|Publication number||US3307296 A|
|Publication date||Mar 7, 1967|
|Filing date||Feb 26, 1964|
|Priority date||Feb 27, 1963|
|Also published as||US3286406|
|Publication number||US 3307296 A, US 3307296A, US-A-3307296, US3307296 A, US3307296A|
|Inventors||Ives Ashworth Stewart|
|Original Assignee||Abrasive Dev|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (3), Referenced by (12), Classifications (6)|
|External Links: USPTO, USPTO Assignment, Espacenet|
March 7,1967 I a H H 3,307,296
ABRADING MACHINES Filed Feb. 26, 1964 United States Fatent 3,307,296 ABRADING MACHINES Stewart Ives Ashworth, Crimond, Outhill, near Studley,
England, assignor to Abrasive Developments Limited,
Solihull, England, a British company Filed Feb. 26, 1964, Ser. No. 347,589 Claims priority, application Great Britain, Feb. 27, 1963, 7,808/63; Nov. 9, 1963, 44,305/63 5 Claims. (Cl. 51-8) This invention relates to abrading machines. In such machines, a stream of air and abrasive is directed against a workpiece and abrasive and detritus are removed from adjacent the workpiece by means of suction. It is often necessary to separate from the suction air stream the abrasive which can be reused on the one hand and to discard the shattered abrasive and detritus on the other hand. Having separated the reusable abrasive from the waste, it is then necessary to feed such abrasive back into the system. Since the input pipe containing the air and abrasive being fed to abrade the workpiece will be at a greater pressure than the suction pipe in which the abrasive and detritus is removed from adjacent the workpiece, it is necessary to provide some form of airlock to accomplish this recirculation of the abrasive.
Accordingly it is an object of the invention to provide an abrading machine in which simple means is provided for re-circulating the abrasive.
Two embodiments of the'invention will now be described in detail by way of example with reference to the accompanying drawings in which:
FIGURE 1 is a diagram of a first embodiment of the invention, and
FIGURE 2 is a similar diagram of a second embodiment of the invention.
Referring now to FIGURE 1, the abrading machine comprises a portable blasting chamber which presents at one face an opening 11 adapted to be placed on a flat surface of a workpiece 12 with the edge portions of the opening close to the surface. The edges of the opening are provided with a seal 13 which may comprise rollers, rubber or plastic shielding or bristles or a combination of any of these elements.
Into the top of the box 10 there extends directing means in the form of an accelerating nozzle 14 which is attached to the end of a flexible portion 15 of an input pipe indicated generally at 16. The other end of the input pipe 16 is provided with a bell-mouth 17 which constitutes an air intake and is open to atmosphere. Between the air intake 17 and the nozzle 14 there is provided in the input pipe a recess 18 in the lower wall thereof and a bafile 19 is provided up-stream of the recess 18 so that air flowing through the input pipe from the air intake 17 to the nozzle 14 is forced to flow through the recess 18.
The upper end of the blasting chamber 10 is also connected to one end of a suction pipe 20 which at its other end is connected to the inlet 21 of a first cyclone separator 22. The cyclone is of conventional form having a rubber lining and is deliberately made relatively ineffective so that only the heavier particles contained in the air stream entering the cyclone are separated and fall to the bottom of the cyclone, the lighter particles being carried out of the outlet 23 of the cyclone into a second cyclone 24. The cylone 24 is of a high reentrant type which operates under a fairly high vacuum and effectively separates out the finer particles.
The effectiveness of the second cyclone is believed to be due not only to the low pressure within the cyclone but also because the low pressure leads to adiabatic cooling within the central spinning whirl of the cyclone so that any moisture in the air stream condenses on the dust Kid particles thus increasing their weight and increasing the separating effect of the cyclone. This theory is supported by the fact that if the dust is inspected immediately after being separated by the second cyclone 24 it is slightly damp and is at a low temperature.
The lower outlet 25 from the cyclone 24 leads to an intermediate box 26 which in turn leads to a dust collecting. box 27. As will be seen from the drawing, the intermediate box 26 is of such a shape that the inlet 28 to the dust collecting box is off-set from the vertical axis of the cyclone 24. This prevents the whirling air in the cyclone 24 from disturbing the dust in the dust collecting box 27.
The cyclone 24 has an upper outlet 29 which is connected through an adjustable valve 30 to a multistage centrifugal fan 31. The valve 30 regulates the intensity of the vacuum created within the cyclone and therefore controls the entry of air into the intake 17.
