US3592244A - Flask-charging apparatus - Google Patents

Abstract

Apparatus adapted for charging portable gas-containing flasks adapted for use with spraying devices. The apparatus includes a compressor driven by an electric motor, the operation of the motor being initiated by a switch engaged by the flask when the flask is operatively mounted at the charging station of the apparatus. A pressure-operated switch is disposed in the motor circuit for shutting off the motor driving the compressor when the flask has been charged to the desired predetermined pressure. The apparatus is provided with a novel check valve which is disposed between the compressor and the flask-charging station. The apparatus has a split housing, the parts of the housing being secured together by means which also secures the motor and the compressor to the housing.

Description

United States Patent Edward B. Chamber-1111 112 Fifth St., Garden City, N.Y. 1 1530 741,075

June 28, 1968 July 13, 1971 [72] Inventor [21] AppLNo.

[22] Filed [45] Patented [54] ASK-CHARGING APPARATUS Primary Examiner-Herbert F. Ross Attorney-Robert Ames Norton ABSTRACT: Apparatus adapted for charging portable gascontaining flasks adapted for use with spraying devices. The apparatus includes a compressor driven by an electric motor, the operation of the motor being initiated by a switch engaged by the flask when the flask is operativeiy mounted at the charging station of the apparatus. A pressure-operated switch is disposed in the motor circuit for shutting off the motor driving the compressor when the flask has been charged to the desired predetennined pressure. The apparatus is provided with a novel check valve which is disposed between the compressor and the flask-charging station. The apparatus has a split housing, the parts of the housing being secured together by means which also secures the motor and the compressor to the housing.

PATENTED JUL] 3 l97| SHEET 3 OF 3 ATTORzYS FLASK-CHARGING APPARATUS This invention relates to a gas-compressing apparatus, and more particularly relates to a gas compressor for chargin portable flasks for spraying devices and the like.

The invention has among its objects the provision of an apparatus of the type indicated which includes means mounted at the flask-charging station thereof for starting the compressor upon the positioning of a flask in operative position at the station. I

A further object of the invention lies in the provision of a gas compressor having a novel pressure-operated means for shutting ofithe compressor when the'flask has been charged to the desired predetermined pressure.

Yet another object of the invention lies in the provision of an improved check valve which is disposed at the delivery end of the compressor, such check valve being particularly characterized by its simplicity and positiveness of action.

Still a further object of the invention lies in the provision of an apparatus having a compressor powered by an electric motor which forms an integral part of the apparatus, theapparatus having a split housing, the parts of the housing being held together in a novel manner by means which also secures.

the pump of the compressor and the electric motor to the housing.

The above and further objects and novel features of the in vention will more fully appear from the following description when the same is read in connection with the accompanying drawings. It is to be expressly understood, however, that the drawings are for the purpose of illustration only, and are not intended as a definition of the limits of the invention.

In the drawings, wherein like reference characters refer to like parts throughout the several views,

FIG. I is a view in perspective showing an apparatus in accordance with the invention with an air flask about to be mounted at the charging station of the apparatus, a portion of the wall of the housing of the apparatus at the charging station being broken away;

FIG. 2 is a view in vertical longitudinal axial section through the apparatus, the section being taken along the line 2-2 of FIG. 1;

FIG. 3 is a view in horizontal section through the apparatus, the section being taken along the broken section line 3-3 of FIG. 2, certain of the parts being fragmentarily shown;

FIG. 4 is an enlarged view in vertical longitudinal section through the charging station of the apparatus with the bottom end of a flask being shown mounted at such station, the view also showing a portion of the compressor of the apparatus with the piston thereof having been retracted and the check valve of the compressor in operative position;

FIG. 5 is a view similar to FIG. 4 of the portion of the compressor and the check valve shown therein but with the piston of the compressor being shown in an operative stroke and the check valve thereof being shown in its inoperative position;

FIG. 6 is an exploded view in perspective of the head of the cylinder of the compressor and the parts cooperating therewith to form the compressor check valve;

FIG. 7 is a schematic wiring diagram showing the manner of control of the motor which drives the compressor; and

FIG. 8 is a view in vertical transverse section through the apparatus with an air flask mounted thereon, the section being taken along the line 8-8 of FIG. 3.

