US2783936A - Air compressors or the like - Google Patents

Description

March 5,' 1957 M. w. KlsTLER 2,783,936

AIR coMPREssoRs 0R THE LIKE:

Filed March 10, 1955 2 Sheets-Sheet l INVENTOR. M-AX W. KISTLER W4/MMM I ATTORNEYS March 5, 1957 M. w. KlsTLl-:R 2,783,936

AIR coMPREssoRs 0R THE LIKE Filed March l0, 1955 2 Sheets-Sheet 2 FIGB INVENTOR. `MAX W. KISTLER ATTORNEYS' nited States Patel-ntl() AIR COMPRESSRS R THE LIKE Max W. Kistler, Rochester, N. Y., assignor to American Brake Shoe Company, New York, N. Y., a corporation of Delaware Appiication March 10, 1955, Serial No. 493,530 4 Claims. (Cl. 2312-3) This invention relates to an automatic unloader and speed regulator for use in connection with air compressors and the like.

Air compressors which are adapted to supply air under pressure to a storage tank usually include a so-called unloader attachment adapted to render the compressor in-v effective to pump air under pressure to the tank when the pressure of the air in the storage tank is at a predetermined high value. Subsequently, as the tank pressure is gradually reduced by the use of compressed air stored therein, the unloader responds to such reduction at a predetermined low value of tank pressure and the compressor is thereupon reloaded for normal operation.

Unloading of the compressor has been accomplished primarily in two ways. In one instance, the compressor is normally loaded by a normally open valve afforded in the intake line for the compressor so that until unloaded the compressor draws air from the ambient atmosphere to be compressed, and when the compressor is to be unloaded this valve is closed in which case the supply of air to the compressor is interrupted. Unloaders of this kind have been referred to as being of the intake closing type.

In the second instance, the unloader is used to control the valve which admits air to the cylinder of the compressor on the down stroke of the piston. Thus, when unloading conditions have been reached at the tank, the unloader is operable .to hold open the intake valve afforded for the compressor cylinder in which case no air is compressed. Unloaders of this kind have been referred to as being of the compressor valve opening type.

During the time that the compressor is unloaded, it is desirable that the engine or motor used to drive the compressor be idled inasmuch as at this time the compressor in effect is doing no work. Thus in those in. stances where the compressor has been'driven by an electric motor, it has been common practice to use a pressure responsive switch which shuts olf the motor when the upper limit of tank pressure has been attained and which restarts the motor automatically after the tank pressure has dropped by a predetermined amount. With engine driven compressors, on ,the other hand, .arrangements for-automatic starting and stopping ofthe engine have been of 'a complicated nature and have proven unreliable in practice, and for this reason it is common to keep the engine running at full speed during the unloading cycle of the compressor.

It will be appreciated from the foregoing that under many circumstances an engine driven air compressor will run at full speed for prolonged periods when the cmpresser is not required to pump air, and inasmuch .as

idling of the engine during the unloading cycle of the compressor would conserve fuel and reduce wear on both the engine and the compressor it is the primary object of the present invention to enable this to be accomplished in an efficient manner. More specifically, it is an objectof the present invention to enable the speed of theengine for driving an air compressor to be controlled through 2,783,936 Patented Maf- '55 2 an unloader in such a wayr that the compressor is unloaded before the engine has been idled, and conversely, to bring the engine up to full speed `before the compres-v sor is again to be loaded. In this manner, assurance is had that the speed of the engine is not reduced until after the compressor has been unloaded, and on the other hand that the engine will be running at full speed when the compressor is to be again loaded. l

Another object of the present invention is to enable speed regulation of the foregoing kind to be accomplished either with an unloader of the intake closing type or of the compressor valve opening type.

Other and further objects of the present invention will be apparent from the following description and claims and are illustrated in the accompanying drawings which, by way of illustration, show a preferred embodiment of the present invention and the principles thereof and what I now consider to be the best mode in which I have conf' templated applying these principles. Other embodiments of the invention embodying the sameror equivalent principles may be used and structural changes may be made as desired by those skilled in the art without departing from the present invention and the purview of the appended claims.

In the drawings: v

Figure 1 is an elevation of an unloader embodying a speed control, .including a part in section taken in the line 1 1 of Figure 2; l

Figure 2 is a sectional view taken in the line 2-2, Figure l; e

Figure 3 is a plan view of an air compressor assemblage including the unloader and speed controller of the present invention; and

Figure 4 is a detail view on an enlarged scale, partly in section, of the throttle control shown in Figur`e3.

