Control valve for a variable displacement compressor

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to control valves, and in particular, to a control valve for a variable displacement gas compressor for use in an air conditioning or refrigeration system

2. Description of the Related Art

A gas compressor will change a state of a gas from a low-pressure state to a high-pressure state. Such a compressor is often used in air-conditioning (A/C) systems where expansion of a refrigerant gas compressed by the compressor causes air passing over evaporator gas tubes to cool. After the gas has expanded, it is recycled through the compressor so to be compressed again.

The refrigerant gas is discharged by the compressor at a high pressure known as the discharge pressure. It moves to a condenser, where the high pressure, high temperature gas condenses into a high pressure, high temperature liquid, the energy required for the state change being transferred to air passing over the condenser fins in the form of heat. From the condenser, the liquid travels through an expansion device, where it expands, to an evaporator where it evaporates. The air passing over the evaporator coils gives off its heat to the refrigerant, providing energy needed for the state change. The cooled air passes out into the compartment to be cooled. The degree to which the air is cooled is proportional to the amount of expansion of the refrigerant gas, and the amount of expansion of the gas is directly proportional to how much gas is compressed within the compressor. The pressure of the gas is controlled within the compressor by the amount of displacement of the piston within the compression chamber.

A key concern in designing a cooling system utilizing refrigerant gas is too ensure that the liquid from the condenser does not flow in a quantity and temperature to push the evaporator below the freezing point of water. If there is too much heat absorption by the gas within the evaporator, the water found on the fins and tubes through condensation of water from air passing over the evaporator will freeze up, choking off air flow over the evaporator, thereby cutting off the flow of cool air to the passenger compartment. For this reason, most conventional control valves are calibrated to change the stroke (displacement) of the compressor based on the pressure of the gas returning to the compressor at a set pressure of the gas. The gas returns to the suction area of the compressor. The pressure in this area of the compressor is known as the suction pressure. The desired suction pressure, around which the stroke of the compressor is changed, is known within the art as the set-point suction pressure.

In 1984, a variable displacement refrigerant compressor was introduced which adjusted the flow of the refrigerant gas through the system by varying the stroke of the piston in the pumping mechanism of the compressor in the manner just described. This system was designed for use in an automobile, deriving power to drive the compressor using a drive belt coupled to the vehicle's engine. In operation, when the A/C system load is low, the piston stroke of the compressor is shortened so that the compressor pumps less refrigerant per revolution of the engine drive belt. This allows just enough refrigerant to satisfy the cooling demands of the automobile's occupants. When the A/C system load is high, the piston stroke is lengthened and pumps more refrigerant per revolution of the engine drive belt.

A description of this prior art variable displacement compressor and a conventional pneumatic control valve (CV) is found in U.S. Pat. No. 4,428,718 by Skinner (Skinner '718) which is assigned to the General Motors Corporation of Detroit, Mich. The Skinner '718 description and explanation of the variable displacement compressor, general function, and interaction of the CV with the compressor is hereby incorporated by reference.

FIG. 9

shows a variable displacement refrigerant compressor as described by Skinner '718. There is shown a variable displacement refrigerant compressor

210

of the variable angle wobble plate type connected in an automotive air conditioning system having the normal condenser

212

, orifice tube

214

, evaporator

216

and accumulator

218

arranged in that order between the compressor's discharge and suction sides. The compressor

210

comprises a cylinder block

220

having a head

222

and a crankcase

224

sealingly clamped to opposite ends thereof. A drive shaft

226

is supported centrally in the compressor at the cylinder block

220

and crankcase

224

by bearings. The drive shaft

226

extends through the crankcase

224

for connection to an automotive engine (not shown) by an electromagnetic clutch

236

which is mounted on the crankcase

224

and is driven from the engine by a belt

238

engaging a pulley

240

on the clutch

236

.

The cylinder block

220

has five axial cylinders

242

through it (only one being shown), which are equally spaced about and away from the axis of drive shaft

226

. The cylinders

242

extend parallel to the drive shaft

226

and a piston

244

is mounted for reciprocal sliding movement in each of the cylinders

242

. A separate piston rod

248

connects the backside of each piston

244

to a non-rotary, ring-shaped, wobble plate

250

.

The non-rotary wobble plate

250

is mounted at its inner diameter

264

on a journal

266

of a rotary drive plate

268

. The drive plate

268

is pivotally connected at its journal

266

by a pair of pivot pins (not shown) to a sleeve

276

which is slidably mounted on the drive shaft

226

, to permit angulation of the drive plate

268

and wobble plate

250

relative to the drive shaft

226

. The drive shaft

226

is drivingly connected to the drive plate

268

. The wobble plate

250

while being angularable with the rotary drive plate

268

is prevented firm rotating therewith by a guide pin

270

.

The angle of the wobble plate

250

is varied with respect to the axis of the drive shaft

226

between the solid line large angle position shown in

FIG. 9

, which is full-stroke, to the zero angle phantom-line position shown, which is zero stroke, to thereby infinitely vary the stroke of the pistons and thus the displacement or capacity of the compressor between these extremes. There is provided a split ring return spring

272

which is mounted in a groove on the drive shaft

226

and has one end that is engaged by the sleeve

276

during movement to the zero wobble angle position and is thereby conditioned to initiate return movement.

The working ends of the cylinders

242

are covered by a valve plate assembly

280

, which is comprised of a suction valve disk and a discharge valve disk, clamped to the cylinder block

220

between the latter and the head

222

. The head

222

is provided with a suction area

282

which is connected through an external port

284

to receive gaseous refrigerant from the accumulator

218

downstream of the evaporator

216

. The suction area

282

is open to an intake port

286

in the valve plate assembly

280

at the working end of each of the cylinders

242

where the refrigerant is admitted to the respective cylinders on their suction stroke each through a reed valve formed integral with the suction valve disk at these locations. Then on the compression stroke, a discharge port

288

open to the working end of each cylinder

242

allows the compressed refrigerant to be discharged into a discharge area

290

in the head

222

by a discharge reed valve which is formed integral with the discharge valve disk. The compressor's discharge area

290

is connected to deliver the compressed gaseous refrigerant to the condenser

212

from whence it is delivered through the orifice tube

214

back to the evaporator

216

to complete the refrigerant circuit as shown in FIG.

9

.

The wobble plate angle and thus compressor displacement can be controlled by controlling the refrigerant gas pressure in the sealed interior

278

of the crankcase behind the pistons

244

relative to the suction pressure. In this type of control, the angle of the wobble plate

250

is determined by a force balance on the pistons

244

wherein a slight elevation of the crankcase-suction pressure differential above a suction pressure control set-point creates a net force on the pistons

244

that results in a turning moment about the wobble plate pivot pins (not shown) that acts to reduce the wobble plate angle and thereby reduce the compressor capacity.

