US940648A

US940648A - Steam-condenser.

Info

Publication number: US940648A
Application number: US45087408A
Authority: US
Inventors: Royal D Tomlinson
Original assignee: Allis Chalmers Corp
Current assignee: Allis Chalmers Corp
Priority date: 1908-08-29
Filing date: 1908-08-29
Publication date: 1909-11-16
Anticipated expiration: 1926-11-16

Description

R. D. TOMLINSON.

STEAM CONDENSER.

APPLIUATION FILED new, 1908.

940,648. Patented Nov. 16, 1909.

2 SHE ETSSHEET 1.

WITNESSES; INVENTDR- ATTUFNIEK R. D. TOMLINSON.

STEAM CONDENSER.

APPLICATION FILED AUG.29, 190s.

Patented Nov. '16, 1909.

2 SHBETS SHEET 2.

W W VENTUR WI TNEE'EES' ATTURNE Y.

"UNITED sTAa ps rare T OFFICE.

ROYAL D. TOMLINSON, 0F MILWAUKEE, WISCONSIN, ASSIGNOR TO ALLIS-CHALMERS COMPANY, OF MILWAUKEE, WISCONSIN, A CORPORATION OF N E! JERSEY.

STEAM-CONDENSER.

To all whom it may concern: v

Be it known that I, ROYAL D. TOMLINSON, a citizen .of the United States, residing at Milwaukee, in the countyof Milwaukee and State of WVisconsin, have invented a certain new and useful Improvement in Steam-Condensers, of which the following is a specification.

This invention relates to steam condensers and has for its object to produce a more ellicient condensing system.

The improvement applies to that class in which'a special passage is used to abstract air and prevent it from accumulating in the upper portion of the condenser, thus contributing to the completeness of the vacuum. by means of the arrangement herein shown and described, this air is ell'ectively removed while at the same time a means is provided for automatically breaking the vacuum in case part of the apparatus should fail to operate. A secondary pump used for the removal of the air is so arranged that it greatly increases the efliciency of the system, since its suction takes its supply from the primary pump discharge and therefore all of thewater need not be raised to the higher pressure of the secondary pump discharge.

Referring to the accompanying drawings,-Figure 1 is a vertical section of. a barometric condenser system. Fig. 2 is an elevation partly in section of a surface eondenser system. I

Referring to Fig. 1, the steam admission pipe 2 leads into the top of the condenser 1. The water .inlet pipe 3 leads into the condenser 1 and terminates in an umbrella 31. The condenser discharge 4 passes to the suction of pump 7. An air discharge pipe 5 has its inlet well up under the umbrella 31 within the condenser 1, passes through the wall of the condenser and terminates annu larly about a nozzle 11 in the discharge pipe of the secondary pump 10. The annular space about the nozzle 11 in which the air pipe terminates, communicates beyond nozzle 11 through the openings 12 with the discharge pipe from the secondary pump 10. The secondary pump 10 has its suction connected with discharge pipe of he primary pump 7, there being a check valve in the discharge pipe between this connectlon and the primary pump 7. The discharge pipe from the secondary pump 10 leads to the nozzle 11 from which a discharge pipe Specification of Letters Patent.

Application filed Augnst'29,'1908. Serial No. 450,874.

Patented Nov. 16, 1909..

passes and terminates in the upper part of the reservoir 9. The discharge pi e fromthe primary pump 7 terminates in t e lower. part of reservoir 9. These discharge pi es are separated by a partition wall 6. he

primary and secondary pumps are preferably of the centrifugal type.

Referring to Fig. 2, the condenser 1 is of the surface type having steam inlet 2 at the top. The discharge p1pe'5 leads oil from the bottom of condenser 1 and serves to carry off both air and water of condensation. A check valve 51 is located in this pipe 5. The water inlet pi e 3 leads into one end of the condenser an communicates with the chamber from which the tubes 13 lead.

The discharge ipe 4 leads from the opposite end of the con enser and from the chamber to which the tubes lead. The disohar e pipe 4 passes directly to the lower part 0 reservoir 9. The inlet pipe 3 is the discharge pipe of primary pump 7 whose suction leads from any convenient source. The dischar e pipe 5 terminates annularly about a nozz e 11 in the disehargepipe of the secondary pump 10. The annular space about the nozzle in which the air and water discharge pipe 5 terminates, communicates beyond the nozzle 11 through openings 12 with the discharge pipe from the secondary pump 10. The secondary pump 10 has its suction connected with the discharge pipe 4; which in fact is the discharge from primary pump 7. Discharge pipe 4 has a check valve 80 below the connection to the suction of pump 10. The discharge pipe from the secondary pump 10 leads to the nozzle 11 from which a discharge pipe passes and terminates in the upper part of reservoir 9.

