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US664509A - Rotary engine. - Google Patents

Rotary engine. Download PDF

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Publication number
US664509A
US664509A US1597899A US1899015978A US664509A US 664509 A US664509 A US 664509A US 1597899 A US1597899 A US 1597899A US 1899015978 A US1899015978 A US 1899015978A US 664509 A US664509 A US 664509A
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Prior art keywords
valve
steam
cylinder
hub
engine
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US1597899A
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Frederick G Tees
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JOHN H SORDEN
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JOHN H SORDEN
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04CROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
    • F04C23/00Combinations 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
    • F04C23/001Combinations 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

  • FREDERICK G. TEES OF PHILADELPHIA, PENNSYLVANIA, ASSIGNOR OF ONE-HALF TO JOHN H. SORDEN, OF SAME PLACE.
  • the object of my invention is to so construct a simple and compact rotary engine which can be readily used either as a single or a compounding engine without materially altering the valve mechanism and by simply duplicating the parts and making sundry connections, as fully described hereinafter.
  • Figure l is a longitudinal sectional view of my improved engine, showing two cylinders coupled to form a compounding engine.
  • Fig. 2 is a front view with the valve-chest in section.
  • Fig. 3 is a section on the line 3 3, Fig. l; and
  • Fig. 4 is a section of the controlling-valve.
  • A is the cylinder of the engine, and within the cylinder is mounted the hub B, in which slide the piston-blades Bfour in the- ⁇ present instance.
  • the interior of the cylinder is shaped as clearly shown in Fig. 3, and two abutments are formed, one diametrically 0pposite the other.
  • the hub is hollow and has two trunnions b, adapted to bearings a a, pro-.
  • each cylinder-head A A studing-box is formed in each bearing, so as to make them steam-tight.
  • the shaft C is mounted within the hub.
  • This shaft is adapted to independent bearings c c, as clearly shown in Fig. 1, and the shaft is somewhat less in diameter than the hub, so that the hub does not touch the shaft, as it is free to rotate without touching the hub.
  • Splined on the shaft is an arm 0, the end of which is adapted to a socket b in the hub, so that while the shaft does not touch the trunnions of the hub it is driven by the hub through the arm 0.
  • In each cap are grooves a, to which are adapted pins (1 of bars D, which are guided in slots Win the hubB and which force out the blades B.
  • E E are the upper and. lower abutments, respectively, having springs e e back of them and having swiveled blocks 6', similar to the blocks bot the pistons, so that the abutments will snugly fit the huh.
  • I is a valve-chamber communicating with one portion of the interior of the cylinder through short inlet-passagesit" and with long outlet-passages i i communicating with the opposite end of the cylinder, as clearly shown in Fig. 3.
  • the valve-chamber I is preferably tapered, and adapted to this chamber is a controllingvalve 1'.
  • This valve has a partition t, which divides it into two sections.
  • One chamber, j, of the valve is the inlet-chamber, and the other chamber, j, is the exhaust-chamber.
  • the valve is so formed that by turning it in one direction one of the passages, t', is opened to the inlet for live steam and the other passage, i', is closed, while the passage '5 leading from the opposite end to the cylinder, is open to the exhaust and the other passages closed.
  • the valve is turned in the opposite direction,the other passages are opened and the passages 'i 7? closed.
  • the valve is controlled by a hand-lever 1 K is the steam-chest for the live steam.
  • a steam-pipe k communicates with the chest,
  • the valve covers the ports 17,. n, which communicate with the live-steam passage N, which in turn communicates with the valve-chamber I, containing the controla rod Z to an eccentric-strap Z adapted to an eccentric L on the shaft 0, so that as the shaft 0 is turned the valve L will reciprocate, first opening one port at and then the other, allowing the steam to pass into the passage N through the chest I and into the cylinder by the ports as dictated by the controlling-valve I.
  • I am enabled to make a very simple, compact, and easily-running engine which will be economical in the use of and in the chest is a slide-valve L, having a ling-valve I.
  • the slide-valve L is connected by through the pipe is into the chest K, through steam and'which can be readily constructed and mounted in any suitable manner.
  • my invention as a single high-pressure rotary engine. It will be understood that while I have shown it mounted upon a base M it may be arranged on its side and mounted on a long base, the base supporting the valve-chest as Well as the cylinder; but the position of the engine is immaterial.
  • Fig. 1 I have shown the engine coupled as compounding, providing a duplicate en gine A similar in all respects to the engine just described, with the exception that the cylinder and its passages, as well as the hub pressu-re cylinder, but is also connected tothe reversing-valve of the low-pressure cylinder, so that the one lever will shiftboth valves.