An important element of the variable displacement compressor is a pneumatic control valve

300

inserted into the head portion

222

of the compressor. CV

300

senses the A/C load by sensing the pressure state (the suction pressure) of the refrigerant gas returning to the compressor. The CV is operably connected to the crankcase chamber

278

. There are channels in the cylinder block

220

and the head

222

of the compressor for gas flow between the CV and suction area

282

, discharge area

290

and crankcase chamber

278

of the compressor. The CV controls the displacement of a piston

244

within the compressor by controlling the pressure of gas in the crankcase chamber

278

that acts on the backside of the pistons

244

and the wobble plate

250

.

Control valve

300

inserts into a stepped, blind CV cavity

298

formed in the compressor head

222

. The blind end of CV cavity

298

communicates directly with discharge area

290

through port

292

. CV cavity ports

294

and

295

communicate with the crankcase chamber

278

. CV cavity port

296

communicates with the suction area

282

. CV

300

is sealed into the CV cavity

298

so that particular features of the CV align with ports

292

,

294

,

295

and

296

.

FIG. 10

illustrates, in more detail, the pneumatic CV

300

depicted in FIG.

9

. The valve

300

comprises a valve body

301

and valve bellows cover

312

. Grooves

314

,

316

and

318

are formed in the valve body to position o-rings which seal against the walls of the CV cavity

298

. A groove

299

formed in the wall of the CV cavity

298

holds an o-ring which seals against the valve bellows cover

312

. This arrangement of o-rings seals the valve into four regions within the CV cavity

298

that are sealed with respect to each other and are each in gas communication with one of ports

292

,

294

,

295

or

296

.

CV

300

has an upper valve chamber

330

that communicates to the compressor discharge area

290

via (through) filter

320

and CV cavity port

292

. A mid-valve chamber

322

communicates to the crankcase chamber

278

via an opening

321

in the valve body

310

. A central passageway

326

in the valve body

310

communicates with the crankcase chamber

278

via port

295

. A lower valve chamber

328

communicates with the compressor suction area

282

through opening

327

in the valve bellows cover

312

and via port

296

.

CV

300

has a ball valve comprising ball

332

and valve seat

334

that can be operated to control the flow communication path between upper valve chamber

330

and mid-valve chamber

322

, hence controlling the flow communication between the discharge area

290

and the crankcase chamber

278

of the compressor. CV

300

has a conical valve consisting of conical member

340

and matching conical valve seat

338

that can be operated to control the flow communication between lower valve chamber

328

and central passageway

326

, hence controlling the flow communication between the suction area

282

of the compressor and the crankcase chamber

278

.

The conical valve member

340

is formed as a shoulder near one end of a valve rod

336

. The other end of valve rod

336

is arranged to push against ball

332

as the conical valve member

340

is seated against the matching conical valve seat

338

. With this arrangement, the movement of the valve rod

336

opens and closes the flow communication of both discharge pressure and suction pressure gas to the crankcase chamber

278

. The positioning of valve rod

336

can be used to adjust the crankcase pressure to values between suction pressure and discharge pressure. This adjustment of the crankcase pressure, in turn, adjusts the compressor displacement.

In conventional pneumatic CV

300

, the position of valve rod

336

is established by a balance of forces arising from the discharge pressure acting on ball

332

, a pressure sensitive bellows actuator

350

, ball centering spring

354

and bias spring

352

. Bellows actuator

350

is comprised of an evacuated metal bellows

342

, an internal spring

344

, end caps

345

and

346

, and bellows stem

348

. The bellows actuator

350

is extended by the force of internal spring

344

and is contracted by the force of gas pressure applied to the external surface of the bellows. Bellows actuator

350

is sealed in lower valve chamber

328

that is in gas communication with the suction area

282

of the compressor.

During operation of the compressor, CV

300

responds to changes in the suction pressure of the compressor

210

via the bellows actuator

350

, and to changes in the discharge pressure via the force on ball

332

. The spring constants and nominal compression of the bellows internal spring

344

, bias spring

352

and ball centering spring

354

create forces on valve rod

336

that are set by the valve manufacturer at the time of valve assembly. The spring forces act to normally condition control valve

300

so as to open the flow of discharge pressure gas and simultaneously to close the flow to the suction area

282

from the crankcase chamber

278

. CV

300

will therefore control the flow of discharge and suction pressure gasses to the compressor crankcase

278

according to these fixed spring forces.

The nominal spring bias force set-up design parameters in a pneumatic CV such as CV

300

are chosen so that during operation of the air conditioning system, the temperature of the evaporator is maintained slightly above the freezing point of water. The spring bias set-up requires a balancing of system objectives that apply under different air temperature ambient conditions. For higher air temperature ambient conditions, it is optimal to maintain as cold an evaporator as possible without freezing. At lower ambient air temperatures it is desirable to maintain as high an evaporator temperature as can be maintained while still supplying some dehumidification. One choice of spring bias forces for CV

300

must accommodate to multiple ambient air temperature conditions, engine power loading conditions, and user demands for cooling.

Pneumatic CV's with fixed spring force bias set-up designs have two major disadvantages. First, the system is always working at its maximum capacity at the evaporator requiring maximum energy use by the compressor when the cooling system is operating. Second, since the evaporator is always at maximum capacity, hot air must be introduced into the system to temper the cold air to a temperature other than full cold.

An alternate CV design used in variable displacement compressors for vehicle air conditioning system utilizes a solenoid-assisted valve to control the flow of refrigerant gas into the crankcase of a variable displacement compressor. U.S. Pat. No. 5,964,578 by Suitou, et al (Suitou '578), discloses a CV having a solenoid-activated rod that operates on a valve member that controls the flow of discharge and suction pressure gasses to the crankcase. The valve member position is partially established by a spring-biased bellows in similar fashion to a conventional pneumatic CV. Increasing suction pressure acts on the bellows to reduce gas flow from the discharge area to the crankcase. When energized, the solenoid activated rod applies a force that also urges the valve member so as to reduce discharge pressure flow to the crankcase. This allows an additional control of the piston stroke and the output capacity of the compressor that can be mediated by electrical signals to the solenoid coils.

An alternate CV design using a solenoid actuator to assist discharge valve operation has been disclosed in U.S. Pat. No. 5,702,235 by Hirota (Hirota '235). In this design a solenoid is used to open and close a pilot valve that admits discharge pressure gas to a pressurizing chamber in the CV. The pressurizing chamber is in constant gas communication with the suction pressure area of the compressor. A valve member controls the flow of discharge and suction pressure gasses to the crankcase. The position of the valve member is established by a balance of spring bias forces, the force of the discharge pressure acting on an end of the valve member, and the force of the pressure in the pressurizing chamber acting on the opposite end of the valve member. When energized, the solenoid activated pilot valve allows the pressure to rapidly increase in the pressurizing chamber, opening the valve member to increase the flow of discharge pressure gas to the crankcase.

