

1

2

1

A3

X30 X107

X23

R, S, T CABINET GROUND ROD (W1)

X5B X27

OUTPUT CARD - A3

1

2

3

X17

X29

X26

X46 X105

5 9 7 8 10 10 (to the cabinet)

COMPRESSOR CARD - A15X25 X28 X31 X29 X241 2

X21

X32

X26

1

X47

X499 1 2 1 2 1

X484

X45 X44

1

2

3

4

5

6

7

8

9

1

2

CABINET CONNECTOR CARD - A12

BASE UNIT GROUND ROD (W2)47 46 45 44 43 42 41 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 E4 E3 E2 E1 11 9 8 7 6 5 4 3 2 1 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 S3 S3 10 10 N N

1

X99

X0

TERMINAL BLOCK X0X42 X41 X8

A15

X0.11 X0.10 X0.9 X0.8 X0.7 X0.6 X0.5 X0.4 X0.3 X0.2 X0.1

Figure 6-13: Cable and ground connection points diagram

(Rev. 3)

6-21

APOLLO


6.6

Image intensifier installation

G

NOTE: Assemble the I.I. trolley with the four Spot Film Device support wheels, using the nuts supplied, in such a way as to get a trolley like the one shown in the Figure, for the purposes of the I.I. installation.

Figure 6-14

(Rev. 3)

6-23

APOLLO


6.6.1

9-12 fixed Image Intensifier (I.I.) installation1. Place the I.I. on the trolley (Figure 6-14). Place the remote-controlled table high enough to allow the I.I. to be positioned under the Spot Film Device. Move the I.I. to the table and position it in such a way that the cable outlet on the I.I. power unit side is towards the base of the machine. 2. Use the lift control to lower the table until the I.I.'s fastening holes are aligned with those on the plates. You should proceed cautiously at this stage to avoid any damage occurring to the I.I. It is therefore advisable to lower the table in small steps.

Figure 6-15 3. Fasten the I.I. to the plates with the screws, and tighten.

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6-24

(Rev. 3)


4. Check transversal and longitudinal alignment between the Spot Film Device and the I.I. If any alignment between the two parts is necessary, slacken screws "A" (Figure 6-16) on both sides to get sideways I.I movement relative to the Spot Film Device, or screws "B" (Figure 6-16) for longitudinal movements; once the desired position has been obtained, tighten the screws.

A

BFigure 6-16 5. Connect the I.I. wiring and the angulation motor wiring on the left side of the end wall of the Spot Film Device using the cable clip provided (Figure 6-17). The cables must be wired up so that they run "parallel" to each other, following the path of the cables already in the machine.

Cable clip

Figure 6-17

(Rev. 3)

6-25

APOLLO


6.6.2

16" fixed Image Intensifier (I.I.) installation (Toshiba model)1. Using the bolts supplied fix the two I.I. fixing plates as indicated in Figure 6-18 taking into consideration the 530 mm (20.9") distance between the two guides. Any adjustments to this distance may be made with the plate-guide fixing screws.

530 (20.9")

Figure 6-18 2. Place the I.I. on the trolley (Figure 6-14). Place the remote-controlled table high enough to allow the I.I. to be positioned under the Spot Film Device. Move the I.I. to the table and position it in such a way that the cable outlet on the I.I. power unit side is towards the base of the machine. 3. Use the lift control to lower the table so that the I.I. fixing plates run inside the Spot Film Device's walls and that the holes "A" (6 per side Figure 6-19) on the walls are aligned with the fastening holes on the I.I. support guides. It is advisable to proceed cautiously at this stage to prevent any damage to the I.I. occurring. It is therefore best to lower the table by small steps. 4. Fasten the plates to the Spot Film Device's shoulders by means of the screws provided. 5. Check transversal and longitudinal alignment between the Spot Film Device and the I.I. If any alignment between the two parts is necessary, slacken the I.I. guide-plate support fastenings screws to get sideways I.I movement relative to the Spot Film Device or screws "A" (6 per side - Figure 6-19) for longitudinal movements; once the desired position has been obtained, tighten the screws.

APOLLO

6-26

(Rev. 3)


A

Figure 6-19 6. Connect the I.I. wiring and the angulation motor wiring on the left side of the end wall of the Spot Film Device using the cable clip provided (Figure 6-20). The cables must be wired up so that they run "parallel" to each other, following the path of the cables already in the machine.

Cable clip

Figure 6-20(Rev. 3)

6-27

APOLLO


6.6.3

Image Intensifier (I.I.) with lift installationWARNING: The I.I. lift movement can produce collision between I.I. and inner SFD parts, proceed with maximum attention to the actions indicated in the following paragraphs. The positioning of the I.I. lift is obtained by a motor which movement is stopped by 2 microswitches: S28 for upper position, S29 for lower position. The I.I.-lift end run positions can be adjusted modifying the microswitches activating cams.

APOLLO

6-28

(Rev. 3)


6.6.3.1

9 with lift Image Intensifier (I.I.) installation 1. Check that: measuring chamber is removed grid in park position cassettes jaws completely open. 2. Connect the I.I. lift cable to X106 terminals. 3. Select cell 133 (group 100 paragraph 10.1.15) and by the compressor joystick move the I.I. lift up to the upper and limit. Get out from set-up. 4. Fix the I.I. anchorage plate as indicated in the Figure.