'The first cyclone 22 has a lower outlet 32 which is connected to the upper end of an upper hopper 33. The upper hopper in turn has a lower outlet 34 which discharges into a middle hopper 35. The middle hopper 35 has a downwardly converging lower wall 35a leading to a pipe 35b at the bottom of which is an outlet 36 which discharges into a lower hopper 37 and the lower hopper 37 surrounds the wall 35a and has an outlet 38 which discharges into a metering tube 39 whose lower end is received in the recess 18 in the input pipe.
Communicating with the middle hopper is a pipe 40 which contains first valve means 41 and which terminates in a bell-mouth 42 which is open to atmosphere. The valve means 41 is driven by cycling means so that the valve is alternately opened and closed. The pipe 40 is connected by a pipe 43 to the inlet 21 to the first cyclone 22. A restrictor 43a is inserted between the pipe 40 and the pipe 43.
At the outlet 34 of the upper hopper is provided second valve means 44 in the form of a flap valve. The valve is freely hinged and is operated by differences between the pressures existing in the upper and middle hoppers. When the pressure in the middle hopper is greater than the pressure in the upper hopper the second valve means will close. Conversely, when the pressure in the upper hopper is greater than the pressure in the middle hopper, the second valve means will open.
Third valve means 45 are provided at the outlet 36 of the middle hopper and these valve means operate in a manner similar to the second valve means 44. Thus when the pressure in the lower hopper is greater than the pressure in the middle hopper the third valve means 45 will close whereas when the pressure in the middle hopper is greater than the pressure in the lower hopper, the third valve means will open.
It is apparent that any abrasive stored above either of the valve means 44 or 45 will tend to cause them to open even when the pressure below the valve means is slightly greater than the pressure above the valve means. However, the pressure diiferences are arranged to take into account the weight of such abrasive and to maintain the valve means closed when required.
In operation, the centrifugal pump 31 is set in operation and the valve 30 is opened to induce suction in the suction pipe as far as the blasting chamber 10. When the blasting chamber 10 is in contact with the workpiece 12 so that the seal 13 substantially seals the aperture 11 to the workpiece, the suction is applied to the input pipe 16 and air starts to flow through the input pipe 16 from the air intake 17 to the nozzle 14. As the air flows along the input pipe 16 it will be deflected 'by the baffle 19 to flow through the recess 18. As will hereinafter be described, abrasive is delivered into the recess 18 through the metering tube 39. The abrasive is entrained in the air stream and passes with the air along the input pipe 16 to the accelerating nozzle 14. The abrasive particles are accelerated in the nozzle and will impinge upon the surface of the workpiece 12 and will abrade the surface thereof. The spent abrasive and air will then pass along the suction pipe 20 to the inlet 21 of the first cyclone 22. As has been mentioned above, this cyclone is somewhat ineffective and it is thus able to separate the reusable abrasive which has not been shattered from the spent abrasive which has been shattered into dust. The reusable abrasive passes to the bottom of the first cyclone 22 into the upper hopper 33.
The shattered abrasive and the detritus from the surface of the workpiece remain in the air stream and pass through the outlet 23 of the first cyclone 22 to the second cyclone 24. p In this cyclone, the spent abrasive and detritus are separated from the air and the latter passes through the outlet from the cyclone through the valve 343 to the centrifugal fan 31. The dust, comprising shattered abrasive and detritus falls to the outlet 25 of the second cyclone 24 passes into the intermediate box 26 and thus into the dust collecting box 27.
Returning now to the reusable abrasive, this collects in the upper hopper 33. Assuming that the first valve means 41 is in a position such that the middle hopper is in communication with atmosphere, the pressure in the middle hopper will be greater than the pressure in the upper hopper, the latter pressure being equal to the pressure in the cyclone 22. The valve 44 will thus be shut and abrasive will build up in the upper hopper 33. The lower hopper 37 is always at atmospheric pressure by virtue of apertures 46 in the upper part of the wall 37a thereof which surrounds the converging wall 35a of the middle hopper 35. It follows that, when the pressure in the middle hopper is atmospheric, any abrasive in the middle hopper above the third valve means will open the valve means since the air pressure is the same on both sides thereof and the abrasive will fall into the lower hopper 37 and from thence to the metering tube 39 and the input pipe 16.