The valve member of the Hirota '235 CV design does not respond to the suction area pressure and does not control compressor displacement according to a suction pressure set-point as does the solenoid-assisted CV of Suitou '578 or the pneumatic CV of Skinner '718. The object of the Hirota '235 CV design is to use the force of discharge pressure gas to open the discharge to crankcase valve, thereby allowing the use of a compact, lightweight and inexpensive solenoid.

There are several major disadvantages with the prior art solenoid-assisted CV's. First, a variable position solenoid is required. Variable position solenoids are not linear in performance and the extreme temperatures in an automobile engine compartment make proper operation of the variable position solenoid highly difficult given power constraints. Second, a large and precise current value is required to properly position the solenoid. Third, variable position solenoid systems do not provide a steady suction pressure set-point whereby the cooling system can maintain itself in a state of equlibrium.

As a solution to the inefficiencies of conventional pneumatic and solenoid-assisted CV's, a CV design is needed in which the set-up of the bias forces acting within a pneumatic valve control valve can be changed to optimize the performance of the cooling system under different conditions. That is, a variable set-point control valve (VCV) is needed which varies the degree of displacement of the piston in the compression chamber. The suction pressure set-point is varied by the VCV according to the temperature desired by the occupants of the passenger compartment. In this manner, the cooling system does not have to operate at its maximum at all times, but rather the compressor only compresses and pumps enough the refrigerant gas to the suction pressure set-point necessary to cool the air flow to the temperature defined by the occupants. Substantial energy is saved by pressurizing the gas only to the point required and pumping only the volume required, and efficiencies are realized by eliminating the introduction of hot air into the cooled air flow.

A variable set-point CV is needed which overcomes the drawbacks of conventional pneumatic and solenoid-assisted CV's and enables a cooling system that maintains a steady-state equilibrium to match the needs of the passengers in the passenger compartment while operating efficiently.

SUMMARY OF THE INVENTION

Accordingly, it is an objective of the present invention to provide a control method and a control valve used in variable displacement compressors, which valve maintains the pressure in the compressor crankcase in response to the suction pressure of the compressor relative to a stable, predetermined set-point of the suction pressure, which set-point can be changed during compressor operation by electrical signals.

To achieve the above objective the present invention discloses a control valve in a variable displacement compressor having a piston having a variable displacement within a compression chamber. A gas is admitted to the compression chamber from a suction area of the compressor at a suction pressure and discharged to a discharge area of the compressor at a discharge pressure. A gas pressure in a crankcase chamber acts upon the piston or mechanical elements linked to the piston, so that the displacement of the piston varies according to the crankcase pressure relative to the suction pressure. The control valve controls the crankcase pressure by means of a discharge valve portion that opens a gas communication path between the discharge area and the crankcase chamber. The discharge valve portion is operably coupled to a pressure sensitive member. The pressure sensitive member has a suction pressure receiving area in gas communication with the suction pressure area and a reference pressure receiving area in gas communication with a reference chamber. The reference chamber has a reference pressure established to a predetermined reference pressure by a flow of discharge and suction pressure gas to and from the reference chamber. The pressure sensitive member moves in response to the predetermined reference pressure and suction pressure changes to open the discharge valve portion. The control valve has reference chamber valve means for controlling the flow of discharge and suction pressure gas to and from the reference chamber in response to electrical signals, thereby establishing the predetermined reference pressure. The control valve of the invention is therefore capable of operating as a variable set-point control valve, wherein a stable set-point can be changed in response to electrical signals.

The present invention also discloses a variable set-point control valve for a variable displacement compressor that additionally controls the flow of suction pressure gas to the crankcase chamber by means of a suction pressure valve portion that opens or closes a gas communication path between the suction area and the crankcase chamber.

The present invention further discloses a method of controlling a variable displacement compressor having a piston having a displacement within a compression chamber, the compression chamber admitting gas at suction pressure and discharging gas at discharge pressure, the displacement of the piston varying according to the compressor crankcase pressure, and a control valve having a gas-filled reference chamber for controlling the crankcase pressure. The method comprises determining an amount of gas to be compressed to cause a condition to occur. A predetermined reference pressure within the reference chamber which will cause a crankcase pressure condition to occur is then determined. The reference pressure within the reference chamber is measured. An amount of discharge pressure gas flow to and suction pressure gas flow to the reference chamber, based on the predetermined reference pressure and the measured reference pressure, is calculated. At least one actuator to operate at least one reference chamber valve to cause the reference pressure to change towards the predetermined reference pressure by allowing the flow of discharge pressure and suction pressure gas into and out of the reference chamber is then actuated. A pressure sensitive member is moved according to the pressure within the reference chamber, the pressure sensitive member opening a gas communication path between the discharge area and the crankcase chamber.

These and other objects, features and advantages of the present invention will become more apparent upon a consideration of the following description and drawings of the preferred embodiments of the present invention, and the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described with reference to the drawings. In the drawings are:

FIG. 1

shows a cross-section of available set point control valve according to a preferred embodiment of the present invention.

FIG. 2

shows a cross-section of the variable set point control portion of the variable control valve of FIG.

1

.

FIG. 3

shows a cross-section of the reference chamber valve means of the variable control valve of

FIGS. 1 and 2

.

FIG. 4

shows a cross-section of the valve members and valve seats of the reference chamber valve means of the variable control valve of

FIGS. 1-3

.

FIG. 5

shows a cross section of a variable set point control valve according to another embodiment of the present invention.

FIG. 6

shows a cross-section of a variable set point control valve according to yet another embodiment of the present invention

FIG. 7

shows a cross-section of a variable set point control valve according to a further embodiment of the present invention.

FIG. 8

shows cross-sections of two further embodiments of the reference chamber valve means that can be used with the variable control valves of

FIGS. 1

,

4

,

5

, and

6

of the present invention.

FIG. 9

shows a cross-section of a variable displacement compressor for use in an automobile from the prior art.

FIG. 10

shows a cross-section of a conventional pneumatic control valve for the variable displacement compressor of

FIG. 10

from the prior art.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

A variable set point control valve (VCV)

10

is represented in the diagram of

FIG. 1

according to a preferred embodiment of the present invention. In

FIG. 1

, VCV

10

is depicted in cross-sectional view and has a shape and feature placements appropriate to fit the control valve cavity

298

of the Skinner '718 variable displacement compressor described previously (see FIG.

9

). VCV

10

is coupled to a compressor

100

which compresses a gas. VCV

10

controls the amount of gas and the degree to which it is pressurized in compressor

100

. In the preferred embodiment, the gas compressed in compressor

100

is a refrigerant such as is used in an air conditioning unit. For instance, such an air conditioning unit would be found in an automobile.