For purposes of disclosure, the unloader and speed regulator of the present invention has been illustrated 'as embodied in an unloader of the intake closing kind as will be described, and the way in which this may begmoditied for the valve opening type of unloader will be pointed out herein below. Y In Figure 3, the unloader 10 of the present invention -is illustrated in a well-known association, including van internal combustion engine 11, acompressor 12 and astorage tank 13 to which air is pumped bythe compressor. The engine 11 drives apulley 15, arid this pulley in turn is connected by abelt 16 to the pulley 17 used to drive the compressor.

A ir to be compressed by thecompressor 12 is taken in by the compressor through anair inlet pipe 20, and this pipe is connected to the unloader as will now bedescribed.

In Figures 1 and 2 the unloader and speed Vcontroller* 10 of the present invention is illustrated as embodied in an unloader of the intake closing type. The operative parts are housed in a generally cylindrical housing 2.5, and thelower portion 26 of this housing in the present instance is of elbow construction al'ording an air intake in the form of astub pipe 27 and a compressor inlet likewise in the form of .a stub pipe 29, the latter being adapted to be connected to the compressor by thepipe 20 as described above. t -f f The passages afforded by thepipes 27 and 29 communicateuat achamber 30 disposed within thehousing 25 a'nd in the present instance there is associated withthe cornpressor intake passage a valve orifice 31, afforded by a' tapered tubular boss 33 within thechamber 30. The

boss 33 affording the intake valve orice 31 includes an` annular valve seat 31S about the end thereof whichis away from the compressor intake side, and associated with this .valve seats anunloader valve 35 which .is normally open, so as to admit of air passing through the valve ori- 3 s ge to the intake of the compressor. This is the condition that prevails when the compressor is loaded; when the compressor is tov be runloaded the unloader valve is closed on the valve seat 31S thus disrupting the ow of airthrough thechamber 30 to the compressor intake.

The uploader valve comprlses a pair of valve discs 36 and 37 of the usual kind, and` these are carried at the end da :stem .vvhich'isV under the control of a pressureresponsive diaphragm' as will be described. The valve discs are assembled on a reduced portion of the stem 40 and may be conveniently clamped in position by a nut at the end of the valve stem 40 as shown in Figure 2.

The interior of thehousing section 26 which is spaced above the boss 33 as viewed in Figure 2 includes anannular shoulder 15 serving to support the annular edge of a circular 'guide plate 46 for the valve stem 40, and this plate Yformed in the medial portion thereof with a bearing sleeve 46A in which the enlarged portion of Vthe valve stern above the valve discs is positioned for sliding movement. Thehousing section 26 includes anextension 48 beyond the annual shoulder on which the guide plate for the valve stem is positioned, and this extensionaffords achamber 50 of relatively large dimensions as can be seen in vFigure ,2- v

,d The end of thechamber 50 away from the shoulder 45 is tapered upwardly in a radial outward direction as viewed i'nFigure 2 to afford a sloped surface 51 for accommof dating downward flecture of a control diaphragm used to control the unloader valve as will be described. Outwardly of the sloped surface 51, thehousing section 26 includes aclamping tiange 56 for the outer marginal portion of the control diaphragm, and corresponding to this iiange is a likeannular flange 57 formed about the base of anupper housing section 60.

Thehousing section 60 is clamped to thehousing section 26 by cap screws as 61 which are tightened to hold the twoanges 56 and 57 tightly on the opposed faces of the outer marginal portions `of thecontrol diaphragm 55 for the unlader valve. The interior of theupper housing section 60 `is arched over the control diaphragm for the unloader Yvalve so as to afford a pressure chamber on the side of thediaphragm 55 away from the unloader valve 35 and it is within thepressure chamber 65 that air under pressure is adapted to impinge upon and control thediaphragm 55. l o

The unloader valve 35, as noted above, is normally open with respect to the valve seat aiorded therefor, and this condition is normally maintained by a coil spring 68 within thechamber 50 acting at one end against a pressure plate 69 on the side of the, diaphragm away fromthepress'ure chamber 65, and the. opposite end of the control spring reacts against theguide plate 46 for the valve stem 4 0. The PreSSulQ Plate 69 in the medial portion thereof is formed with ahub 70 configured to eugage a taper on the end o the valve stem 40 that is disposed toward the control diaphragm and preferably Vthe hub is welded thereto.

