US754672A - Rotary steam-engine. - Google Patents
Rotary steam-engine. Download PDFInfo
- Publication number
- US754672A US754672A US16275803A US1903162758A US754672A US 754672 A US754672 A US 754672A US 16275803 A US16275803 A US 16275803A US 1903162758 A US1903162758 A US 1903162758A US 754672 A US754672 A US 754672A
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- Prior art keywords
- piston
- steam
- valve
- engine
- exhaust
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- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04C—ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
- F04C23/00—Combinations of two or more pumps, each being of rotary-piston or oscillating-piston type, specially adapted for elastic fluids; Pumping installations specially adapted for elastic fluids; Multi-stage pumps specially adapted for elastic fluids
- F04C23/001—Combinations of two or more pumps, each being of rotary-piston or oscillating-piston type, specially adapted for elastic fluids; Pumping installations specially adapted for elastic fluids; Multi-stage pumps specially adapted for elastic fluids of similar working principle
Definitions
- My invention consists in mechanical dcvices and combinations for securing and util- Figure l is a perspective of my invention,-
- Fig. 2 is a detail plan of valve G.
- Fig. 3 is a section of exhaust-valve T.
- Fig. 4 is a section of the rotary receiver-valve.
- Fig. 5 is a front view of A of Fig. 1 with the casing removed.
- Fig. 6 is a detail sectional view showingthe subsidiary exhaust-channels in the cylinders.
- Fig. 7 is a detail drawing of the cylinder-packing ring.
- Fig. 8 isa plan of the piston with two stems, although a piston with one stem may be used.
- A is the high -pressure
- B the low-pressure, parts of the engine, and a a part of the casing, which is removed in the lower part of Fig. 1.
- B is the pillow-block; b, the covering of the bearing; G, the power-shaft; C, the fly-wheel to which the shaft C is keyed, and O the flywheel of B.
- 'D is the eccentric of A, housed behind b; D, the eccentric of B.
- E E are straps about the eccentrics D and D.
- L is the steam-supply pipe; M, the throttle-pipe. (Shown only in dotted lines, Figs. 1 and N is the steam-space between the casing and the outer periphery of the wheel C, which space forms the high-pressure cylinder of A and is provided at the steam-entrance with the abrupt shoulder a and extends to the exhaust X, from which it gradually tapers to a Steamtight joint at Y.
- N is the space between the casing and the wheel G which forms the low-pressure cylinder of B, extending to the exhaust X and tapering to Y.
- O is the piston; 0 0, the piston-stems for A; O, the piston for B, (its guides not shown.)
- P P are springs normally pressing the piston outwardly.
- ' R is the exhaust from A to B and is so enlarged as to constitute a receiver.
- S is the emergency-valve
- T the exhaustvalve
- U is the rotary receiver-valve.
- V V V V are the subsidiary exhaust-grooves to allow the escape of the steam after the pistons pass X X.
- W is the packing. It will be seen that the half-rotary valve is worked by an eccentric and by a lever which automatically adjust themselves to a non-reversible engine.
- Fig. 6 I have shown the subsidiary channels whereby the steam when it reaches X in the part A may pass under the piston back to the exhaust, and so on to R.
- the advantage of these subsidiary channels or grooves is to avoid the impact which otherwise would occur in the exhaust.
- a supply-pipe a valve therefor operated by an eccentric and a lever, a double-stem piston, a cylinder having a plurality of packing-rings distributed along the piston in grooves, a flywheel carrying said rotatable cylinder and piston, an eccentric carried by said fly-wheel and connected with a lever for operating said valve, an exhaust X, a receiver R, and a second similar piston, cylinder, fly-wheel carrying same, and eccentric; substantially as described and shown.
- a rotary fluid-engine the combination of a casing provided through part of its periphery with an annular steam-space, a rotating disk forming the inner wall of said steamspace, an outwardly-pressed piston carried by said disk and adapted to close said steam-space when outwardly pressed, a supply-pipe entering said steam-space, an adjustable valve therein driven by an eccentric from said disk to operate said valve, an exhaust-port opening into said steam-space, and subsidiary exhaust-grooves in said casing across the exhaustport, as and for the purpose described, all substantially as described.
- a double-stemmed piston O having packinggrooves 1 and the stems 0, 0; substantially as and for the purpose described.
Description
No. 754,672. PATENTED MAR. 15, 1904.
H. 0. MITCHELL. ROTARY STEAM ENGINE. APPLICATION FILED JUNE 23, 1903.
N0 MODEL, 2 SHEETS-SHEET 2.
WITNESSES: INVENTOR.
UNITED STATES Patented March 15, 1904.
PATENT OFFICE.
ROTARYSTEAlVl-ENGINE.
SPECIFICATION forming part of Letters Patent No. 754,672, dated March 15, 1904.
Application filed June 23,1903. Serial No. 162,758. (No model.)
To all whom it may concern.-
Be it known that I, HENRY C. MITCHELL, of
Andover, Massachusetts, have invented a new turbineengines-and is intended to avail of all the power of steam expansion instead of a part of it.
My invention consists in mechanical dcvices and combinations for securing and util- Figure l is a perspective of my invention,-
showing the high-pressure .part of the engine A and the low-pressure part of the en- 7 gine B. Fig. 2 is a detail plan of valve G.
Fig. 3 isa section of exhaust-valve T. Fig. 4 is a section of the rotary receiver-valve. Fig. 5 is a front view of A of Fig. 1 with the casing removed. Fig. 6 is a detail sectional view showingthe subsidiary exhaust-channels in the cylinders. Fig. 7 is a detail drawing of the cylinder-packing ring. Fig. 8 isa plan of the piston with two stems, although a piston with one stem may be used.