  • a by-pass is formed by a pipe 3 from the live-steam pipe 7a to the exhaust-pipe P, and this by-pass has a suitable valve 3, by which it can be closed, so that in starting the engine the valve can be opened and both engines will take steam at high pressure.
  • this port Z communicates first with the port 'n,then closes, and then communicates with the port n, then closes, and as the valve returns it communicateswith theport' n again,.then closes, and then communicates with the port n and closes, so that thererare four distinct passages of steam to thecylinder during one revolution of the shaft.
  • the valve mechanism can be so set balance of the stroke.
  • the valves will have the proper lap and the proper cut off.
  • the engine does not take steam until the blade is on the line 00.
  • the valve L opens up the upper port '11 and takessteam, the valve being full-open when the blade reaches the point on the line 00', and steam is gradually out off and the valve is closed when the blade'reaches the line m
  • the steam is allowed to expand during the When the blade reaches the point m gthe valve L commences to uncover the port 01, the second blade being on the line m, and the engine will take steam again until the point or is reached by the second blade, when the valve will close the port 91., and during the remainder of the stroke of the valve and the.
  • a third blade is moving into position, so that when the valve on its return opens the lower port n the engine will take steam'back of the third blade, and when this third bladereaches the point x the valve will close theport n, and during the time the-valve'ispassi-ng from the port n to the port at the fourth blade will be moved. t-o the position 00. Steam will then be admitted back of this blade at this point, and when the blade reaches the point 00 the valve will cut olf the steamfrom the port at and will complete its upward movement, so that by this mechanism a very simple valve motion is obtained and the valve can be set to cut off at any point to-give more or less ex pansion and to operate the engine economically.
  • the controlling-valve not only acts in its capacity as areversingvalve, but also controls the flow of steam. to the cylinders. If the valve: is shiftedwide open, so that it will give a clear passage to the ports, then the engine will run at full speed. If the valve is turned so as to partly open the inlet-port, then the steam is'cut down and the: engine is turned slowly, andby simply turn-' ing the valve to the position shown inv the drawings the ports will be closed and theengine will stop.
  • the passage -t may connect with the exhaust-passage or may exhaust into the open air.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Output Control And Ontrol Of Special Type Engine (AREA)

Description

Patented Dec; 25, I900.
' F. G. TEES.
ROTARY ENGINE.
(Application flledlept. 18, 1899. Renewed May 8, X900.)
2 Sheets-Sheet (No Model.)
m: Norms PEYIRS co wHoToufNo" WASHINGTON. u c
No. 664,509. Patented Dec. 25, I900;
F. Ga TEES. 4 ROTARY ENGINE.
A lication filed Sept. 13, 1899. Renewed May s, 1900.
(No Model.)
2 shaats shpat 2.
ZIW
UNITED STATES PATENT OFFICE.
FREDERICK G. TEES, OF PHILADELPHIA, PENNSYLVANIA, ASSIGNOR OF ONE-HALF TO JOHN H. SORDEN, OF SAME PLACE.
ROTARY ENGINE.
SPECIFICATION forming part of Letters Patent No. 664,509, dated December 25, 1900. Application filed $eptember 13, 1899. Renewed May 8, 1900. SerialNo.15,978. (No model.)
To all whmn it may concern:
Be it known that I, FREDERICK G. TEES, a
citizen of the United States, residingin Philadelphia, Pennsylvania, have invented certain Improvements in Rotary Engines, of which the following is a specification. The object of my invention is to so construct a simple and compact rotary engine which can be readily used either as a single or a compounding engine without materially altering the valve mechanism and by simply duplicating the parts and making sundry connections, as fully described hereinafter.
In the accompanying drawings, Figure l is a longitudinal sectional view of my improved engine, showing two cylinders coupled to form a compounding engine. Fig. 2 is a front view with the valve-chest in section. Fig. 3 is a section on the line 3 3, Fig. l; and Fig. 4 is a section of the controlling-valve.
In setting forth my invention I will describe the high-pressure engine in detail as follows, it being understood that the engine may be used as a single high-pressure engine or coupled to another and used as a compounding engine, as shown in the drawings.