VCV

10

comprises a compressor displacement control portion

30

and a variable set point control portion

80

. Compressor displacement control portion

30

controls the flow of the gas from compressor

100

in and out of VCV

10

while variable set point control portion

80

controls the operation of compressor displacement control portion

30

. VCV valve body

12

is formed with many VCV functional elements which will be described later. In the preferred embodiment illustrated in

FIG. 1

, valve body

12

is substantially cylindrical in shape as may be inferred from the cross-sectional view shown. O-ring retaining grooves

14

are indicated on the exterior of valve body

12

in three locations. When VCV

10

is inserted into a control valve cavity of a compressor (see for example, FIG.

9

), it is assembled with o-ring seals that allow different pressure sources to be communicated to different portions and ports of VCV

10

.

Compressor displacement control

30

comprises a suction pressure chamber

32

formed in the lower end

16

of valve body

12

which is in gas communication with the suction area

120

of the compressor

100

through VCV suction port

34

formed in valve body

12

and suction pressure path

112

. Refrigerant circuit line

111

feeds low pressure gas into a compression chamber

114

of compressor

100

via the suction area

120

and a compressor valve plate

126

. Refrigerant circuit line

111

is a line returning low pressure refrigerant gas from the accumulator

144

of an air conditioning system

Compressor

100

further comprises piston

116

, crankcase chamber

118

, and discharge area

124

. In simple terms, the operation of compressor

100

is as follows. The refrigerant gas in compression chamber

114

is compressed by the stroke of piston

116

as piston

116

moves towards the compressor valve plate

126

. The compressor valve plate admits high pressure gas to the discharge area

124

. The refrigerant circuit line

111

is connected to the discharge area

124

. The greater the displacement (stroke)

128

along compression chamber

114

of piston

116

, the greater the pressure and flow volume of the refrigerant gas as it passes through compressor valve plate

126

. The refrigerant gas then passes from refrigerant circuit line

111

to a condenser

140

where it condenses to a liquid in the condenser coils. The liquid then flows to an evaporator

142

, where the liquid expands at an orifice within the evaporator

142

, and evaporates. The air passing over the coils gives off heat energy that provides the energy for the state change from liquid to gas The cooled air is then blown into the passenger cabin of the automobile, or into whatever chamber the air conditioning system is required to cool. After expanding, the refrigerant gas is in a low pressure state and is returned to compressor

100

through the refrigerant circuit line

111

.

Compressor

100

is a variable compressor, meaning that the stroke of piston

116

varies dependent upon the required air conditioning system load. For instance, if a user requires additional cooling of the air passing over the evaporator coils, the flow volume of the refrigerant discharged into refrigerant circuit line

111

is increased. The stroke

128

of piston

116

is increased to increase the flow volume.

A pressure is applied within crankcase chamber

118

to the back of piston

116

. The greater the pressure within crankcase chamber

118

, relative to the suction pressure, the shorter the return stroke

128

of piston

116

after compression due to the high pressure force exerted against piston

116

on the return (away from valve plate

126

). Conversely, the lower the pressure within crankcase chamber

118

, relative to the suction pressure, the greater the return stroke of piston

116

after compression due to the low pressure force exerted against piston

116

. By varying the pressure within crankcase chamber

118

, thus varying the displacement

128

of piston

116

and ultimately the pressure of the discharge through refrigerant circuit line

111

, the temperature of the air from the evaporator is controlled.

The compressor displacement control portion

30

has a middle chamber

40

formed as a bore centered in valve body

12

leading from suction pressure chamber

32

. A first middle port

42

is formed in valve body

12

and communicates with middle chamber

40

. First middle port

42

is in gas communication with the crankcase chamber

118

through a first crankcase pressure path

130

. VCV

10

further comprises a pressure sensitive member, diaphragm

36

, exposed to suction pressure chamber

32

. A suction pressure valve, comprising a suction valve closing member, suction valve ball

38

, and a suction valve seat

37

formed in valve body

12

, is provided to open and close a gas communication path between the suction pressure chamber

32

and the middle chamber

40

.

Suction valve ball

38

is urged against suction valve seat

37

by rigid member

41

, which is in floating contact with diaphragm

36

. A bias spring

44

, retained in middle chamber

40

, urges suction valve ball

38

off suction valve seat

37

, that is, urges the suction valve portion to open. It is also seen that the bias spring

44

opposes a movement of the diaphragm towards the suction valve seat and so acts as an equivalent pressure, a spring bias pressure, adding to the action of the suction pressure on the pressure receiving area of diaphragm

36

. The VCV suction pressure valve opens and closes a gas communication path between the suction area

120

and the crankcase chamber

118

of compressor

100

.

A discharge pressure valve portion of VCV

10

is comprised of a discharge valve member, discharge valve ball

50

, and discharge valve seat

52

formed in valve body

12

. Discharge valve ball

50

is positioned in a discharge pressure chamber

60

formed in an upper end

18

of valve body

12

. Valve insert

64

has a stepped throughbore

62

that positions discharge valve ball

50

in alignment with discharge valve seat

52

. A ball centering spring

58

may be used to further condition the nominal position of discharge valve ball

50

. A particle filter cap

74

sealably covers the end of valve body

12

, completing discharge pressure chamber

60

. When VCV

10

is inserted into the compressor

100

, the upper end

18

of the valve body is sealed in a blind end of a control valve cavity such as cavity

298

illustrated in FIG.

9

. Discharge pressure path

110

from the discharge area

124

of the compressor is communicated to the blind end of the control valve cavity. Discharge pressure gas is thereby communicated to the VCV discharge pressure chamber

60

through filter

74

.

VCV

10

has a central stepped bore

70

through valve body

12

. Central bore

70

has a large diameter bore portion at the upper end adjacent the discharge chamber

60

whereat discharge valve seat

52

is formed. Central bore

70

and middle chamber

40

are aligned with each other. A second middle port

56

is formed in valve body

12

and communicates with the large bore portion of central bore

70

. Second middle port

56

is in gas communication with the crankcase chamber

118

through second crankcase pressure path

132

. When discharge valve ball

50

is moved off discharge valve seat

52

, discharge pressure gas can flow through bore

70

to second middle port

56

and then to the crankcase chamber

118

via second crankcase pressure path

132

.

A valve rod

54

, inserted in central bore

70

partially links the actions of the suction valve portion and the discharge valve portions of the VCV. Valve rod

54

has a diameter slightly smaller than the small bore portion of central bore

70

. Valve rod

54

freely slides in central bore

70

yet substantially blocks gas communication between middle chamber

40

and discharge chamber

60

. The length of valve rod

54

is chosen so that it simultaneously touches seated discharge valve ball

50

and suction valve ball

38

in a fully open (fully unseated) position. This arrangement links the suction and discharge valve portions in a partial open-close relationship. As suction valve ball

38

moves in a valve-closing direction, valve rod

54

pushes discharge ball

50

in a valve-opening direction. As discharge valve ball

50

moves in a valve closing direction, valve rod

54

pushes suction ball

38

in a valve-opening direction.

