1994 HONDA INTEGRA Workshop Manual

I
Rcf. No. I Tool Numb€lDcscriptionO'ty I P!9. Relrrrncc
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07GAF - PH70100
07GAF - SD40700
07GAG - SD40100
07GAG - SD40200
07GAG - SD40400
07JGG - 0010104
07MAC - 5100200
07MAG - 5100100
07NAD - SR30200
07NAG - SR30900
OTNAK - SR3O11A
OTNAK - SR3O12A
07406 - 0010001
07406 - 0010300
07405 - 0010400
07725 - 0030000
07746 - 0010100
07746 - 0010200
007i$ - 0010000
07916 - SA50001
07947 - 6340500
07974 - 6890801
0797,1 - SA50200
Pilot Collar
Hub DivAssembly Base
Piston Seal Ring Guide
Piston Seal Ring Sizing Tool
Cylinde. End Seal cuide
Belt Tension Gauge
Ball Joint Remover, 28 mm
Ball Joint Boot Clip Guide
Cylinder End Seal Remover Attachment
Valve Ssal Ring Sizing Tool
P/S Joint Adapter (Pump)
P/S Joint Adapter (Hos6)
P/S Pressure Gsuge
Pressure Control Valve
Pressure Gauge
Universal Holder
Attachment, 32 x 35 mm
Attachment, 37 x 40 mm
Driver
Locknut Wrench, i[0 mm
Driver Anachment
Cylinder End Seal Slider
Sleeve Sesl Ring Sizing Tool
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'17 -52
17-39
17 -57
17 -57
17-EO
17 -20't7 -15
17-50
17-5{
17 -22
17 -22't1-22
17 -22
17-35, 53
17-55, 56
17 -1'l
t7-55
17 -2'l
17 -11
17-57,58
17-55
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17-2

Component Location
lndex
Powar Siooring:
NOTE:
a
a
It an intact airbag ass€mbly has been r€moved from a scrapped car or has been found defective or damaged during
transit. storage or service, it should be doploy€d (see section 23).
Before removing tho gearbox, remove ths ignition key to keep the steering shaft Jrom turning.
After installing the gearbox, check ths whe€l alignment and adiust if necessary.
CAUTION:
. All SRS aloctricll wiring h!m!|$a rrc covcred with
yrllow in3uhtion.
. 8€for€ disconnocling lny ptrt ol thc SRS wiro h!r'
ne*r, connect thc lhort conncctor{3l.
. Rcplsce lhc ontira ttfact d SRS harnccc a$embly il
it hs3 !n oprn circuh 01 dtm!9.d wiring.
SIEERING COLUiINRemoval, page 17-28Inspection, pago 17-30Installation, p6ge 17-31rcNMON SwlTCHSee s6ction 23
STEERII{G GEARBOXRack Guide Adjustment, pag.11-21
Removal, pags 17-45Diossombly, page 17-{8Bea65€mbly, page 17-53Installation, page 17-63
POWEN STEERING PUMPPump Beft Inspoction. page 17-2OPump Eeft Adjustm6nl, pago 17-2OPump Pressurg Ch€ck, page 17-22Removai, p6go 17-35Disassembly, p3gs 17-35Reassombly, psge l7-40lnstallation, page 17-44
STEERING WHEELRemoval. page 17-24Oisassembly/Reassembly, pageInstallation, page 17-2617-25
TIE'ROD END BALL JOINTBall Joint Eoot Replacement, page 17-63
17-3

System Description
Fluid Flow Diagram
The system is a compact rotary-valvs-type power stssring, connocted to the st€oring gearbox. Th6 fluid pressure is pro-vided by a vane-type pump which is driven by the engine crank pulley. The amount of fluid and pressurs is regulsted bythe flow control valve built into ths pump, The fluid prssaurs from th6 pump is dolivsred to tho valve unit sround the pin-ion of the steering g€arbox. The vslv€ inside the valvs unit controls the hydraulic prossur€ End changos the direction otthe flow. The fluid then flows to the power cylinder, where rack thrust is gen6rat6d. Fluid returning from th6 powsr cylin-der flows back to the .eservoir, where the fluid is 'filtered" and supplied to the pump Egain.
17-4

Construetion
The pump is a vane-type incorporating a flow control valve (with an integrated relief valve) and is driven by a V-belt from
the crank pulley. The pump features 10 vanes, Each vane performs two intake/dischsrge operations for every rotation of
the rotor. This means that the hydraulic fluid pressure pulse becomes extremely small during discharge.
CAM RING
FLOW CONTBOL VALVE
DRIVE
Operation
The belt-driven pulley rotates the rotor through the drive shaft, As the rotor rotates, the hydraulic pressure is applied to
the vane chamber of the rotor and the vanes witl rotate while being pushed onto the inner circumference of the cam .ing.
The inner circumference of the cam ring has an extonded portion with respect to the center of the shaft. so the rollers
move downward in the axial direction as the carrier rotates. As a result of this roller movemsnt, the internal volume of the
vane chamber will change, resulting in fluid intake and discharge.
START OF FLUID INTAKE:FLUID INTAKE:FLUID MOVEMENT:FLUID DISCHABGE:
DISCHARGE P('BT
I
SHAF'
The vanes are pushed ontothe inner circumference of th6cam ring.
Th6 volums otth€ van€ cham-ber increasos so that lluid issuckod in.
Th6 sucked-in fluid moves
towsrd the discha196 pon.As the vanes return to th€their original position on theinner side, the volume of thevane chamber decreases sothe fiuid is discharg6d fromthe discharge port.
(cont'd)
INLET PORT
VANE

