RU2239704C1 - Steam power plant with piston steam machine - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: proposed steam power plant with piston steam machine has steam boiler 1, piston steam machine 2, condenser 3 and feed water pump 4 hydraulically connected in series by pipelines. Piston steam machine 2 is made with water jacket 5 around its cylinder 6 connected by bridges 7. Inlet 9 of water jacket is located in end 10 of cylinder 6, being hydraulically connected with outlet of feed water pump 4, and outlet 11 is located at beginning of cylinder 6 from side of working chamber 12, being hydraulically connected with inlet of steam boiler 1. Steam inlet and outlet of piston steam machine 2 are located on cylinder 6 at its beginning and end, respectively. Cylinder 6 can be made with ratio of length of piston stroke to cylinder bore from 5 to 20, to provide optimum conditions of operation. Bridges 7 can be to spiral with increasing pitch from inlet 9 of water jacket 5 to outlet 11 to provide constant high velocity of feed water flow and guarantee minimum hydraulic losses and required amount of heat for warming feed water. Saturated steam from boiler 1 is fed to working chamber 12 where it starts expanding executing mechanical work when piston 8 moves. Simultaneously feed water pump 4 supplies feed water under pressure from condenser 3 through inlet 9 into water jacket 5. Feed water is heated with saturated steam, when passing through water jacket 5, to maximum possible temperature of steam in steam boiler 1. Steam is discharged into condenser 3 at end of working stroke of piston 8, and cycle repeats itself. Invention provides increasing of thermal efficiency owing to maximum heating of water getting into steam boiler by removing heat of saturated steam expanding in piston steam machine and partially condensing inside cylinder.

EFFECT: increased thermal efficiency.

2 cl, 1 dwg

Description

The invention relates to the field of engineering, in particular to steam power plants with a reciprocating steam engine.

Known steam power installation, containing interconnected hydraulically in series steam boiler, reciprocating steam engine, condenser and feed water pump. The feed water pump is hydraulically connected to the steam boiler (V.A. Kuzovlev. Technical thermodynamics and heat transfer basics. / Under the editorship of L.R. Stotsky. - M.: Higher School, 1975, p. 189-190).

Known steam power installation, containing interconnected hydraulically in series steam boiler, reciprocating steam engine, condenser and feed water pump. The feed water pump is hydraulically connected to the steam boiler (V.P. Blyudov et al. General heating technology. / Under the editorship of S.Ya. Kornitsky and Ya.M. Rubinshtein, 2nd ed. M.-L .: Gosenergoizdat, 1952, p. 81-82).

The disadvantage of both known steam-powered plants is the insufficiently high thermal efficiency due to insufficient heating of the feed water entering the steam boiler.

The problem solved in the invention is the creation of a steam power plant with a reciprocating steam engine, which provides a high thermal efficiency due to the maximum heating of the feed water entering the steam boiler, by taking heat from saturated steam, expanding in the reciprocating steam engine and partially condensing inside the cylinder.

The task of creating a steam power plant with a reciprocating steam engine is solved by the fact that the steam power plant with a reciprocating steam engine contains a steam boiler, a reciprocating steam engine, a condenser and a feed water pump connected hydraulically in series, according to the invention, the reciprocating steam engine is made with a water jacket around its cylinder, fastened with jumpers, the inlet of the jacket is located at the end of the cylinder and is hydraulically connected to the outlet of the pump, and the outlet is located at the beginning of the cylinder the working chamber and is hydraulically connected to the inlet of the steam boiler, jumpers fastening the water jacket and cylinder are made in a spiral with an increasing step from the inlet of the jacket to the exit from it, the inlet and outlet of the steam of the reciprocating steam engine are located on the cylinder, respectively, at its beginning and end .

The implementation of a piston steam engine with a water jacket around its cylinder, jumpers fastened to each other, the location of the inlet of the jacket at the end of the cylinder and its hydraulic connection to the pump outlet, the location of the outlet at the beginning of the cylinder from the side of the working chamber and the hydraulic connection to the input of the steam boiler, location of the inlet and steam output of the reciprocating steam engine on the cylinder, respectively, at its beginning and end provide heating in the water jacket of the feed water entering the steam boiler inlet to the maximum possible temperature by continuous withdrawal of heat from the steam cycle and accomplishing work expanding a piston steam engine.

The feed water in the water jacket is heated to the maximum possible temperature only when moving through the water jacket against the movement of expanding steam in the working chamber of the cylinder of the reciprocating steam engine.

The bonding of the water jacket and cylinder to each other allows heating feed water passing through the water jacket to the maximum possible temperature when the cylinder wall is thin without being crushed by flowing water under high pressure.

The execution of jumpers holding the water jacket and cylinder in a spiral with an increasing step from the inlet of the jacket to the outlet of it ensures a high speed of the feedwater flowing through the jacket, which makes it possible to obtain the required amount of heat for heating it, and also allows to obtain a constant flow rate of the feed water, reducing its density along the length of the shirt when heating the water, leading to minimal hydraulic losses.

The implementation of the cylinder of a reciprocating steam engine with a ratio of the piston stroke length to the inner diameter in the range from 5 to 20 allows you to create the most optimal conditions for steam condensation and heating of the feed water supplied to the input of the steam boiler at various machine powers.