In the preferred embodiment of

FIG. 1

, valve rod

54

is not attached to either valve closing ball. Valve rod

54

operates to open either the discharge or the suction valve portions of the VCV but not to close either. The forces which act to close the discharge valve portion are the pressure of the discharge gas on an effective pressure receiving area of discharge valve ball

50

and a small spring force imparted by ball centering spring

58

. The force that acts to close the suction pressure valve portion derives from a movement of pressure sensitive diaphragm

36

via rigid member

41

. Other embodiments of the invention in which both valve closing members are attached to a coupling means such as valve rod

54

will be apparent to those skilled in the control valve art. If both valve members are rigidly linked, then a full open-close relationship will exist.

Reference is made specifically now to the variable set point control portion

80

of VCV

10

. Variable set point control

80

comprises a closed reference chamber

90

bounded by VCV diaphragm

36

, walls

91

formed at the lower end

16

of valve body

12

when the suction pressure chamber

32

was formed, and valve end cap

20

. Diaphragm

36

is positioned and sealed against an interior step

93

in the suction pressure chamber

32

by a reference valve carrier

81

. The diaphragm

36

has a first side

43

with a suction pressure receiving area exposed to suction pressure in suction pressure chamber

32

and a second side

39

with a reference pressure receiving area exposed to the reference pressure in the reference chamber. Diaphragm

36

is arranged to seal the reference chamber

90

from direct gas communication with the suction pressure chamber

32

, the discharge pressure chamber

60

, middle chamber

40

or central bore

70

.

Two pressure bleed passageways, a discharge bleed passageway

68

and a suction bleed passageway

72

are provided in valve body

12

and align with two holes in the diaphragm

36

that is sealed against valve body interior step

93

. Valve insert

64

has a valve insert bleed hole

69

provided to communicate discharge chamber

60

with discharge bleed passageway

68

. The bleed passageways, valve insert bleed hole, and corresponding diaphragm holes, provide a source of suction pressure gas and discharge pressure gas to the reference chamber

90

. The feature depicted of supplying the discharge pressure gas to the reference chamber from VCV discharge pressure chamber

60

is important because this design uses filter

74

to protect the components and passages in reference chamber

90

from foreign material.

The VCV components contained in the reference chamber are illustrated more clearly in FIG.

2

. Reference chamber valve means are further illustrated at higher detail level in FIG.

3

. Same elements in

FIGS. 1-3

are labeled with the same numbers.

Referring now to

FIGS. 1-3

, the reference valve carrier

81

is formed as a thick-walled cylinder with outside walls that sealably fit against the interior of walls

91

formed at the lower end

16

of valve body

12

. The upper end of reference valve carrier

81

seals against diaphragm

36

. Two small blind chambers, a suction bleed chamber

96

and a discharge bleed chamber

98

are formed in the reference valve carrier

81

from the upper end that is sealed against the diaphragm

36

. The open end of suction bleed chamber

96

aligns with suction bleed passageway

72

and the open end of discharge bleed chamber

98

aligns with discharge bleed passageway

68

. Reference chamber valve means are generally indicated as reference inlet valve

88

and reference outlet valve

86

.

Turning to

FIG. 3

, reference inlet valve

88

is comprised of reference inlet valve closing member

162

, reference inlet through hole

160

, and reference inlet valve seat

164

. Reference inlet through hole

160

is formed from an interior surface of the cylindrical reference valve carrier

81

through to discharge bleed chamber

98

. Reference inlet valve seat

164

is formed around the inlet through hole

160

where it emerges from reference valve carrier

81

, that is into reference chamber

90

. The reference inlet valve closing member

162

is attached to an inlet valve push rod

167

which is part of inlet solenoid actuator

94

. When an electrical current signal is applied to inlet solenoid leads

85

, inlet valve push rod

167

is pulled into the center of solenoid actuator

94

, urging reference inlet valve closing member

162

against reference inlet valve seat

164

, closing off reference inlet through hole

160

. Reference inlet through hole

160

communicates reference chamber

90

with discharge bleed chamber

98

. Thus, opening and closing reference inlet valve

88

by means of electrical signals applied to inlet solenoid actuator

94

controls the flow of discharge pressure gas to the reference chamber.

Inlet solenoid leaf spring

168

is arranged to bias inlet valve push rod in a retracted position as is illustrated in FIG.

3

. This inlet solenoid spring bias configuration means that the reference inlet valve

88

will open the reference chamber to the flow of discharge pressure gas in the absence of an electrical signal to energize the coil of the inlet solenoid actuator

94

. The depicted reference inlet valve is said to be normally open The opposite arrangement of spring biasing the reference inlet valve to a normally closed condition is an alternate configuration of the reference inlet valve means that may also be employed successfully in another embodiment of the present invention.

Reference outlet valve

86

is comprised of reference outlet valve closing member

172

, reference outlet through hole

170

, and reference outlet valve seat

174

.

Reference outlet through hole

170

is formed from an interior surface of the cylindrical reference valve carrier

81

through to suction bleed chamber

96

. Reference outlet valve seat

174

is formed around the outlet through hole

170

where it emerges from reference valve carrier

81

, that is into reference chamber

90

. The reference outlet valve closing member

172

is attached to an outlet valve push rod

177

which is part of outlet solenoid actuator

92

. When an electrical current signal is applied to outlet solenoid leads

87

, outlet valve push rod

177

is pulled into the center of solenoid actuator

92

, pulling reference outlet valve closing member

172

away from reference outlet valve seat

174

, opening reference outlet through hole

170

. Reference outlet through hole communicates the reference chamber

90

with suction bleed chamber

96

. Thus, opening and closing reference outlet valve

86

by means of electrical signals applied to outlet solenoid actuator

92

controls the flow of suction pressure gas to the reference chamber.

Outlet solenoid leaf spring

178

is arranged to bias outlet valve push rod in an extended position as is illustrated in FIG.

3

. This outlet solenoid spring bias configuration means that the reference outlet valve

86

will close the reference chamber to the flow of suction pressure gas in the absence of an electrical signal to energize the coil of the outlet solenoid actuator

92

. The depicted reference outlet valve is therefore normally closed. The opposite arrangement of spring biasing the reference outlet valve to a normally open condition is an alternate configuration of the reference outlet valve means that may also be employed successfully in another embodiment of the present invention

It should also be appreciated that, while solenoid actuators are discussed herein and depicted in

FIGS. 1-3

, any electrically-driven physical actuator means could be employed to open and close reference inlet valve

88

and reference outlet valve

86

.