Air under pressure in thetank 13 is adapted to be admitted to thepressure chamber 65 through aninlet oriiiee 72 formed in thehousing section 60 and the end of this orifice away from thepressure chamber 65 is normally closed by a pilot valve 75 which in the present instance is in the form of adiaphragm 76. Theinlet oritice'v 72 for theypressure chamber 65 is formed centrally in aboss 78 which extends in the direction away from thepressure chamber 65, and surrounding this boss is an annular chamber 80. Coniining the chamber 80 on the side thereof away from theboss 78 is a flange 83 serving in part asl a clamp for thepilot valve diaphragm 76 as will be described.

The end of theboss 78 away from thepressure chamber 65 affords a valve seat 75S where theoritice 72 opens into the chamber 80, and the pilot valve 75 is baised to anormally closed position with respect to the valve seat 75S by. acoil spring 86 which will be described in moretapered cap 87 which includes at the base thereof anannu lar iange 88 complementary to the ange 83 so that thecap 85 may be held to thehousing section 60 by cap screws as 91 with the outer marginal portion of thepilot valve diaphragm 76 clamped tightly between thecomplementary flanges 83 and 88.

The housing section 6i) is formed with an inlet passage ororifice 95 communicating at the inner end thereof with the chamber 80 that surrounds the pilot vaive 75. The outer end of this inlet passage is enlarged and tapped at 96 to accommodate a conduit (not shown) connected at the opposite end to thetank 13 so that there will be air in the chamber 80 having a pressure corresponding to that of the compressed air in the tank tending to lift the normally closedpilot valve diaphragm 76 away from the valve seat 75S about theinlet orifice 72 to thepressure chamber 65. Such tendency of air under pressure within the chamber Si) to lift the pilot valve diaphragm is no1'- mally resisted by the return action of the pilot valvecontrol coil spring 86 acting at one end against apressure plate 98 disposed on the side of thepilot diaphragm 76 away from the chamber 80. This pressure plate is formed in the medial portion thereof with ahub 99 serving as a socket for the corresponding end of thecoil spring 86.

The end of thecoil spring 86 away from thepressure plate 98 carries anotherpressure plate 101 including a socket 192 for the corresponding end of the pilot valve control spring. Thepressure plate 101 includes adepression 106 in the medial portion thereof, and this depression is adapted to receive the rounded head 1081-1 of an adjustingscrew 108 adapted to regulate the tension of the pilot valve control spring. This may be accomplished by threading the screw into anut element 110 formed in the end of thecap 85 away from the anged portion thereof, and capping the exposed end of the adjusting screw with an exposed lock nut 111.

Thereturn spring 86 that controls the pilot valve is set as described above so that the pilot valve 75 will be opened or retracted relative to the valve seat 75S when air under pressure in thechamber 30 attains the maximum desired value, and when this occurs air under predeter mined high pressure iiows through theorlce 72 and impinges upon thecontrol diaphragm 55 for the unloader valve. The tension of the return spring 68 for the unloadervalve control diaphragm 55 is such that thediaphragm 55, being of relatively large diameter, is flexed at a pressure in thechamber 65 of about l5 p. s. i. in the direction of the valve seat 31S for the unloader valve 35, thus driving the stem 40 in a compressor unloading direction. In this manner, the unloaderr valve 35 is closed on the seat 31S thereby interrupting the supply of air to the compressor.

It may here be pointed out that once the pilot valve 75 is opened to unload the compressor, an additional area of thediaphragm 76 is exposed to air under pressure, namely, the medial portion of thediaphragm 76 that is normally closed on the valve seat 75S. Hence, the pilotvalve control spring 86 is more than over-balanced when the pilot valve 'is opened, thereby assuring that the pilot valve remains open until pressure in thetank 13 has been reduced to a value appreciably below that at which the pilot valve is rst opened during the unloading cycle.