If now the first valve means 41 moves to a position such that the middle hopper 35 is in communication with the cyclone inlet 21, the air pressure on both sides of the second valve means 44- will be equal and any abrasive in the upper hopper will thus cause the second valve means to open 44 and the abrasive will pass to the middle hopper 35. In this situation, since the middle hopper is at a lower pressure than atmospheric, the third valve means 45 will be shut so that the abrasive delivered to the middle hopper will remain therein until the first valve means again places the middle hopper in communication with atmosphere. The first valve means are arranged to cycle at a predetermined rate so that there is a constant supply of abrasive being passed from the cyclone 22 to the metering tube 39 through the upper, middle and lower hoppers.
The metering tube 39 is adjustably mounted in the input pipe 16 so that the bottom of the metering pipe may be adjusted with respect to the bottom of the recess 18. By this means, the amount of abrasive entrained in the air stream can be varied..
Turning now to FIGURE 2, the abrading machine there shown comprises a generally rectangular cabinet having in its upper portion an observation window 51. The cabinet is provided with arm-holes 52 which lead into rubber gloves so that an operator of the machine can place his hands in the gloves and manipulate a workpiece inside the cabinet. The workpiece is arranged to rest upon a grille 53 extending across the cabinet approximately half way up the cabinet. Beneath the grille is a sump 54 of inverted pyramidical form.
Mounted inside the cabinet on a flexible part 55 of an input pipe 56 is a nozzle 5'7 which accelerates the air and abrasive passing therethrough. The nozzle is provided with a handle 58 to assist in manipulation thereof. In
the top of the cabinet is a ventilator 59 to allow additional air to enter the cabinet.
At its other end, the input pipe 56 is connected to a pressure manifold 60 which in turn is connected to the outlet of a centrifugal fan or blower 61 by means of a pipe 62. The fan 61 is arranged to deliver air to the manifold 69 at a pressure of approximately 5 p.s.i. The input pipe is provided with a recess 63 in its lower wall and into this recess projects a metering pipe 64- from a lower hopper 65 as will hereinafter be described. A bafiie 66 is arranged in the input pipe upstream of the re cess 63 and this bafiie ensures that air passing along the input pipe 56 passes through the recess 63.
The abrasive falls through the grille 53 into the sump 54 after having acted on the workpiece and the abrasive and air in the cabinet is removed by means of a suction pipe 67, which is connected to the inlet 68 of a first cyclone 69. The bottom outlet of the first cyclone 69 is connected to an upper hopper 70 the lower outlet of which is connected in turn to a middle hopper 71 and the lower outlet of the middle hopper 71 is connected to the lower hopper 65. The lower hopper 65 is also connected by a pipe 72 to the manifold 60. The middle hopper 71 is connected by means of a pipe 73 to the manifold 60 through first valve means 74. The pipe 73 is also connected by means of a pipe 75 to the central portion of the first cyclone 69. The pipe 75 contains a restrictor 76.
Second valve means 77 are arranged at the outlet of the upper hopper 7t and third valve means 78 are arranged at the bottom of the middle hopper 71. The valve means are operated by a pressure difference between the hoppers in the same manner as the valve means 44 and 45 in the embodiment shown in FIGURE 1.
The first cyclone 69 has an upper outlet 79 which is connected to the inlet of a second cyclone 80. The second cyclone 86 has a lower outlet 81 which is connected to an intermediate box 82 and a dust collecting box 83 in a manner similar to that described with reference to the first embodiment. The upper outlet 84 of the cyclone is connected to a centrifugal fan 85 through a valve 86.
Except that the system is under a low pressure of some p.s.i. induced by the centrifugal fan 61, it operates in the same manner as does the embodiment described with reference to FIGURE 1. Thus when the centrifugal fans 85 and 61 are started, air is blown into the cabinet and entrains abrasive from the recess 63, the abrasive being delivered by the nozzle 57 onto the workpiece in the cabinet. The used abrasive, detritus and air is removed from the cabinet by means of the suction pipe 67 and delivered to the first cyclone 69. In the first cyclone, the reusable abrasive is separated out and collects in the upper hopper 70. The reusable abrasive passes to the metering tube 64 in the same manner as described with reference to the first embodiment except that in this case, since the inlet pipe is at the pressure of the manifold 60, the lower hopper is connected to the manifold 60 by the pipe 72 and the first valve means 74 is also connected to the manifold 60 so that the pressure in the middle hopper alternates between that in the manifold 6t) and that in the centre of the first cyclone 69.
By way of example, the timing of the operation of the first valve means may be arranged so that there will be no build-up of abrasive in either the upper or middle hoppers. For example, the first valve means may be arranged to open for ten seconds followed by a closed period of ten seconds followed by an open period of ten seconds and so on.