A is the cylinder of the engine, and within the cylinder is mounted the hub B, in which slide the piston-blades Bfour in the-\present instance. The interior of the cylinder is shaped as clearly shown in Fig. 3, and two abutments are formed, one diametrically 0pposite the other. The hub is hollow and has two trunnions b, adapted to bearings a a, pro-.
jecting from each cylinder-head A. A studing-box is formed in each bearing, so as to make them steam-tight. Mounted within the hub is the shaft C. This shaft is adapted to independent bearings c c, as clearly shown in Fig. 1, and the shaft is somewhat less in diameter than the hub, so that the hub does not touch the shaft, as it is free to rotate without touching the hub. Splined on the shaft is an arm 0, the end of which is adapted to a socket b in the hub, so that while the shaft does not touch the trunnions of the hub it is driven by the hub through the arm 0. In each cap are grooves a, to which are adapted pins (1 of bars D, which are guided in slots Win the hubB and which force out the blades B. Springs b are mounted between these bars D and the blades B. Thus there is a yielding pressure of the blades against the inner walls of the cylinder. At the extreme end of each blade is a swiveled block b, which conforms to the shape of the cylinder and makes a tight joint at all times.
E E are the upper and. lower abutments, respectively, having springs e e back of them and having swiveled blocks 6', similar to the blocks bot the pistons, so that the abutments will snugly fit the huh.
I is a valve-chamber communicating with one portion of the interior of the cylinder through short inlet-passagesit" and with long outlet-passages i i communicating with the opposite end of the cylinder, as clearly shown in Fig. 3.
The valve-chamber I is preferably tapered, and adapted to this chamber is a controllingvalve 1'. This valve has a partition t, which divides it into two sections. One chamber, j, of the valve is the inlet-chamber, and the other chamber, j, is the exhaust-chamber. The valve is so formed that by turning it in one direction one of the passages, t', is opened to the inlet for live steam and the other passage, i', is closed, while the passage '5 leading from the opposite end to the cylinder, is open to the exhaust and the other passages closed. When the valve is turned in the opposite direction,the other passages are opened and the passages 'i 7? closed. The valve is controlled by a hand-lever 1 K is the steam-chest for the live steam. A steam-pipe k communicates with the chest,
single passage 1. The valve covers the ports 17,. n, which communicate with the live-steam passage N, which in turn communicates with the valve-chamber I, containing the controla rod Z to an eccentric-strap Z adapted to an eccentric L on the shaft 0, so that as the shaft 0 is turned the valve L will reciprocate, first opening one port at and then the other, allowing the steam to pass into the passage N through the chest I and into the cylinder by the ports as dictated by the controlling-valve I. By this means I am enabled to make a very simple, compact, and easily-running engine which will be economical in the use of and in the chest is a slide-valve L, having a ling-valve I. The slide-valve L is connected by through the pipe is into the chest K, through steam and'which can be readily constructed and mounted in any suitable manner.
I have described my invention as a single high-pressure rotary engine. It will be understood that while I have shown it mounted upon a base M it may be arranged on its side and mounted on a long base, the base supporting the valve-chest as Well as the cylinder; but the position of the engine is immaterial.
In Fig. 1 I have shown the engine coupled as compounding, providing a duplicate en gine A similar in all respects to the engine just described, with the exception that the cylinder and its passages, as well as the hub pressu-re cylinder, but is also connected tothe reversing-valve of the low-pressure cylinder, so that the one lever will shiftboth valves.
A by-pass is formed by a pipe 3 from the live-steam pipe 7a to the exhaust-pipe P, and this by-pass has a suitable valve 3, by which it can be closed, so that in starting the engine the valve can be opened and both engines will take steam at high pressure.
The operation of the compound engine is readily understood. Steam isadmitted itinto the passage N, and directed by the controllingvalve I into the proper ports. To drive the engine in one direction, steam will act upon the blades and turn the hub, and the hub being connected to the shaft through the arm 0 will turn the shaft. The steam asit is exhausted from the high-pressure cylinder will pass through the pipe P to the steam-chest of the low-pressure cylinder,
. audit will pass through the low-pressure-controlling valve into the low-pressure cylinder and will turn the hubin the manner described above and willv exhaust through the pipe P. The eccentrics controlling the valve are operated so that the valves will open the ports at-the proper time.
It will be noticed that there are four blades.
onthe hub and one inlet-passage, so that there must be four admissionsofsteam on each revolution. There are two ports mat in the steamchest,v and the valve L has a single passage Z.
On. the downward stroke this port Z communicates first with the port 'n,then closes, and then communicates with the port n, then closes, and as the valve returns it communicateswith theport' n again,.then closes, and then communicates with the port n and closes, so that thererare four distinct passages of steam to thecylinder during one revolution of the shaft. The valve mechanism can be so set balance of the stroke.