When the predetermined value of low pressure of air in thetank 13 has been attained, the pilot valve 75 is closed on the valve seat 75S by thereturn spring 86 and this disrupts the supply of air under pressure through theorifice 72 tothe pressurechamber 65. To enable -ai'r under pressure to be bled from thepressure chamber 65` so that the unloader valve will return to the normally open position when the pilot valve '75 closes as aforesaid, ableed orilice 120, Figure 1, is aorded in thehousing section 60 in communication with the pressure Ichamber l65. At the end opposite the pressure chamber 6 5, the bleed orifice opens into anair chamber 122 of relatively small avancee' diameter, and this air chamber is tapped so as to receive an .adjustable set screw 125 which will be described in more detail below. The end of theset screw 125 that is disposed in theair chamber 122 is formed with atransverse aperture 127, and the shank and cap of theset screw 125 are bored with an axial bleed aperture 13() which at one end communicates with thetransverse aperture 127 and which at the other end opens to atmosphere. In this manner, irrespective of the setting of theset screw 125, air under pressure in thepressure chamber 65 is enabled to bleed to the atmosphere. This of course is a bleed of relatively small rate which does not interfere with unloading operation of thecontrol diaphragm 55. However, when the pilot valve 75 closes as aforesaid to enable the compressor to be again loaded, air will gradually bleed from thepressure chamber 65 until thepressure chamber 65 has been exhausted to such an extent that the return spring 68 relieves the unloader valve 35 relative to the valve seat 31S whereupon the compressor is again eective to pump air.

Theset screw 125 enables the compressor to be manually unloaded when desired. Thus referring to Figure 1,v it will be noted that theset screw 125 includes a tapered end portion `135 which when the set screw.125 is turned `fully in is adapted to close off one end of anorifice 136. The opposite end of theoriiice 136 communicates with theair passage 95, which, it will be recalled, is adapted to be connected with thetank 13 as described above. Normally, theset screw 125 is positioned so that thetapered end 135 thereof closes oft' theorifice 136 with respect to theair chamber 122, but if it be desired to manually unload the compressor theset screw 125 is backed ot`r" several turns and thereupon air under pressure flows into theair chamber 122 about the tapered end of theset screw 125 and from thechamber 122 to thepressure chamber 65 through theair passages 127 and 120.

Under and in accordance with the present invention,

the unloader 1i) is used to control the throttle setting of the internal combustion engine 11 shown in Figure 3. To enable this to be achieved in a way to be described, an air outlet 140 is formed in the housing section 6l) in communication with thepressure chamber 65, and the end of the outlet 140 opposite the end that opens into thepressure chamber 65 is tapped as at 141 to receive anelbow 142, Figure 3. The oppositeend ofelbow 142 receivesv aconduit 143, and as shown in Figure 4 this conduit leads to an inlet opening afforded in the wall of thecylinder 145 of an air operatedpiston 146 which is mounted at the side. of the internal combustion engine 11 as shown in Figure 3.

by the piston rod 151), and an oppositely directedrightangled cleat 153B on theshoe 153 engages the edge of` thelever 151 forwardly of thepin 152 to rock the lever 15'1Qconnterclockwise as viewed in Figure 4 when .thef piston -146 is actuated. The end of thelever 151 opposite the end associatedwiththe piston rod 150 has attached thereto acable 155 which in turn is used to set the throttle of lthe engine 11 from full speed to idle positions t .The'engine throttle is normally biased in full speed.

Thepiston 146 is normally in the una-ctuated"position` shown in Figure '4 with therod 150 of the piston retracted relative to athrottle control lever 151. The throttle con;

positionl conforming to the normally loaded'fcondtion'for', the'eonipressor, and areturn spring 159 yieldably holdspiston 146 so that the piston rod tive to thecontrol lever 151.

15G is retracted rela-ff ,Wh'en air under l'pressure` is .admitted tothe pressurechamber 65 upon opening o'f the pilot valve 75, air under pressure is simultaneously furnished. to the outlet passage lfllLand through theconduit 143 to thecylinder 145 whiclrtl1e tllrottl'e controlpiston146 is arranged to res ciprocate. Under and in accordance with therpresentl invention, the return spring 68 for thediaphragm 55 and thereturn spring 159 for the air operatedpiston 146 are selected so that the unloader valve 35 closes to unload the compressor prior to thepiston 146 and thepiston rod 15! being effective on theshoe 153 to pivot the lever 1,51 counterclockwise as viewed in Figure 4 to set the throttle of the engine 11 in idling position. Preferably, the tension of spring 68 is selected to permit closing of the unloader valve 35 when the air pressure inchamber 65 attains approximately 15 p. s. i., while the tension of they returnspring 159 for thepiston 146 is such that a pressure of approximately 50 p. s. i. is required to advance thepiston rod 150 against thecleat 153A of thelever control shoe 153. In this way, a diterential yis assured between unloading of the compressor and idling of the engine so that the compressor is unloaded in advance of engine idling.