Spacer

Anchorage plate

Figure 6-21 5. Place the I.I. on the trolley (Figure 6-14). Place the remote-controlled table high enough to allow the I.I. to be positioned under the Spot Film Device. Move the I.I. to the table at the point of the lift assembly. 6. Lower the table by sliding the I.I. inside the walls of the Spot Film Device until the 4 fixing holes on the I.I. anchorage plate are in line with the corresponding four in the lift plate (Figure 6-22). You should proceed cautiously at this stage to avoid any damage occurring to the I.I. It is therefore advisable to lower the table in small steps. Screw the anchorage plate to the lift plate without tightening using the screws provided. 7. Insert the 4 spacers provided (2 each side - Figure 6-22) between the I.I. anchoring plate and the lift plate. this enables proper alignment of the two plates.

(Rev. 3)

6-29

APOLLO


8. Check longitudinal alignment between the Spot Film Device and the I.I. Longitudinal alignment is obtained with the supplementary spacers that are inserted where there are those already present. Tighten the screws at the slots' midline; this ensures correct sideways alignment between the I.I. and the Spot Film Device.

SpacerFigure 6-22 9. The distance between cassette jaw lower side and I.I. must be never less than 5 mm (0.2"); if necessary adjust the lower end run cam. 10. Check that the conditions on item 1 are the same, set cell 133 again and move by joystick the I.I. lift on the upper end limit. Check that during the I.I. lift movement does not happens any collision between I.I. and internal SFD parts. 11. Connect the I.I. wiring, the angulation motor wiring and the lift wiring on the left side of the end wall of the Spot Film Device using the cable clip provided (Figure 6-17). The cables must be wired up so that they run "parallel" to each other, following the path of the cables already in the machine.

APOLLO

6-30

(Rev. 3)


6.6.3.2

12 Image Intensifier (I.I.) with lift installation 1. Check that: measuring chamber is removed grid in park position cassettes jaws completely open. 2. Connect the I.I. lift cable to X106 terminals. 3. Select cell 133 (group 100 paragraph 10.1.15) and by the compressor joystick move the I.I. lift up to the upper and limit. Get out from set-up. 4. Fix the I.I. anchorage plate as indicated in the Figure.

Spacer

Anchorage plate

Figure 6-23 5. Place the I.I. on the trolley (Figure 6-14). Place the remote-controlled table high enough to allow the I.I. to be positioned under the Spot Film Device. Move the I.I. to the table at the point of the lift assembly. 6. Lower the table by sliding the I.I. inside the walls of the Spot Film Device until the 4 fixing holes on the I.I. anchorage plate are in line with the corresponding four in the lift plate (Figure 6-24). You should proceed cautiously at this stage to avoid any damage occurring to the I.I. It is therefore advisable to lower the table in small steps. Screw the anchorage plate to the lift plate without tightening using the screws provided. 7. Insert the 4 spacers provided (2 each side - Figure 6-24) between the I.I. anchoring plate and the lift plate. This enables proper alignment of the two plates.

(Rev. 3)

6-31

APOLLO


8. Check longitudinal alignment between the Spot Film Device and the I.I. Longitudinal alignment is obtained with the supplementary spacers that are inserted where there are those already present. Tighten the screws at the slots' midline; this ensures correct sideways alignment between the I.I. and the Spot Film Device.

Spacer

Figure 6-24 9. The distance between cassette jaw lower side and I.I. must be never less than 5 mm (0.2"); if necessary adjust the lower end run cam. 10. Check that the conditions on item 1 are the same, set cell 133 again and move by joystick the I.I. lift on the upper end limit. Check that during the I.I. lift movement does not happens any collision between I.I. and internal SFD parts. 11. Connect the I.I. wiring, the angulation motor wiring and the lift wiring on the left side of the end wall of the Spot Film Device using the cable clip provided (Figure 6-17). The cables must be wired up so that they run "parallel" to each other, following the path of the cables already in the machine.

APOLLO

6-32

(Rev. 3)


6.6.3.3

16 Image Intensifier (I.I.) with lift installation 1. Check that: measuring chamber is removed grid in park position cassettes jaws completely open. 2. Connect the I.I. lift cable to X106 terminals. 3. Select cell 133 (group 100 paragraph 10.1.15) and by the compressor joystick move the I.I. lift up to the upper and limit. Get out from set-up. 4. Fix the I.I.'s two anchoring brackets as indicated in the Figure.

Anchoring brackets

Figure 6-25 5. Place the I.I. on the trolley (Figure 6-14).Place the remote-controlled table high enough to allow the I.I. to be positioned under the Spot Film Device. Move the I.I. to the table at the point of the lift assembly. 6. Use the lift control to lower the table by sliding the I.I. inside the walls of the Spot Film Device until the 4 fixing holes on the anchoring brackets are in line with the corresponding four holes in the lift plate (Figure 6-26). You should proceed cautiously at this stage to avoid any damage occurring to the I.I. It is therefore advisable to lower the table in small steps. Screw the anchorage plate to the lift plate without tightening using the screws provided.

(Rev. 3)

6-33

APOLLO


7. Check longitudinal alignment between the Spot Film Device and the I.I. longitudinal alignment is obtained with the supplementary spacers that are inserted where the bracket fastening screws are (Figure 6-26). Tighten the screws at the slots' midline; this ensures correct sideways alignment between the I.I. and the Spot Film Device.

Spacer

Figure 6-26 8. The distance between cassette jaw lower side and I.I. must be never less than 5 mm (0.2"); if necessary adjust the lower end run cam. 9. Check that the conditions on item 1 are the same, set cell 133 again and move by joystick the I.I. lift on the upper end limit. Check that during the I.I. lift movement does not happens any collision between I.I. and internal SFD parts. 10. Connect the I.I. wiring, the angulation motor wiring and the lift wiring on the left side of the end wall of the Spot Film Device using the cable clip provided (Figure 6-20). The cables must be wired up so that they run "parallel" to each ot

Apol Lo

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