GENERAL DESCRIPTION The illustrative apparatus, which is generally designated by the reference character 10, is shown in FIG. I in conjunction with an air flask 11 which is about to be mounted upon the apparatus to be recharged. Such air flask is here shownas being employed to power a spray device generally designated 12. The combination of flask I1 and spray device 12 is completely portable when separated from the apparatus 10. Such apparatus may serve as the source of compressed air for a number of flasks employed in any particular operation or operations.

The apparatus 10 is provided with a verticaltube or hollow post 13 which mates with an inwardly closed end tube 18, which is sealed to the bottom of the flask 11, when the flask is mounted at the charging station. Tube 18 carries its own check valve 20 so that after being charged with compressed air the flask remains charged after its removal from the apparatus. The apparatus has an electric motor 14 which drives a reciprocating pump or compressor 15 so as to deliver compressed air to the inflation tube 13. Motor l4-is started upon the placing of the flask 11 in operative position at the charging station, there being a switch 16 interposed in the circuit of the motor for starting the motor when the flask is operatively positioned as shown in FIGS. 4 and 8. Motor 14 is stopped when 'the flask II has-been charged to the predetermined desired pressure, there being a second, pressure-operated switch 17 interposed in the motor circuit so that such circuit is opened when the desired charging pressure is attained. A novel check valve 19 disposed at the head of the reciprocating pump supplements the action of the check valve 20 of the-flask 11. The

pressure-responsive means operating the switch 17 is con- -ing operation.

The apparatus has a housing made up of upper and lower portions 22, 21. The motor 14 and the compressor or pump 15 are secured together by means which in part includes the means securing the portions of the housing together.

vSpecific Description As shown in FIGS. 2 and 8, the housing of the apparatus 10 is made in two parts, .there being a lower flat-bottomed and vertical-walled portion 21 and an upper portion 22 which has a rear, taller portion 24 within which the vertically mounted motor 14 is contained and a forward, shorter portion 25'which contains a circular cylindrical well 26 forming the charging station of the apparatus. The starting switch 16 for the motor 14 is mounted upon the bottom wall of the well 26 in the upper portion of the housing; the pressure-actuated switch 17 is mounted upon an angle bracket 23 affixed to the pump body 29 as shown in FIG. 2.

The structure of the compressor or pump of the apparatus and the manner in which it, the motor 14, and the two housing parts 21 and 22 are secured together are more clearly shown in FIGS. 2 and 3. The pump of the apparatus has a body 29 which is provided with three wings integral therewith and extending horizontally therefrom, two wings 30 projecting laterally in opposite directions while the third wing 31 projects rearwardly. The wings 30 and 31 rest upon flanges at the upper rear end of the lower housing part 21, a vertical bolt 33 extending through the flange on the bottom housing part 2.1, the respective wing-30, 31, and a flange on the bottom edge of the upper housing part 22. The lower end of the motor 14-rests upon the upper surface of the flange onithe upper housing part, the motor being secured to the housing by long vertical bolts 27, each of which extends through the stator of the motor and downwardly'through the flange on the upper housing portion, the respective wing on the pump body, and the lower flange.

The pump body 29 has a horizontal cylinder provided by a sleeve 32 therein, a piston 34 being reciprocated in the cylinder by the motor 14 through driving means including the vertical motor shaft 35, a crank disc 36 secured thereto, an eccentrically mounted crank pin 37 on the disc, and a connecting rod 39. Air is drawn into the housing'of the compressor through the grille 40 in the upper rear and top wall of portion 24 of the housing and thence into a port 41 in thesi'dewall-of the body 29 and sleeve 32, such port being uncoveredby the piston when the piston has travelled to the rear to approach its fully retracted position, as shown in H0. 2. Upon forward travel of the piston in its operative direction, it covers port 41 and then compresses the air remaining in the cylinder so as to deliver air in compressed condition through the forward end of the cylinder to the check valve 19.