System Description
Steering Pump (cont'dl
Flow Control
The flow control valve in the pump performs the follow-
ing steps @ through O to control the flow of fluid, i.e. to
increase the discharge volum€ wh6n engine speed is
low and to decrease it when the engine speed increases.
The assistance thrust of the steering gearbox changes in
compliance with the change in the discharge volume.
When the engine starts, fluid discharged from the
discharge port starts to run through the metering
orifice in the pump. The discharge volume increas€s
as the engine speed increases,
As the flow has already been regulated by the
metering orifice when the engine speed is at or near
the idle speed, a constant and regulated amount ot
fluid is discharged until the engine speed reaches
the middle speed range. As the engine speed
increases, the pressure difference between the ends
of the metering orifice increases. A pressure differ-
ence is created between the top and bottom ends ofthe flow control valve, too, pushing the flow control
valve to open the by-pass passage. This allows the
excess fluid to return to the inlet pon preventing
pressure at the discharge port trom rising exces-
sively.
As the engine speed continues to increase, the tlow
control valve is pushed back further. When the
engine speed reaches a given speed. the return pas-
sage outside the metering orifice is connected to
the inlet port, and the opening to the inlet port
widens in proportion to the increase in engine
speed. This makes pan of the fluid regulated by the
metering orifice return to the inlet pon of the pump;
there by discharged fluid from the pump is
decreased slowly by this amount.
The orifice in the return passage regulates and
maintains the flow of fluid discharged from thepump at a given level until the engine speed reach-
es the high speed range.
.5IJ
lot=ro
FLOW CURVE
PUMP R.P,M.
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VALVE
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17-6

Pressure Relief
Pressu.6 outside of the metering orifice is directed to
the bonom ot the flow control valve. When the pressure
builds up, the reliet valve in the flow control valve opens
to relieve the pressure. As the flow control valve is
pushed back by the pressure difference this time, the
flow of fluid in the bypass passsge increases, convolling
the pressure outside the metering orifice. The above
operations are repeated to provide constant discharge
prsssure lrom the pump,
VALVE
{Dacrarlai cxco33ivaYibration in iha valva.l
(cont'dl
17-7

System Description
Steering Gearbox
The rack-and-pinion type steering gearbox has a valve unit incorporated with the pinion to control the steering fluid pres-
sure. Steering fluid from the pump is regulated by a rotary valve in the valve unit and is sent through the cylinder pipe to
the power cylinder, where hydraulic pressure is applied. The steering fluid in the other side of the power cylinder returns
through the cylinder pipe and valve unit to the reservoir.
VALVE UNIT
CYLINDER PIPE
POWEB CYLINDER
Valve Unit
Inside the valve unit is the valve, which is coaxial with the pinion shaft, and controls the steering fluid pressure. The valve
housing is connected with the fluid pipe from the pump, return pipe to the pump, and the two cylinder pipes from the
respective power cylinder.
The pinion shaft is double - structured with the input shaft connected to the pinion gear, both of which are interconnected
with the torsion bar.
The pin insened in the valve and the pinion shaft groove engage; this allows the pinion shaft to rotate together with the
Because of this construction, the difference in angle in the circumferential direction between the input shaft and the valve
becomes larger according to the torsional strength of the pinion or steering resistance. However, maximum torsion
between the shafts is regulated by the engaged splines of the shafts at the pin engagement section to hold the torsion bar
within the set value.
This allows the steering system to lunction as an ordinary rack-and-pinion type steering if the steering fluid is not pressur-
ized because of a faulty pump.
VALVE
Difforcnco in .ngl. bo{w€cn thainput shalt rnd pinion !h.tt
ln-1
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lEngag€ with the pinionshaft groove)

17-8
INPUT SHAFT

Pressure Control
Low assist at higher speeds:
When steering resistance is low. such as when driving at high speeds. or when driving straight ahead, the input shaft is
near or in the neutral position, so there is little or no flow to any of the power cylinder orifices, Most of the feed pressure
trom the pump is bypassed to the reservoir. Because of this, the pressure stays the same in both sides of the power cylin-
der, resulting in low or no assist.
vaz =- S\->/-\7/RETURN PASSAGE(To RESERVOIRI
VALVE UNITINPUT SHAFT
High assist at lower speeds:
When steering resistance is high, such as when driving at low speed, or when turning the wheel with the car stopped, the
difference in angle created between the input shaft and the valve opens the fluid passage on one side, and closes the fluid
passage on the other side, at each pair of orifices. The fluid pressure increases in the side of the power cylinder fed by the
larger fluid passage. This increased pressure pushes on the rack piston, allowing the steering wheel to be turned with light
effon. On the other side of the power cylinder, the return passage opens allowing the steering fluid to return through the
input shaft to the reservoir. The fluid passages to the power cylinder automatically change in size, increasing as the steer-
ing resistance increases. In other words, the passages become larger and power assist increases when the steering effort
would normally be high, (for example. when parking or making low speed turns). and the passages become smaller and
power assist decreases when the steering effort would normally be low, (for example, when driving at high speeds or
straight ah€ad).
FLUIO PASSAGE TOPOWER CYLINDERFrom PUMP
A
/t-:\
v"
=iJ
RETURNPASSAGE
FLUID PASSAGE FROMPOWER CYLINDER
ALVE F.om PUMP
RESERVOIR