The pumps in both modifications may be on the same shaft and even in the same caslho operai ion of the barometric system is as follows: The steam entering the inlet pipe 2 is condensed by the water entering the inlet pipe 3, and the we '-r of condensation and the condensing water are-together discharged by the primary pump 7. All of this water asses the check valve 8 in the discharge pipe of the pump 7. The greater portion of the water discharged from the pump 7 passes directly to the reservoir 9. A small portion of the vater discharged by pump 7 passes to the secondary pump 10 and is discharged thereby at a higher presemcee sure through the nozzle 11 to the reservoir 9. Air is removed from the condenser 1, through pipe 5 by being entrained through the opening 12 in nozzle 11, with the water flowing at a high velocity from this nozzle. In case pump 7 fails to operate, the water will accumulate in the condenser 1 until it is removed through pipe 5 by pump 10. To provide for this emergency the capacity 01 pipe 5 and pump 10 must be made sullieientto carry all the water. in this case check valve 8 prevents water from the reservoir 0 backing up into thecondenser by atmospheric pressure. During this operation the air and Water are removed in the same manner as air alone in the ordinary operatioi'i; but the pump 10 takes its supply directly from reservoir 9 instead of from the discharge of pump 7. The wall 6 in this case serves to prevent air from being drawn up through the discharge pipe from pump 7. In case both pumps fail to operate, the vacuum in the condenser 1 will immediately be broken by atmospheric air from reservoir 9 entering through the discharge pipe from the pump 10, through openings 12 in nozzle 11, annular space around nozzle 11 and-pipe 5. with condensingwater.

The operation of the surface condenser system of Fig. 2 is similar. The steam onters inlet 2 and condenses on the tubes 13. The water of condensation and the air pass out through pipe 5 and are entrained from the annular termination of pipe 5, around nozzle 11, through openings 12 and are discharged trom the nozzle into "eservoir t). The condensing water pumped by pump 7 through the inlet pipe 3, tubes 13, and the greater part is discharged through pipe 1- to the reservoir 9. Some of this 'aier is taken from pipe 1 by the suction of pump 10 and discharged at a higher pressure through nozzle 11 in the discharge pipe oi pump 10. It is at this point that the high velocity of the discharge throu h the nozzle 11 causes the air and water of condensation to be entrained from pipe 5 as above pointed out. In case pump vtails to operate, the pump 10 will take its supply from reservoir S) through pipe a until check valve 80 is closed by such inlet flow. After this the supply This will prevent flooding of the enginev for pump 10 will come through pump 7, inlet pipe 3, tubes 13 and outlet pipe 4, and the system Will still be in Working condition though less efiicient. In case pump 10 fails to operate, the vacuum in the condenser will not be broken because of the check valve 51 in pipe 5.

It should be understood that it is not desired to be limited to the exact details of construction shown and described, for 0bvious modifications will occur to a person skilled in the art.

It is desired to secure by Letters Patent,

1. The combination in a condenser system, of a coudenser,'a pump for discharging Water therefrom, and a pump and connections for discharging air therefrom, said latter pump having its suction directly connected to the discharge of said former pump.

2. The combination in a condenser system, of a condenser a pump for discharging Water therefrom, a pump for discharging air therefrom, an air pipe connecting from a water-tree portion of said condenser to said aii discharging pump, and a connection from the discharge of said waterdiscl'iarging pump to the suction of said air-disclulrging pump.

3. The combination in a condenser system, of a condenser, a pump for discharging water therefrom, a pump for discharging air therefrom, said latter pump having its suction directly connected to the discharge of said former pump, and an air pipe connecting from a water-free portion of said con denser to said air-discharging pump.

4. The combination in a condenser system, of a t'UlHlOllfiQl', a pump for discharging water therefrom, a pump for discharging air therefrom, a lower connection. between said condenser and said former pump, a separate upper connection between said condenser and said latter pump, and a connection from the discharge of said former pump to the suction of said latter pump.

in testimony whereof, I aflix my signature in the presence of tWo witnesses.

It. D. TOMLINSON.

Witnesses G. 1 Du W'Em, ELLA BRICKELL.