Check valve 19 is particularly shown in FIGS. 4, 5, and 6. Such valve is contained within a cylinder head 44 having larger and smaller diametered portions 45 and 61, respectively. Portion 61 is provided with an axial passage 60 therethrough, the rear end of passage 60 being of forwardly converging frustoconical shape at 59. Portion 59 of the passage forms a first, outer seat of the valve. The larger end 45 of the cylinder head covers and is secured to the body 29 of the pump by head bolts 46. There is a short circular cylindrical cavity 47 in the cylinder head 44 coaxial of the cylinder within sleeve 32 and communicating with the passage 60 through the valve-seat-forming portion 59 thereof. An O-ring 49 is disposed within the cavity 47, the O-ring being of such diame ter as to be at least slightly compressed between the forward coplanar forward ends 54 of the pump body 29 and the sleeve 32 and the rear wall 57 of the cavity 47. A disc or wafer 50 having a thickness somewhat less than the axial depth of cavity 47 is disposed in the cavity coaxially thereof with its outer edge 51 in sealing engagement with the radially inner edge of the O-ring 49. The wafer 50 has at least one passage therethrough (two shown at 52), passages 52 being disposed at equal distances from the axis of the wafer with their radially inner edges in approximate alignment with the rear, larger diametered edge of the valve seat 59.

The second, inner seat of the valve 19 is provided by a small O-ring 55 which is held under at least a slight axial compression, when the pump is idle and there is no air pressure in passage 60, between the first, outer valve seat 59 and the for ward surface 56 of the wafer 50, the O-ring 55 constantly thrusting the wafer 50 rearwardly into the position shown in FIGS. 4 and with its rear edge portion engaging the forward end surface of sleeve 32. When the pressure of air in passage 60 exceeds that in the forward end of the pump cylinder, as it does under the condition of FIG. 4 in which the piston 34 is being retracted, the air in passage 60 thrusts the O-ring 55 into forcible sealing engagement with the outer valve seat 59 and the forward surface 56 of wafer 50. When, however, the pressure of air in the forward end of the pump cylinder exceeds that within the passage 60, as during a forward, operative stroke of the piston 34 (FIG. 5), air flows from the cylinder forwardly through holes 52 in the wafer 50 and thence radially inwardly toward the O-ring 55. Such air locally distorts the O- ring 55 in the vicinity of the holes 52 to force the O-ring radially inwardly away from valve seat 59, so that air then flows forwardly into passage 60. When the pressure rearwardly of the valve 19 is reduced to a value substantially below that forwardly of the valve, the valve is again sealed against the rearward flow of air therethrough. The resilience of the O-ring 55 and the holding of it under compression between surfaces 56 and 59 aid the O-ring 55 in its described function in the valve 19.

The forward end of the smaller diametered portion 61 of the cylinder head 44 sealingly receives the rear end of a conduit 62, the forward end of such conduit being similarly received within and sealed to the rear, lower horizontal branch of a branched or T-fitting 64. Conduit 62 communicates with a passage 63 in such fitting 64, passage 63 leading to a central cavity 72 therein. The hollow inflation post 13 has an enlarged lower end 65 thereon; portion 65, which is threaded at its lower end, extends through a hole 66 in the bottom 67 of the well 26 of the apparatus and is threadedly connected to the upper portion of fitting 64 at 69'. Upper and lower O- rings 69, 71 mounted between a flange 70 on member 65 and the upper and lower surfaces, respectively, of the bottom wall 67 cushion the inflating tube 13 and retain it securely in place on the bottom 67 of the well 26. The lower end of the central passage 77 in post 13 directly communicates with the cavity 72 in fitting 64.