that the valves will have the proper lap and the proper cut off.. As shown in the'drawings, there is a certain amount of lap-for instance, in referring to Fig. 3 the engine does not take steam until the blade is on the line 00. Then the valve L opens up the upper port '11 and takessteam, the valve being full-open when the blade reaches the point on the line 00', and steam is gradually out off and the valve is closed when the blade'reaches the line m The steam is allowed to expand during the When the blade reaches the point m gthe valve L commences to uncover the port 01, the second blade being on the line m, and the engine will take steam again until the point or is reached by the second blade, when the valve will close the port 91., and during the remainder of the stroke of the valve and the. return stroke a third blade is moving into position, so that when the valve on its return opens the lower port n the engine will take steam'back of the third blade, and when this third bladereaches the point x the valve will close theport n, and during the time the-valve'ispassi-ng from the port n to the port at the fourth blade will be moved. t-o the position 00. Steam will then be admitted back of this blade at this point, and when the blade reaches the point 00 the valve will cut olf the steamfrom the port at and will complete its upward movement, so that by this mechanism a very simple valve motion is obtained and the valve can be set to cut off at any point to-give more or less ex pansion and to operate the engine economically.
It will be seen that the controlling-valve not only acts in its capacity as areversingvalve, but also controls the flow of steam. to the cylinders. If the valve: is shiftedwide open, so that it will give a clear passage to the ports, then the engine will run at full speed. If the valve is turned so as to partly open the inlet-port, then the steam is'cut down and the: engine is turned slowly, andby simply turn-' ing the valve to the position shown inv the drawings the ports will be closed and theengine will stop.
In order to prevent back pressureand trapping of the steam when the engine-is quickly reversed, I form a small outlet-passage t between the two i-nlet-ports vl i and recess; the valve, as shown, so that when the. valve is shifted the steam entrapped within the cylinder can freely escape through the small outlet-passage. The passage -t may connect with the exhaust-passage or may exhaust into the open air.
I claim as my invention- 1. The combination of a cylinder of a rotary engine, ahub adapted to the cylinder having four blades, a steam-inlet passage.
com municating with the interior. of the cylinder, two portscommunicatingwiththe steamwill be four independentpassages of: steam to the cylinder during one revolution of the hub, substantially as described.
2. The combination of a cylinder of a rotary engine, a hub adapted to the cylinder having fourblades, a steam-inlet passage communicating with the interior of the cylinder, two ports communicating with the steam-inlet passage, a slide-valve having a single passage, means for reciprocating said slid e-valve so that there will be' four independent passages of steam to the cylinder during one revolution of the hub, substantially as described.
3. The combination in a rotary engine, of a cylinder, a hub mounted therein having four blades, asingle steam-inlet port, a valve-chest having two ports n n communicating with the single steam-port, a slide-valve having a single passage and adapted to uncover the ports four times during the revolution of the hub, a controlling-valve in the steam-passage between the slide-valve chest and thecylinder, so as to control the admission of steam to the cylinder, substantially as described.
4. The combination in a compound rotary engine, of the two cylinders, one larger in diameter than the other, a hub in each cylinder, blades on the hub, a valve-chest, slidevalves in'each chest, eccentrics on the shaft controlling the movement of the slide-valves, a pipe leading from the exhaust-passage of the high-pressure cylinder to the inlet-passage of the low-pressure cylinder, the shaft on which the hub is mounted being adapted to independent bearings, substantially as described.
5. The combination in a rotary engine, of a cylinder, a hub mounted in ,the cylinder, bearings for said hub, blades carried by the hub, a shaft free of the hub, independent bearings for said shaft, an arm on the shaft engaging said hub, ports in the cylinder, and valve mechanism controlling the admission and exhaust of steam to and from the cylinder, substantially as described.
6. The combination in a cylinder having heads, cam grooves in said heads, a hub adapted to bearings in the heads, radial slots in the hub, blades in these heads, bars back of the blades and having pins extending into the camways, ports in the casing, valves controlling the admission of steam to the cylinder, a shaft adapted to independent bearings and connected to the hub, substantially as described.
7. The combination in a rotary engine, of a casing, a hub, blades on the hub adapted to travel Within the casing, a valve-chamber having a steam-inlet to the valve-chamber, a slide-valve having a single port, two ports in the valve-casing covered by the said valve, and means for reciprocating said slide-Valve, substantially as described.
8. The combination in a rotary engine, of the cylinder, a hub within the cylinder having'blades, passages leading to the cylinder, a valve-chest, ports at n in said valve-chest communicating with the passage N, a controlling valve chest I, a controllingvalve therein, a slide-valve having a single passage and adapted to cover the ports n 41, means for reciprocating said valve, a steam-inlet passage communicating with the valve-chest, substantially as described.
In testimony whereof I have signed my name to this specification in the presence of two subscribing Witnesses.
FREDERICK G. TEES.
Witnesses:
WILL. A. BARR, J os. H. KLEIN.
US1597899A 1899-09-13 1899-09-13 Rotary engine. Expired - Lifetime US664509A (en)

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