DE18568C - Automatic boiler feed pump - Google Patents

Description

IMPERIAL

PATENT OFFICE.

The increasingly general use of steam boilers with a large heating surface and low water content makes it necessary to set up a feed pump which keeps the water level in the boiler at the same height as possible. Thereby it is achieved that the pressure corresponding to the best utilization of the steam remains constant, and that the preheater, in which the water stays for the longest with a regular feed corresponding to the respective steam extraction and thereby assumes the highest temperature achievable, also delivers the greatest possible benefit , whereby a significant saving of coal is achieved. It often happens that the stoker ₍ who is entrusted with observing the water level in the kettle) notices the sinking of it very late put into action and usually so much water pumped into the kettle that the water level exceeds its normal height very high, so that it does not have to be observed every moment The self-acting feed pump, which is used in Below besc is driven, for sure.

The same generally consists of a float device a, FIG. 6, attached to the boiler wall or its vicinity, which is connected through the tubes b to the steam chamber and through the tubes c to the water chamber of the steam boiler or boilers to be fed. The upward and downward movement of the float caused by the rise and fall of the water level in the boiler is used to close or open a regulating valve located below it. When the water level in the boiler drops only slightly, the valve opens and allows water to flow out of the feed reservoir c, FIG. 6, into the pump. The same is put into operation and turns itself off again after the water level in the boiler has risen to its normal level and the regulating valve is closed by the upward movement of the float. This game repeats itself when the water level drops again and therefore also follows the irregularities in the steam extraction.

The float apparatus, Fig. 3, 4 and 9, consists of the housing 1, which by the Steam pipe 2 and the water pipe 3 is brought into connection with the boiler so that the The specified lowest water level is the same as that of the boiler. In the case there is the float 4, a hollow sphere made of sheet copper to which the lever 5 is attached. The same is in that by means of bolts suspended from the upper fork-shaped part of the regulating valve housing 6 and held with the

Tabs 7 serving as a valve rod, provided with screwed-in grooves piston 8,. Fig. 9, and raises or lowers, depending on the rise or fall of the float, the regulating valve 9. When the water level in the boiler falls, the valve 9 opens and drains water from the feeder reservoir through the pipe 10 and 1.1 after the bottom of the Drain the pump. By the rising of the water in that. Under the pump, the latter is activated by the mechanism to be described later, and supplies water to the boiler until the normal water level is reached. is. At this moment the float is raised so high by the constant rise of the water level that it closes the regulating valve 9, whereby the inflow of water from the feed reservoir to the pump is interrupted. As soon as the water level in the base of the pump has reached a certain depth due to the suction of the water, another device sets the pump for so long. ''; in addition to activity, until the water level in the boiler has sunk so much that the float 9: opens the regulating valve again, whereby the. The process described above is repeated anew. In order for such water, which boiler ■■ ';' to prevent ■ 'settles stone blockage of the piston guide ■ V therethrough which Munich ^to: · :.. these protrude over the water.

The pump with automatic on and off ■ '; · "'. rear device, Fig. 1, 2, 5, 7, 8 and 10, consists of the formed into a reservoir • Underframe 15, in which the from the regulating valve of the float 9 - water coming out. On the lower, '. frame 15 are two uprights 16 attached, in which the countershaft 17, Fig. 1, and the ■ Crankshaft 18 are stored. From the pulley 19 the countershaft is operated, which is driven by the gearbox 20 and the spur gear 21 communicates its movement to the crankshaft. The crank pin 23, which in the ■■■ '■ -. "· ■' crank disk 22 is attached, transmits through .the push rod 24 by means of the cross head 2 5, which is in the cylindrical guide 2 6 ■ · ■ '.- ■ -'. · ■ runs, the movement on the piston rod 27 and pistons 28, Figs. 1 and 2. The pump cylinder 29 is on the front extension of the Underframe attached, which is separated from the main reservoir by a partition is. In the same narrow openings 30, Fig. 1, are left for the entry of the water, so gross impurities are retained. The water rises in that of the cylinder and the conversion of vacated space up to the suction valves 32, Fig. 5, and in the pump. The latter is double-acting and has a suction valve 32 and a on each side Pressure valve 33. The valve box covers 34 are simply opened by means of the screws 35, FIG their bearings pushed on. The water passes through the channels 36 into the pressure pipe 37, FIG. 5 and 7, and through this to the boiler. 38, Fig. I, is a safety valve which serves to provide the water with a drain, if the pressure pipe should be blocked by any body.

Mechanisms that initiate pump engagement. As soon as of that Regulirventil, 9 water flows after the pump, reservoir 15, the float rises 39,;.]. Fig. Ι and 8, and lifts the lever 41, Fig. 1 through the rod 40, until the same with his j Bolt 42 abuts against the upper transverse bolt 43 'of the coulisse 44. When walking on. lifts the same from the tooth 45, whereupon the '; Mechanism for engaging the pump in; Can take action. In Fig. 1 the same is | shown at the moment in which the.! ■ Pump shut down ".;

Mechanisms that get the pump engaged. The angle lever 47, y Fig. I, moves, driven by the falling 'weight 48, in the. Direction of the arrow sideways as soon as the tooth of the coulisse 44 has been lifted out. The lower part of the lever 47, which when the pump is at a standstill on the _; Bolt 58, Fig. 10, of the stopper 57 rests, takes it with it and thereby guides the belt onto the fixed pulley, whereby the pump is put into action. The angle lever 47 leans against the thumb disk 50, Fig. 1, which is fixed on the crankshaft, by means of the guide roller 51 and receives an oscillating movement from the same with each revolution of the shaft.