The upper end portion 74 of the post 13 is ofcircular cylindrical configuration, such portion 74 having upper and lower rings 75, 76 disposed in axially spaced upper and lower transverse annular grooves in the outer surface thereof.

The post 13 is provided with a plurality of radial passages 79 through the wall thereof adjacent its upper end, passages 79 being connected at their outer ends with a transverse annular groove 80 in the outer surface of post 13. The passages 79 and the groove 80 constitute a port through which air is delivered under pressure from the cavity 72 and passage 77 to the flask 11 being charged.

When the flask is mounted upon the post 13 in operative position at the charging station as shown in FIG. 4, the annular groove 80 confronts and communicates with a plurality of radial passages 81 through the wall of the tube 18 sealingly affixed to the bottom wall 83 of the flask 11. An annular groove 82 which is of V-cross-section is provided in the outer wall of the member 18, there being an O-ring 84 disposed in such groove. It will be apparent that upon the subjection of the space within the flask 11 to a pressure which exceeds that in passage 77 the O-ring 84 is strongly thrust into sealing engagement with the surfaces of the groove 82 at the cessation of each pumping stroke of the pump. When, however, the pressure of air delivered from the pump to the passage 77 exceeds that within the flask 11, the O-ring 84 is thrust outwardly so as to open the inflating port in the member 18 so that air may then flow into the flask.

The pressure-responsive switch 17 is operated by means particularly shown in FIGS. 2 and 4. The fitting 64 has a further, horizontal branch within which there is disposed a horizontal cylinder 85 having a piston 86 reciprocable therewithin. Affixed to the piston 86 there is a piston rod 89 which is guidingly received within a central bore 90 in a bushing 87 which is affixed to the fitting 64 to close the outer end of the cylinder 85. The piston 86 is constantly urged toward its rear, inner position by a coil compression spring 91 which acts between the piston 86 and the inner end of the bushing 87. The piston 86 and piston rod 89 are held in their inner position, shown in FIG. 4, by a collar 92 which is affixed to the piston rod 89 and abuts a surface on the outer end of the bushing. The position of the piston 86 and piston rod 89 serves as a measure of the pressure of air in the cavity 72 during a flaskcharging operation. When the pressure in the cavity 72 of air delivered by the pump, and thus the air pressure within the flask being charged, reaches a certain value, the piston and piston rod are thrust outwardly sufficiently for the outer end 94 of the piston rod 89 to engage and thrust forwardly a plunger 95 of the pressure-responsive switch 17. Thereupon switch 17 is opened and the motor 14 is stopped. As will be seen in FIG. 7, switches 16 and 17 are disposed in series with the motor in a motor supply circuit extending between supply terminals L and L The flask 11 in this instance is employed as a source of air pressure for a spraying device 12, as above indicated. Device 12 is connected to a flask closure member 96 affixed to the outer end of the neck 97 of the flask. Device 96 includes a valve 99, not specifically shown, which is opened upon the depressing of a valve-operating button 100. Connection between the outlet passage from the valve 99 and the spraying device 12 is effected through a quick-operating connector 101. The spraying device shown includes an aspirator 102 which receives liquid 105 in the container through the medium of a dip tube 104. Upon the opening of the valve 99, the mixture of atomized liquid 105 and air from the flask 11 is delivered through the spray orifice 106 of the device 12. It is to be understood that charged flasks 11 may be employed with other types of spraying devices, as well as sources of compressed air for other operations.

It will be apparent from the above that in operating the apparatus of the invention the placing of an empty flask 11 in charging position within the well 26, the plunger 28 of the normally open switch 16 is depressed by engagement with the bottom wall 83 of the flask to close such switch. Since the pressure-operated switch 17 is now closed, the motor 14 starts. Charging of the flask ll continues until forward movement of piston rod 89 opens switch 17 to stop the motor. Upon the removal of the charged flask 11 from the charging ap paratus 10, switch 16 opens and switch 17 closes to restore the apparatus to its initial condition, so that it is in readiness for the charging of another flask.