When the pilot valve closes to commence a reloading cycle, air bleeds from theconduit 143 simultaneously with air in thepressure chamber 65 through thebleed passage 120, and in view of the foregoing thepiston rod 159 will be, retracted from thecontrol lever 151 as soon as the pressurein theconduit 143 drops to about 50 p. s. i., whereas on the other hand the unloader valve is not opened until the pressure inpressure chamber 65 drops to approximately 15 p. s. i. Hence, under compressor reloading conditions, the engine is brought up to full speed before the unloader valve 35 is opened.

It will be appreciated from the foregoing whilethe, connection -with` present invention has been described in an unloader of the intake closing type, the invention is also applicable to unloaders of the compressor intake valve opening type. In connection with the latter applicationl of the invention, it is merely necessarly to omit the unloader valve 35 andextend the stem 40 asvan air-operated piston to the intake valve of the compressor as will be apparent for instancefrom U. S. Patent No. 2,275,303 of Burr W. Mantle.

From the foregoing it will be seen that the present invention enables the compressor to be unloaded before the engine is idled,'and conversely, the engine to be4 brought up to full speed before the compressor isA again loaded, and this is attained through an unloaderl having; a pressure chamber used to control pneumatically from a coinrno'ri sourceof air'un'der-pressure both an unloader'-4 valve and an air-operated piston for controlling the throttle of the gas engine used to drive the compressor.

Hence, while l have illustrated and described the pretion, and 1 therefore do not wish te be limited; toy the; y to avail myself ofl sii'ch', changes and alterations as'vfallY within the purview pe'cise'details setl forth, Abutdesireof ,th following claims.

,"I claim: 1. An unloader and speed driven air compressor or the like including an engine coupled 'in mechanical driving-relationship to acornf presso'r',a liu'id storage device coupled; to the outlet of@ valve for said compressor' said 'compressonf `an' intake actuatable between two diierent operating positions to load and unload said compressor, and a throttle for said engine, said device comprising: a housing structure defining first and second pressure chambers, and inlet ports for said two chambers; a diaphragm mounted within said'housing structure and-constituting at least a portion ofone-wall of said first pressure chamber, said diaphragm being actuatable between two given operating positions` in response to predeterminedgchanges in .fluid pressure within said rst pressure connecting said diaphragm ating positions and for actuating said valve to its loading my invention, itis to be under-'- control device for an engine-A chamber; means-1 mechanically to said intake control valve to actuate said valve to its 'unloading position in. response to actuation of said diaphragm to one of lsaidtwo oper-ff arcanes position in response to actuation of said diaphragm to the other of its two operating positions; conduit means interconnecting sid llid storagevdcvice and said inlet pot of said second chamber; pilot valve comprising a second diaphragm mounted within said housing and constituting at least a portion of one wall of said second pressure chamber, said second diaphragm being inter posed in the inlet port of said first pressure chamber to admit fluid under pressure to said first chamber in response to an increase in liuid pressure within said second chamber above a predetermined threshold value; biasing means for closing said pilot valve in response to a decrease in pressure in said second chamber to a value substantially lower than said threshold pressure; a pressure-responsive piston adapted t'o engage said engine throttle; and a conduit interconnecting said piston with said first pressure chamber to actuate said piston between a full speed position in which said piston is disengaged from said throttle and an idle position in which said pistonis in engagement with said throttle in predetermined time relationship with respect to actuation of said intake control valve between said loading and unloading positions. p

2. An unloader 4and speed control device for an enginedriven air compressor or the like including an engine coupled in mechanical driving relationship to a compressor, a fluid storage device coupled to the outlet of said compressor, an intake valve for said compressor actuatable between two different operating positions to load and unload said compressor, and a throttle for said engine, ksaid device comprising: a housing structure defining first and 'second pressure chambers, an inlet port for vsaid first chamber interconnecting said two chambers, and an inlet port for said second chamber; a diaphragm mounted within said housing structure and constituting at least `a portion of one wall of said first pressure chamber, said diaphragm being actuatable between two given operating positions in response to predetermined changes in uid pressure within said first pressure chamber; means mechanically connecting said diaphragm to said intake control valve to actuate said valve to its unloading position in response to actuation of said diaphragm to one of said two operating positions and for actuating said valve to its loading position in response to actuation of said diaphragm to the other of its two operating positions; conduit means interconnecting said iluids'torage device and said inlet port of said second chamber; a second diaphragm mounted within said housing and constituting at least 'a portion of one wall of said second chamber; avalve seat, -having a substantial surface area relative to the 'surface area of said second diaphragm, encompassing the opening of said first chamber inlet port into said second chamber; biasing means, normally urging said second diaphragm linto engagement vwith said val've seat to close said first chamber vinlet port, for establishing a rst threshold pressure which must be Vexceeded within said second chamber before uid under pressure may be admitted to said first chamber from said second chamber and for establishing a second threshold pressure, substantially lower than said lirst threshold pressure, below wli-iclt the pressure -in said second chambei' must drop Vto i'e-seat said diaphragm; a pressureresponsive piston adapted to engage said engine throttle; and `a conduit interconnecting said piston with said first pressure chamber to actuate said piston between a full speed position in which said piston is disengaged from saidfthrottle and an idle position in which said piston is in engagement withjsaid lthrottle in predetermined time relationship with -respectlto actuation of said intake control valve between said loading and unloading positions.