1. An abrading machine comprising directing means for directing air and abrasive against a workpiece, an input pipe for conveying air and abrasive to the directing means, a suction pipe for conveying a mixture of air, reusable abrasive, shattered abrasive and detritus from adjacent the workpiece, a separator to which the suction pipe delivers said mixture and which separates reusable abrasive from the remainder of the mixture, an upper hopper connected to the separator to be fed with reusable abrasive therefrom, means placing the upper hopper in communication with the suction pipe, a lower hopper to deliver abrasive by gravity into the input pipe, means continuously maintaining the interior of the lower hopper at substantially the same pressure as that in the input pipe, a middle hopper interposed between the upper and lower hoppers and communicating with them both, first valve means for selectively placing the middle hopper at one of the pressures of the suction pipe and the input pipe, cycling means for operating the first valve means so that the pressure in the middle hopper is changed continually, and abrasive controlling second and third valve means between the upper and middle hoppers and the middle and lower hoppers respectively, each of said second and third valve means comprising a valve member freely movable between open and closed positions in response to the net resultant force exerted on the member by differences in the pressures in the hoppers between which the valve member is interposed and the downward force exerted on the member by any abrasive in the hopper above the valve member, the second valve means opening and the third valve means closing when the middle hopper is at suction pipe pressure, and the second valve means closing and the third valve means opening when the middle hopper is at input pipe pressure.
2. An abrading machine according to claim 1 including a continuously open conduit between the middle hopper and one of the suction pipe and the separator and a restrictor in said conduit and wherein the first valve means is interposed between the middle hopper and one of the atmosphere and a source of super-atmospheric pressure.
3. An abrading machine according to claim 1 wherein each of said valve members is a pivoted flap.
4. An abrading machine according to claim 1, including means continuously placing the lower hopper and the input pipe open to atmosphere.
5. An abrading machine according to claim 1, including means continuously subjecting the lower hopper and the input pipe to a super-atmospheric pressure.
References Cited by the Examiner UNITED STATES PATENTS 2,521,931 9/1950 Mead 5l12 2,628,456 2/ 1953 Berg 5 18 2,810,991 10/1957 Mead et a1. 5l8
LESTER M. SWINGLE, Primary Examiner.
|Cited Patent||Filing date||Publication date||Applicant||Title|
|US2521931 *||Oct 18, 1948||Sep 12, 1950||Mead William H||Grit feed valve|
|US2628456 *||Jan 15, 1952||Feb 17, 1953||Mariblast Corp||Sandblasting device|
|US2810991 *||Feb 18, 1955||Oct 29, 1957||Mead William H||Abrasive blasting apparatus|
|Citing Patent||Filing date||Publication date||Applicant||Title|
|US3404556 *||Jun 18, 1965||Oct 8, 1968||Boris M. Kameras||Abrasion resistance testing apparatus|
|US3461478 *||May 2, 1966||Aug 19, 1969||Taylor Bernard||Apparatus for cleaning surfaces|
|US3640023 *||Aug 19, 1969||Feb 8, 1972||Abrasive Dev||Abrading machines|
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|US4258505 *||Mar 2, 1979||Mar 31, 1981||Metallgesellschaft Aktiengesellschaft||Method of and apparatus for the surface cleaning of workpieces|
|US4470226 *||Aug 30, 1982||Sep 11, 1984||Wynfor Corporation||Bathtub abrading system|
|US4671022 *||Aug 31, 1984||Jun 9, 1987||Williams David R||Bathtub abrading system|
|US5100412 *||Jan 11, 1989||Mar 31, 1992||L.I.C.A. Di Rosso & C. S.N.C.||Apparatus for making micro-abrasions, particularly on human tissue or on hides|
|US5207234 *||Mar 5, 1992||May 4, 1993||L.I.C.A. Di Rosso & C.S. N.C.||Method for making micro-abrasions on human tissue|
|US5709587 *||Mar 25, 1996||Jan 20, 1998||Kennametal Inc.||Method and apparatus for honing an elongate rotary tool|
|US5762538 *||Dec 9, 1996||Jun 9, 1998||Kennametal Inc.||Method and apparatus for honing an elongate rotary tool|
|US5775979 *||Oct 22, 1996||Jul 7, 1998||Coke; Dan A.||Enclosed abrasive blasting apparatus|
|U.S. Classification||451/2, 451/88|
|International Classification||B24C3/00, B24C3/06|