Mechanisms that cause the pump to disengage. The angle lever 53, Fig. I, the horizontal arm of which forms a hook, which is always held up by its counterweight, has the second bolt 59, Fig. 1, of the shelf when engaging ^! caught and held on to it. The weight 55, Fig. I, which sits on the lever 54, tries to push the storage device back onto the empty pane by means of the lever 61, Fig. 1. As soon as the float 39 sinks in the pump reservoir after the supply is complete, the bolt 42 pulls the lower cross bolt 43 of the coulisse 44 downward until the tooth 45 has caught the angle lever 47 again (see FIG. 1). During the next upward piston stroke, the thumb 56, FIG. 1, of the cross head pushes the bolt 52, FIG. 10, of the angle lever to the side and thereby lifts the hook off the bolt 59 of the storage device; the same is now pushed back by the weight 55, which acts on the lever 61, so that the belt opens. the blank disk comes and the pump is turned off

will. FIG. 10 corresponds to this point in time. The four levers 60 and 61 form the guide for the shelf, which is attached to the right or left can be.

The shutdown would take place with every stroke of the pump, if not the one through the The thumb disk set the lever 47 to vibrate the bolt 58 always at the same moment held, in which the thumb of the cross head triggers the angle lever 53 and from the same would be held until the hook of the lever 53 by the action of its counterweight has again caught the bolt 59 of the shelf. During this process, the weight 48 must suspend the weight SS keep. The pump is always disengaged in a position which corresponds to the lever 47 clears the way for engagement. The elevation of the thumb disk 5 ° is located when the pump is at a standstill on the opposite side of the shaft (see Fig. 10).

To prevent the water from overflowing from the pump base, the following arrangement is made: The rod 40 of the float 39 is connected by bolts to the counterweight lever 63, FIG. 8; it counterbalances part of the weight of the float and the rod. On the axis of the lever 63 sits the thumb 64, FIG. 5, which engages in the fork of the angle lever 65 (see FIG. 5). As soon as the reservoir is filled, the thumb 64 presses the fork and closes the valve 66, whereby the flow of water from the feed reservoir to the pump is interrupted. The basic idea of the process described is as follows: The sinking of the water level in the steam boiler causes a free-floating weight to fall, which primarily sets the pump in motion by some engagement device and also raises a lighter weight. After the necessary quantity of water has been supplied to the kettle, with which the normal water level has been reached, the first weight is raised again and underpinned. The second, lighter weight, on the other hand, is released, which in its case takes care of the disengagement of the pump. · Feathers can be used instead of weights.

After attaching a meter to the pump, it can also be used as a water meter used for the water supplied to the boiler and evaporated.

The fluctuations in the height of the water level are only very small by already the pump is activated when it falls very slightly, and when it rises slightly is turned off again. It may therefore be assumed that the in the steam boiler The amount of water is almost the same at all times, especially in view of this; that the pump feeds the water to the boiler in proportion to the steam drawn off.

The use of the pump as a steam meter is based on this property. : There anytime there is the same amount of water in the kettle, i.e. the same amount after an experiment is present, which was also present before the start of the experiment, it is only necessary to determine how much water was added to the boiler during the duration of the experiment. This is also the steam used during the experiment. Is the weight of the same known, then the work can be calculated, which a machine for its operation requires.

The pump can also be used to control the steam engine itself. is The good condition of a steam engine has been established by thorough experiments only to note the steam consumption for the idle. Should be due to a larger consumption of fuel the presumption emerges that the steam engine is no longer in good condition If it is in a state of affairs and causes the greater consumption of fuel, then you only have that Let the steam engine run idle for a while and the steam consumption of the same to control the pump. By comparing the steam or Water consumption to the Time in which the good condition of the machine was established through detailed tests, With the current one it is easy to see whether the steam engine is due to the greater consumption of the fuel is to blame or whether the same by the poor quality of the latter itself is initiated. If the steam engine tried the same amount later Steam or As before, water consumes, so one can be certain that the machine is still using it in good condition and the fuel is of low quality; but needs the steam engine to empty more steam respectively. Water, as in the first attempt, the proof is also given that it is not is more in good condition than when it was first tried. In these attempts therefore exercises the pump control over the water or. Steam consumption from by it the same exactly with the help of the counting apparatus.

Claims (1)

Patent claim: An automatic feed pump, in which when the water level in the boiler drops : is brought into free-floating weight in case, which primarily the pump through activates some engagement device and also puts a light weight into it Height lifts. After the necessary quantity of water has been supplied to the boiler, with which the normal water level has been reached, that will SfJZ /. first weight lifted again and underpinned, on the other hand, the second, lighter one, is freed, which in his case takes care of the disengagement of the pump. Instead of weights, springs can just as easily be used; and on this feeder: a) the floating apparatus 4 shown, which on the one hand by the sinking of the water level the valve 9 opens in the boiler, the feed water from the reservoir to the pump 'runs, on the other hand the valve closes and the inflow of water from the feed , interrupts the reservoir to the pump as soon as the normal water level is reached in the boiler; b) the illustrated mechanisms for using the feed water flowing to the pump on the one hand to engage the pump as the water rises in the pump reservoir by means of the angle lever 47, the weight 48, the sliding roller 51, thumb washer 50, bolt 58 and stop 57, on the other hand to disengage the pump, so- . soon the water supply is interrupted by the rising float, consisting of .. the angle lever 53, the thumb 56 on the cross head, the levers 54 and 60 with the Weight 55 and the shelf 57; c) the devices shown in the drawing for initiating or initiating the engagement of the pump, consisting of the float 39 with the rod 40, the lever 41 and the coulisse 44; d) the device described in more detail above for shutting off the water supply to the pump for the purpose of preventing the same from overflowing, consisting of the weight lever 63 with the thumb 64 * the fork-shaped angle lever 65 and the valve 66. For this purpose 2 sheets of drawings.