The variable set point control portion

80

further comprises an electronic control unit

82

, pressure sensor

84

, electrical circuit carrier

83

, and VCV electrical leads

89

. Pressure sensor

84

is an optional feature of the preferred embodiment of the present invention. It is a transducer device that produces an electrical signal that is related to a gas pressure impinging on its sensitive and Pressure sensor

84

is mounted on electrical circuit carrier

83

so as to respond to the gas pressure within closed reference chamber

90

. It is not necessary for the practice of the present invention that pressure sensor

84

be mounted directly in the interior of reference chamber

90

. An alternative embodiment could mount the pressure sensor at some other position as long as the pressure sensitive portion of the sensor is brought into gas communication with the reference chamber

90

.

Electronic control unit

82

is an optional feature of the preferred embodiment of the present invention. Control unit

82

may contain electronic circuitry to control the reference chamber valve means or to receive and process the electrical signals produced by the pressure sensor

84

. In a preferred embodiment of this optional feature of the present invention, the electrical components of control unit

82

are co-located with pressure sensor

84

by means electrical circuit carrier

83

. Other functions of optional control unit

82

will be described later.

VCV electrical leads

89

are routed from electrical circuit carrier

83

through a sealed opening in valve end cap

20

. The number of electrical leads needed by VCV

10

will depend on the functions performed by optional electronic control unit

82

and the device characteristics of optional pressure sensor

84

. When neither electrical control unit

82

nor reference chamber pressure sensor

84

are employed, then VCV electrical leads

89

need comprise only those needed to carry electrical signals to activate the reference chamber valve means.

Variable set point control portion

80

controls the operation of compressor displacement control portion

30

. By controlling a pressure within reference chamber

90

, variable set point control

80

is able to regulate the open/close conditions of the suction pressure valve portion and the discharge pressure valve portion of VCV

10

. For instance, if the pressure in reference chamber

90

exerts a force against diaphragm

36

which is less than the force exerted by the pressure in suction pressure chamber

32

and bias spring

44

, diaphragm

36

will distort into reference chamber

90

, that is in the direction of reference inlet let actuator

94

. This motion moves suction valve ball

38

from suction valve seat

37

, thus opening the flow of gas from first crankcase pressure path

130

to suction pressure chamber

32

. At the same time, the discharge pressure valve portion is closed by the pressure of discharge gas forcing discharge valve ball

50

onto discharge valve seat

52

. By opening the flow through the suction valve portion of VCV

10

, gas from crankcase chamber

118

will flow into suction pressure chamber

32

and out to the suction area

120

of compressor

100

via suction pressure path

112

. With the bleeding of gas out of crankcase chamber

118

, less force is exerted on piston

116

giving piston

116

greater displacement. The flow of refrigerant gas flowing into the evaporator of the system is thus increased.

If the pressure in reference chamber

90

exerts a force against diaphragm

36

which is greater than the force exerted by the pressure in suction pressure chamber

32

and bias spring

44

, diaphragm

36

will distort into the suction pressure chamber

32

, that is, in the direction of suction valve seat

37

. This action closes the VCV suction valve portion and, at the same time, opens the VCV discharge valve portion by pushing discharge valve ball

50

away from discharge valve seat

52

by means of valve rod

54

. As the discharge valve portion is opened, high pressure gas from discharge pressure path

110

flows through discharge pressure chamber

60

, stepped central bore

70

, second middle port

56

and second crankcase pressure path

132

to crankcase chamber

118

. Pressure will build up in crankcase chamber

118

, thus applying a force against piston

116

. The displacement

128

of piston

116

is thus restricted and the amount of refrigerant gas passing into the evaporator of the system is reduced.

The force that bias spring

44

exerts on the diaphragm is an important design variable for the overall performance of VCV

10

. It has been found through experimentation that it is most beneficial if the spring force is adjusted to be equivalent to from 2 to 20 psi of suction pressure, and most preferably, from 4 to 10 psi. This range of spring bias force allows for sufficient operational range of VCV

10

in the condition of very low compressor capacity usage, that is, when the compressor is near full de-stroke operation.

The pressure within reference chamber

90

is controlled by the opening and closing of reference outlet valve

86

and reference inlet valve

88

. Each of these are optionally controlled, in the preferred embodiment, by pressure sensor

84

and electronic control unit

82

. Specifically, the pressure within reference chamber

90

is in gas communication with pressure sensor

84

. Pressure sensor

84

, interfaced to electronic control unit

82

, measures the pressure of the gas in reference chamber

90

and communicates that pressure to electronic control unit

82

. Electronic control unit

82

receives control signals and information from a compressor control unit

146

. Passenger comfort level settings and other information about environmental conditions and vehicle operation conditions are received by compressor control unit

146

. Compressor control unit

146

uses stored compressor performance algorithms to calculate a necessary amount of gas to be compressed within the compression chamber

114

by piston

116

to cause a desired condition to occur, namely that the passenger comfort level settings are optimally achieved within the constraints imposed by environmental and vehicle operational factors.

The calculated compressor displacement requirements, the pressure information from pressure sensor

84

, and known physical response characteristics of VCV

10

elements are utilized by VCV performance algorithms to calculate a necessary pressure within reference chamber

90

to meet the compressor displacement requirements. This calculated reference pressure, necessary to meet the requirements determined by the compressor control unit, is called a predetermined reference pressure. The variable displacement compressor

100

is thereby controlled by the determining of the predetermined reference pressure and the maintenance of the gas pressure in the reference chamber to this predetermined pressure level

Alternatively, if a pressure sensor

84

is not employed, the predetermined reference pressure may be selected from a stored set of reference pressure levels that has been pre-calculated based on the known nominal characteristics of VCV

10

or, in addition, customized for each VCV by means of a calibration set-up procedure. In the case of this alternate embodiment of the present invention, the calculated compressor displacement requirements are used to determine, in look-up table fashion, the predetermined reference pressure that is optimal for achieving the desired compressor displacement control.

Control of reference outlet valve

86

and reference inlet valve

88

comes from electronic control unit

82

through actuators

92

and

94

, respectively. Dependent upon the outputs of the algorithms within electronic control unit

82

, electronic control unit

82

will open and close reference outlet valve

86

by actuating outlet actuator

92

and open and close reference inlet valve

88

by inlet actuator

94

. For instance, when the pressure within reference chamber

90

is to be increased, inlet actuator

94

will retract reference inlet valve member

162

allowing high pressure gas to flow from discharge pressure chamber

60

through valve insert bleed hole

69

, discharge pressure bleed passageway

68

and discharge bleed chamber

98

into reference chamber

90

. At the same time, outlet actuator

92

closes reference outlet valve

86

, thus allowing the pressure in reference chamber

90

to increase. Inversely, to decrease the pressure in reference chamber

90

, electronic control unit

82

will actuate outlet actuator

92

to retract reference outlet valve member

172

to open flow from reference chamber

90

through suction bleed chamber

96

to suction pressure bleed passage

76

to suction pressure chamber

32

, thereby bleeding off pressure. At the same time, actuator

94

is signaled by electronic control unit

82

to extend reference inlet valve member

162

to close off discharge pressure flow into reference chamber

90

.