In the drawings, as already remarked, A is the high -pressure, and B the low-pressure, parts of the engine, and a a part of the casing, which is removed in the lower part of Fig. 1.
B is the pillow-block; b, the covering of the bearing; G, the power-shaft; C, the fly-wheel to which the shaft C is keyed, and O the flywheel of B.
'D is the eccentric of A, housed behind b; D, the eccentric of B.
E E are straps about the eccentrics D and D.
trio-rod for B.
Gis the adjustable valvelever; H, the valve; J, the valve-shaft, and K the valveopening.
L is the steam-supply pipe; M, the throttle-pipe. (Shown only in dotted lines, Figs. 1 and N is the steam-space between the casing and the outer periphery of the wheel C, which space forms the high-pressure cylinder of A and is provided at the steam-entrance with the abrupt shoulder a and extends to the exhaust X, from which it gradually tapers to a Steamtight joint at Y.
N is the space between the casing and the wheel G which forms the low-pressure cylinder of B, extending to the exhaust X and tapering to Y.
O is the piston; 0 0, the piston-stems for A; O, the piston for B, (its guides not shown.)
P P are springs normally pressing the piston outwardly.
' R is the exhaust from A to B and is so enlarged as to constitute a receiver.
S is the emergency-valve; T, the exhaustvalve. (Shown in' Fig. 3.) U is the rotary receiver-valve. These valves are only modifications of well-known forms.
V V V are the subsidiary exhaust-grooves to allow the escape of the steam after the pistons pass X X.
W is the packing. It will be seen that the half-rotary valve is worked by an eccentric and by a lever which automatically adjust themselves to a non-reversible engine.
The operation of my invention will be plain from these drawings. The steam being admitted from the supply-pipe L through the pipe M and the valve G, acts upon the piston O in the cylinder N, therebycausing revolution of-said cylinder and the fly-wheel, which revolution by reason of the eccentric D acting upon the rod F closes the adjustable valve G and permits the continuous expansion of the steam until the piston 0 passes the point X in the cylinder, whereupon the steam is admitted to the receiver R of B. the lowpressure engine.
G to the boiler-pressure permits both of using any normal boiler-pressure required and of cutting off the steam'coming through the valve G at any desired extent of movement The adjustability of valve IOO of piston O, and the same is true of piston 0. Also it will be understood that from about X to Y piston O constantly recedes into the fly-wheel C, and from Y to cylinder N, Fig. 5, said piston is wholly within the flywheel, and the same is true of piston O and its cylinder C Upon the piston O reaching the position again, as shown in Fig. 1, the efiect of the eccentric will have been to again open the valve G and steam will again be admitted to operate the piston O, as before, and continuously until shut off. The exhauststearn which passes to .the receiver R entering the cylinder N of B expands against the piston O, causing a similar operation to that in the part A -that is to say, the rotation of wheel C and the continuous advance of the piston O until the same passes the exhaust X, at which point the ordinary open-air exhaust may be used or the steam may be condensed in the usual way or another, and if required a succession of the parts B may be used.
In Fig. 6 I have shown the subsidiary channels whereby the steam when it reaches X in the part A may pass under the piston back to the exhaust, and so on to R. The advantage of these subsidiary channels or grooves is to avoid the impact which otherwise would occur in the exhaust.
As a packing for the piston O, I prefer the construction shown in Fig. 7 in which W shows a metallic spring clasping the piston in grooves 1 1 1, Fig. 8, for by reason of this any wear from the movement of the cylinder, and
consequent variation in the tightness of the piston, will be compensated by the spring action of the packing. The only use of energizing-valve S will be in case of the engine stopping with valve G closed.
the exhaust to a steam-tight joint, subsidiary exhaust-grooves and a fiy-wheel carrying said rotatable cylinder and piston.
2. In a non-reversing rotary engine, a supply-pipe, a valve therefor operated by an eccentric and a lever, a double-stem piston, a cylinder having a plurality of packing-rings distributed along the piston in grooves, a flywheel carrying said rotatable cylinder and piston, an eccentric carried by said fly-wheel and connected with a lever for operating said valve, an exhaust X, a receiver R, and a second similar piston, cylinder, fly-wheel carrying same, and eccentric; substantially as described and shown.
3. In a rotary fluid-engine, the combination of a casing provided through part of its periphery with an annular steam-space, a rotating disk forming the inner wall of said steamspace, an outwardly-pressed piston carried by said disk and adapted to close said steam-space when outwardly pressed, a supply-pipe entering said steam-space, an adjustable valve therein driven by an eccentric from said disk to operate said valve, an exhaust-port opening into said steam-space, and subsidiary exhaust-grooves in said casing across the exhaustport, as and for the purpose described, all substantially as described.
4. In a non-reversing rotary steam-engine, the combination of the double-stem piston 0 having the grooves I with the steam-packing W composed of resilient metal substantially circumferential to the form of the piston, and closely fitting the same, and broken at its lower part to admit of a spring action as required.
5. In a rotary engine operated by steam expansion, a double-stemmed piston O having packinggrooves 1 and the stems 0, 0; substantially as and for the purpose described.
In witness whereof I hereunto subscribe my name this 22d day of June, 1903.
HENRY C. MITCHELL.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US16275803A US754672A (en) | 1903-06-23 | 1903-06-23 | Rotary steam-engine. |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US16275803A US754672A (en) | 1903-06-23 | 1903-06-23 | Rotary steam-engine. |
Publications (1)
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US754672A true US754672A (en) | 1904-03-15 |
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US16275803A Expired - Lifetime US754672A (en) | 1903-06-23 | 1903-06-23 | Rotary steam-engine. |
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1903
- 1903-06-23 US US16275803A patent/US754672A/en not_active Expired - Lifetime
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