3. An unloader and speed control device for an enginedriven air compressor or the like including an engine coupled in mechanical driving relationship to a compressor, a -fluid storage device coupled to the outlet of said compressor, and a throttle for said engine. said device comprising: a housing structure defining trst and second pressure chambers, an inlet port for said rst chamber interconnecting said two chambers, an inlet port for said second chamber, and an intake conduit adapted to be connccted to the intake port of said compressor; an unloader valve mounted within said intake conduit in said housing and actuatable between two different operating positions to load and unload said compressor; a diaphragm mounted within said housing structure and constituting at least a portion of one wall of said tirst pressure chamber, said diaphragm being actuatable between two given operating positions in response to predetermined changes in fluid pressure within said irst pressure chamber; a valve stem mechanically interconnecting said diaphragm and said unloader valve to actuate said valve to its unloading position in response to actuation of said diaphragm to one of said two operating positions and for actuating said valve to its loading position in response to actuation of said diaphragm to the other of its two operating positions; conduit means interconnecting Said liuid storage device and said inlet port of said second chamber; a pilot valve comprising a second diaphragm mounted within said housing and constituting at least a portion of one wall of said second pressure chamber, said second diaphragm being interposed between said second pressure chamber and the inlet port of said first pressure chamber to admit fluid under pressure to said first chamber in response to an increase in uid pressure within said second chamber above a predetermined threshold value; biasing means for closing said pilot valve in response to a decrease in pressure in said second chamber to a value substantially lower than said threshold' pressure; a pressure-responsive piston adapted to engage said engine throttle; and a conduit interconnecting said piston with said first pressure chamber to actuate said piston between a full speed position in which said piston is disengaged from said throttle and an idle position in which said piston is in engagement with said throttle in predetermined time relationship with respect to actuation of said intake control valve between said loading and unloading positions.

4. An unloader and speed control device for an enginedriven air compressor or the like including an engine coupled in mechanical driving relationship to a compressor, a lluid storage device coupled to the outlet of said compressor, an intake valve vfor said compressor actuatable between two difterent operating positions to load and unload said compressor, and a throttle for said engine, said device comprising: a housing structure defining first and second pressure chambers, an inlet port for said first chamber interconnecting said two chambers, and an inlet port for said second chamber; a diaphragm mounted within said housing structure and constituting at least a portion of one wall of said fir'st pressure chamber, said diaphragm being actuatable between two given operating positions in response to predetermined changes in lluid pressure within said first pressure chamber; means mechanically connecting said diaphragm to said intake control valve to actuate said valve to its unloading position in response to actuation of said diaphragm to one' of said two operating positions and for actuating 'said valve to its loading position in response to actuation of said diaphragm to the other of its two operating positions; means for biasing 'said diaphragm toward said other position to establish a predetermined minimum valve actuation pressure for said intake valve; conduit means interconnecting said uid storage device and said inlet port of said second chamber; a pilot valve cornprising a second diaphragm mounted within said housing and constituting at least a portion of one wall of saidA second pressure chamber, said second diaphragm being interposed between said second pressure chamber and the inlet port of said first pressure chamber to admit uid under pressure to said first chamber in response to an increase in uid pressure within said second chamberv piston adapted to engage said engine throttle; a conduit 5 interconnecting said piston with said first pressure charnber to actuate said piston between a full speed position in which said piston is disengaged from said throttle and an idle position in which said piston is in engagement with said throttle; and means biasing said piston toward 10 2,661,893

its disengaged position to establish a predetermined mini- 10 mum piston actuation pressure substantially greater than said minimum valve actuation pressure whereby said piston is actuated to its full speed position before said compressor is loaded and to its idle position after said compressor is unloaded.

References Cited in the le of this patent UNITED STATES PATENTS Wainwright Dec. 9, 1913 Le Valley Dec. 8, 1953

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