By controlling the pressure within reference chamber

90

to the predetermined reference pressure, electronic control unit

82

, through actuators

170

and

172

, controls the deflection of diaphragm

36

, thus controlling the varying of displacement

128

of piston

116

. For the preferred embodiment depicted in

FIGS. 1-3

, the reference chamber pressure can be continuously or periodically monitored by means of pressure sensor

84

. This pressure information can be used as a feedback signal by control unit

82

in a pressure servo control algorithm to maintain the reference chamber at the predetermined reference pressure within chosen error boundaries.

It is anticipated that an important benefit of the VCV design disclosed herein is the ability to maintain valve control performance by tightly maintaining the predetermined reference pressure. The disclosed design also enables the system to electronically change the predetermined reference pressure to a different value, thereby changing the suction pressure set-point about which the variable displacement compressor operates. This allows the vehicle to adjust the compressor control in the face of changing environmental factors to achieve a desired balance of passenger comfort and vehicle performance. In order to realize these benefits to the fullest, the control of the pressure in the reference chamber must be sufficiently responsive.

The responsiveness of the reference pressure control system depends in part on the characteristics of the flow of discharge pressure gas through inlet valve

88

and the flow out of outlet valve

86

to suction pressure.

FIG. 4

illustrates some important geometrical feature details of reference inlet valve

88

and reference outlet valve

86

.

Referring first to

FIG. 4A

, inlet valve closing member

162

is illustrated in a fully closed position holding off the force of discharge pressure gas impinging an effective pressure receiving area, A

I

, on inlet valve member

162

. Also indicated in

FIG. 4A

is the diameter, D

I

, of the reference inlet port

160

leading from the discharge bleed chamber

98

. A large value of D

I

will promote quick response to commands to increase reference chamber pressure by admitting a large flow of discharge pressure. The size of D

I

needed to achieve a given reference chamber pressure rise time will depend on the reference chamber gas volume. A larger reference inlet port

160

will be required for a larger reference chamber gas volume to achieve the same increase in reference chamber pressure rise time as for a smaller reference chamber gas volume.

However, a large value of D

I

necessitates a correspondingly large value of A

I

, the effective inlet valve member pressure receiving area This, in turn, would mean that the closing force that would be needed from the inlet valve actuator

94

would also be large. A large closing force might require a physically large actuator or require excessive power to maintain the inlet valve in a closed state. Consequently, the choice of the reference inlet port

160

diameter, D

I

, and the pressure receiving area, A

I

, involves a balance of competing requirements.

The effective inlet valve member pressure receiving area, A

I

, is the net, unbalanced, area of the inlet valve closing member that is exposed to the discharge pressure when the inlet valve is fully closed. That is, the area that effectively receives the force of the discharge pressure, A

I

, may be calculated by measuring the force exerted on the inlet valve closing member by the discharge pressure, and dividing by the discharge pressure. It has been found through experimentation effective inlet valve pressure receiving area, A

I

, may be beneficially chosen to be less than 30,000 square microns and preferably, less than 7500 square microns when the reference chamber gas volume is approximately 2 cm

3

. Under typical automotive air conditioner compressor operating conditions, a reference inlet valve closing force of less than 1 Lb. will suffice if the effective inlet valve member pressure receiving area, A

I

, is less than approximately 7500 square microns.

Referring to

FIG. 4B

, outlet valve closing member

172

is illustrated in a fully open position with gas flowing out of reference chamber

90

through an effective gas flow area Many geometrical designs of the reference outlet port

170

may be chosen to have the same result in terms of the gas volume flow for a given pressure differential between reference chamber

90

and the suction bleed chamber

96

. The effective flow area is chosen to balance competing performance characteristics. In order to insure quick response to a command to lower the reference chamber pressure, it is desirable to have a large outlet valve

86

effective flow area On the other hand, to help restrain rapid pressure increases in the reference chamber when opening the inlet valve

88

to discharge pressure, and to bring down reference pressure overshoots that may occur, it is helpful to have a small outlet valve

86

effective flow area

The effective gas flow area of the reference outlet valve

86

may be beneficially chosen as a ratio to the effective flow area of the inlet valve

88

. Alternatively, the diameter, D

O

, of the reference outlet port

170

, may be chosen as a ratio of the reference inlet port

160

diameter, D

I

. It has been determined by experimentation and analysis that the beneficial range of the ratio D

O

to D

I

is from 0.5 to 5.0, and, most preferably, from 0.7 to 2.0. The corresponding beneficial ratio of inlet-port to outlet-port cross-sectional areas, the inlet-to-outlet port areal ratio, is 0.25 to 25.0, and, most preferably, 0.5 to 4.0. When the geometries of inlet and outlet gas flow areas are more complex than the circular passageways illustrated in

FIG. 4

, the gas flow cross-sectional areas may be analyzed or experimentally determined and the inlet-to-outlet port areal ratio design guideline followed.

It has been found through experimentation, for example, that when the reference chamber

90

gas volume is approximately 2 cm

3

, a reference outlet port

170

diameter D

O

of 100 microns is an effective choice when the reference inlet port

160

diameter D

I

is 100 microns, a reference outlet port diameter to reference inlet port diameter ratio of 1.0. With these parameter values, and under typical automotive air conditioner compressor operating conditions, the reference chamber pressure can be controllably changed, or tracked to a predetermined reference pressure, at the rate of 10 psi/second.

For alternative embodiments of VCV

10

without a pressure sensor, the compressor control unit

146

may periodically recalculate the compressor displacement conditions required to maintain performance of the cooling system. Based on the magnitude and time behavior of changes in these calculations, compressor control unit

146

may send instruction signals to VCV electronic control unit

82

to increase or decrease the reference chamber pressure to re-establish the pre-determined reference pressure level. It will be appreciated by those skilled in the art that this method of affecting servo control of the pressure in the reference chamber to the predetermined level will be less timely than can be implemented using a direct measurement of reference chamber pressure. Nonetheless, this loose-servo method can be effective and appropriate for a low cost embodiment of the present invention.

The functions attributed to VCV electronic control unit

82

and compressor control unit

146

could be performed by other computational resources within the overall system employing the VCV

10

, compressor

100

and cooling equipment. For example, if the overall system is an automobile with a central processor, then all of the control information and calculations needed to select and maintain the predetermined reference pressure could be gathered and performed by the automobile central processor. Signals to and from pressure sensor

84

could be routed to an input/output (I/O) port of the central processor and reference inlet and outlet valve actuation signals could be sent to VCV

10

from another I/O port of the central processor. Alternately, a compressor control unit

146

could perform all the control functions needed to manage VCV

10

. And finally, VCV control unit

82

could be provided with circuitry, memory and processor resources necessary to perform the compressor displacement requirement calculation as well as selecting and maintaining the predetermined reference pressure.

Another embodiment of the present invention is illustrated in FIG.