Although only one embodiment of the invention has been il lustrated in the accompanying drawings and described in the foregoing specification, it is to be especially understood that various changes, such as in the relative dimensions of the parts, materials used, and the like, as well as the suggested manner of use of the apparatus of the invention, may be made therein without departing from the spirit and scope of the in vention, as will now be apparent to those skilled in the art.

Iclaim:

1. An apparatus for charging portable containers having at one end a hollow gas inlet port provided with a check valve permitting flow of gas only into the container, said apparatus comprising a container-charging station adapted to have the end of a container carrying the gas inlet port positioned thereon, a tubular outlet means fixedly connected to the charging station and positioned and dimensioned to slidably receive the gas inlet port and produce a gastight seal when the container is slid thereon, said tubular outlet means comprising a post having passage means for alignment with said check valve and elastic means for sealingly engaging said hollow inlet port of said container for a predetermined pressure, said elastic means engaging said hollow inlet port on each side of said check valve to preclude said container from being propelled from said post. gas-compressing means and a connection to the tubular outlet means, and means responsive to sliding a container into the charging station to initiate the gascompressing means, whereby when a container is slid on the charging station compressed gas passes through the tubular outlet and the gas inlet port of the container into the container only when the passage and check valve are aligned.

2. An apparatus according to claim 1 in which the gas-compressing means is driven by a motor and the means responsive to sliding a container on the charging station is a switch connected to start the motor.

3. An apparatus according to claim 1 in which the gas-compressing means is provided with a stopping means actuated when gas pressure into the container exceeds a predetermined amount.

4. An apparatus according to claim 2 in which the gas-compressing means is provided with a switch actuated by gas pressure to the container in excess of a predetermined amount, said switch stopping the motor.

5. An apparatus according to claim 2 in which the switch acmated by sliding a container on the charging station is a spring switch and opens under spring pressure when a charged container is slid off of the charging station.

6. An apparatus according to claim 4 in which the switch actuated by sliding a container on the charging station is a spring switch and opens under spring pressure when a charged container is slid offof the charging station.

Claims (6)

1. An apparatus for charging portable containers having at one end a hollow gas inlet port provided with a check valve permitting flow of gas only into the container, said apparatus comprising a container-charging station adapted to have the end of a container carrying the gas inlet port positioned thereon, a tubular outlet means fixedly connected to the charging station and positioned and dimensioned to slidably receive the gas inlet port and produce a gastight seal when the container is slid thereon, said tubular outlet means comprising a post having passage means for alignment with said check valve and elastic means for sealingly engaging said hollow inlet port of said container for a predetermined pressure, said elastic means engaging said hollow inlet port on each side of said check valve to preclude said container from being propelled from said post, gas-compressing means and a connection to the tubular outlet means, and means responsive to sliding a container into the charging station to initiate the gas-compressIng means, whereby when a container is slid on the charging station compressed gas passes through the tubular outlet and the gas inlet port of the container into the container only when the passage and check valve are aligned.

2. An apparatus according to claim 1 in which the gas-compressing means is driven by a motor and the means responsive to sliding a container on the charging station is a switch connected to start the motor.

3. An apparatus according to claim 1 in which the gas-compressing means is provided with a stopping means actuated when gas pressure into the container exceeds a predetermined amount.

4. An apparatus according to claim 2 in which the gas-compressing means is provided with a switch actuated by gas pressure to the container in excess of a predetermined amount, said switch stopping the motor.

5. An apparatus according to claim 2 in which the switch actuated by sliding a container on the charging station is a spring switch and opens under spring pressure when a charged container is slid off of the charging station.

6. An apparatus according to claim 4 in which the switch actuated by sliding a container on the charging station is a spring switch and opens under spring pressure when a charged container is slid off of the charging station.

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