5

. This embodiment is similar to the embodiment of

FIG. 1

except that bias spring

44

is omitted and rigid member

41

is replaced with rigid alignment member

510

. Rigid alignment member

510

is formed with a cavity that retains suction valve ball

38

by compression fit. Rigid alignment member

510

floats in the suction pressure chamber

32

and responds to the movement of diaphragm

36

. In the embodiment of

FIG. 5

, VCV

500

operates in analogous fashion to VCV

10

in FIG.

1

. The force exerted by bias spring

44

in

FIG. 1

serves to push the suction valve portion farther open than would be achieved by simply reducing the reference pressure chamber all the way to suction pressure, fully retreating diaphragm

36

. This bias spring force contribution is most important when opening the suction pressure valve portion of VCV

10

to rapidly reduce (dump) the pressure in the crankcase chamber

118

to increase compressor

100

capacity for rapid cooling.

In VCV

500

in

FIG. 5

the suction valve ball

38

is nominally held in a maximum open condition by the set up of diaphragm

36

position, the dimensions of the rigid alignment member

510

and valve ball

38

assembly, and the position of suction valve seat

37

. A higher predetermined reference pressure is needed to displace diaphragm

36

towards suction valve seat

37

, to compensate for the maximum open set up. When maximum suction valve opening is needed to dump the crankcase chamber pressure, the predetermined reference pressure is reset back down to suction pressure, retreating diaphragm

36

, and allowing the high pressure crankcase gas to push the suction valve portion to a maximum open condition.

FIG. 6

illustrates another embodiment of the present invention. In this embodiment the compressor

109

has an internal bleed passageway

108

that allows gas to bleed from the crankcase chamber

118

to the suction area

120

of compressor

109

. VCV

600

in

FIG. 6

is similar to VCV

10

in

FIG. 1

except that it omits the suction pressure valve portion. VCV

600

also uses a valve piston

610

as the pressure sensitive member instead of a diaphragm. Valve piston

610

has a suction pressure receiving area

612

and a reference pressure receiving area

614

. Valve piston

610

moves in a suction pressure chamber

620

. Valve piston

610

is operably coupled to the discharge pressure valve portion by valve rod

54

. VCV

600

operates in analogous fashion to VCV

10

in

FIG. 1

except that discharge gas will be supplied to the crankcase chamber

118

on a nearly continuous basis except when the compressor

109

must operate at maximum displacement and the crankcase pressure is maintained at suction pressure. The reference chamber pressure control algorithms will be different for VCV

600

than for VCV

10

in

FIG. 1

due to some leakage of reference chamber gas to suction pressure chamber

620

via gaps between piston

610

and the walls of suction pressure chamber

620

.

FIG. 7

illustrates another embodiment of the present invention. VCV

700

is configured to operate with compressor

109

having an internal bleed

108

between the crankcase chamber

118

and the suction area

120

. It is similar to VCV

600

in

FIG. 6

except that it uses a diaphragm

36

as a pressure sensitive member and rigid member

710

and valve rod

54

to operably couple the movement of diaphragm

36

to the discharge pressure valve portion VCV

700

operates in analogous fashion to VCV

600

in FIG.

6

. The reference chamber pressure control algorithms used with VCV

700

are similar to those used with diaphragm-equipped VCV

500

and VCV

10

since there is no leakage of reference chamber gas to suction pressure outside the control of the reference chamber valve means.

FIG. 8

illustrates two additional embodiments of the present invention. FIG.

8

(

a

) shows an alternative embodiment of the reference chamber valve means illustrated in FIG.

3

. The reference valve carrier

81

and inlet valve means

88

and inlet valve actuator

94

are unchanged. However in place of outlet valve means

86

, a constant outlet bleed orifice

810

is provided. The predetermined reference pressure is set and maintained by actuating the reference inlet valve admitting discharge pressure gas. The reference pressure control algorithms used with this embodiment of the reference valve means are derived with cognizance of the characteristics of the constant bleed to suction pressure. With this arrangement a compromise must be struck between a desire to be able to rapidly change the predetermined reference pressure toward suction pressure, favoring a large bleed flow, and the controllability of higher predetermined reference pressure settings, favoring a small bleed flow.

FIG.

8

(

b

) shows another alternative embodiment of the reference chamber valve means illustrated in FIG.

3

. The reference valve carrier

81

and outlet valve means

86

and outlet valve actuator

92

are unchanged. However in place of inlet valve means

88

, a constant inlet bleed orifice

820

is provided. The predetermined reference pressure is set and maintained by actuating the reference outlet valve, releasing reference chamber gas to suction bleed chamber

96

. The reference pressure control algorithm used with this embodiment of the reference valve means are derived with cognizance of the characteristics of the constant bleed of discharge pressure into the reference chamber. With this arrangement a compromise must be struck between a desire to be able to rapidly change the predetermined reference pressure toward discharge pressure, favoring a large bleed flow, and the controllability of predetermined reference pressure settings that are near suction pressure, favoring a small bleed flow.

Either alternate embodiment of the reference chamber valve means disclosed in

FIG. 8

may be substituted for the dual inlet and outlet reference valve arrangements depicted in

FIGS. 1-7

. That is, any of VCV embodiments VCV

10

, VCV

500

, VCV

600

, or VCV

700

could be constructed with either of the single actuator reference valve means embodiments disclosed in FIG.

8

.

Thus, a variable set point control valve is described which variably controls the displacement of a piston within a gas compression system by controlling a reference pressure acting upon a pressure sensitive member. Utilizing actuators which open and close based upon input from control algorithms within a control unit to control the flow of high or low pressure gas, the pressure acting upon the diaphragm can accurately adjust the degree of displacement of the piston. This variable fine tuning of the pressure against the diaphragm, hence the fine tuning of the piston displacement control, allows the compression system to operate at less than maximum capacity, thus substantially increasing the efficiency of the compression system.

The present examples and embodiments are to be considered as illustrative and not restrictive and the invention is not limited to the details given herein, but may be modified within the scope and equivalence of the appended claims.

Number	Name	Date	Kind
4730986	Kayukawa et al.	Mar 1988	A
4732544	Kurosawa et al.	Mar 1988	A
4932843	Itoigawa et al.	Jun 1990	A
5588807	Kimura et al.	Dec 1996	A
5620310	Takenaka et al.	Apr 1997	A
5681150	Kawaguchi et al.	Oct 1997	A
5702235	Hirota et al.	Dec 1997	A
5964578	Suitou et al.	Oct 1999	A
5975859	Kawaguchi et al.	Nov 1999	A
6010312	Suitou et al.	Jan 2000	A
6126405	Kawaguchi et al.	Oct 2000	A
6164925	Yokomachi et al.	Dec 2000	A
6164926	Kawaguchi	Dec 2000	A

Control valve for a variable displacement compressor

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

US Referenced Citations (13)

Foreign Referenced Citations (1)