The drawing shows a schematic diagram of a steam power plant with a reciprocating steam engine.

A steam-powered installation with a reciprocating steam engine comprises a steam boiler 1, a reciprocating steam engine 2, a condenser 3 and a feed water pump 4 connected hydraulically in series through pipelines. The piston steam engine 2 is made with a water jacket 5 around its cylinder 6, fastened with jumpers 7. The piston 8 is movable in the cylinder 6. The inlet 9 of the water jacket 5 is made in the form of a fitting and is located at the end 10 of the cylinder 6 and is hydraulically connected by a pipeline to the outlet of the feed water pump 4, and the outlet 11 of the water jacket 5 is made in the form of a fitting and is located at the beginning of the cylinder 6 from the side of its working chamber 12 and hydraulically connected by a pipeline to the inlet of the steam boiler 1. The entrance to the reciprocating steam engine 2, made in the form of a steam supply manifold 13 with a supply valve 14, and the outlet from the reciprocating steam engine 2, made in the form of a steam outlet collector 15 with exhaust windows 16, located enes on the cylinder 6, respectively at the beginning and end 10. End 10 of cylinder 6 is closed with a seal 18 through which the rod 19 of the piston 8 and the fitting 17 is connected hydraulically with the inlet conduit of the condenser 3.

The cylinder 6 of the piston steam engine 2 can be made with the ratio of the piston stroke length S to the inner diameter d in the range from 5 to 20.

The length S of the piston stroke is equal to the length of the cylinder 6 without taking into account the harmful space.

The choice of the range of ratios of the length S of the piston stroke in the cylinder 6 to its internal diameter d from 5 to 20 was carried out from the condition of providing condensation of steam on the inner walls of the cylinder at minimum temperature differences between the steam and the walls of the cylinder, washed from the outside with feed water, for various capacities of the reciprocating steam engine from 15 to 60 kW, that is, the cylinder must have a smaller internal diameter and a longer length than a conventional reciprocating steam engine.

The jumpers 7 fastening the water jacket 5 and the cylinder 6 can be made in a spiral with an increasing step from the inlet 9 of the water jacket 5 to the outlet 11 of the water jacket 5, and the step of the spiral is inversely proportional to the density of the water heated in the water jacket 5.

Steam power installation works as follows.

Saturated steam from the steam boiler 1 is fed through a pipeline through the supply manifold 13 with the supply valve 14 open to the working chamber 12 of the piston steam engine 2 with the piston 8 in the extreme dead center position, with a minimum amount of harmful space of the cylinder 6. When the piston 8 is filled, the working the chamber 12 with a predetermined amount of saturated steam, after which the supply valve 14 is closed. Saturated steam begins to expand, performing mechanical work with the further movement of the piston 8. At the same time, the feed water pump 4 supplies pressurized water from the condenser 3 through the inlet 9 to the water jacket 5 and the feed water exits through the outlet 11 of the water jacket 5. The feed water is heated, passing through the water jacket 5 towards the expanding steam, to the maximum possible temperature and is fed to the inlet of the steam boiler 1. At the same time, saturated steam expanding in the reciprocating steam engine 2 partially condenses inside cylinder 6 on its walls. At the end of the stroke of the piston 8, when the exhaust release windows 16 are opened, steam is discharged through the exhaust manifold 15 to the condenser 3 together with condensed water condensed on the walls of the cylinder 6, while the piston 8 displaces the dead volume of steam between the windows 16 and the cover 18 through the fitting 17 into the condenser 3 , the pressure in which is lower than at the end of the stroke in the cylinder 6 at bottom dead center. When the piston 8 moves back to the top dead center, it closes the exhaust windows 16 with its body and compresses the remaining low pressure steam after the exhaust to the volume of harmful space, after which the cycle repeats.

When the feed water flows through the water jacket 5 in the space between the jumpers 7, made in a spiral with an increasing step from the inlet 9 of the water jacket 5 to the outlet 11 from the water jacket 5, a constant high flow rate of the feed water is ensured with maximum heat transfer and minimal water loss, which allows heat the feed water to the maximum possible temperature before it is fed to the steam boiler 1 and obtain the maximum thermal efficiency of the steam power plant. For example, when using saturated steam with heating feed water in a water jacket 5 to its boiling point under pressure, that is, in an ideal process without a temperature difference between the steam in the cylinder 6 and the water in the water jacket 5, only heat will be expended in the steam boiler 1 r the evaporation of water at a temperature T _p and the entropy of steam S _p and water S _in

q = (S _p -S _c ) T _p = r,

and the polytropic expansion of the condensing vapor in the cylinder 6 will provide useful work of steam at a temperature of the condenser T _to

I _p = (S _p -S _c ) (T _p -T _k ).

The thermal efficiency of the steam cycle will be η = I _p / q = (S _n -S _a) / r (T _n -T _k).

So at T _p = 583K and a pressure of 100.64 kg / cm ² - T _k = 323K; r = 316.5 kcal / kg; S _p = 1.3431 kcal / kg S _in = 0.8003 kcal / kg

Thermal efficiency η = (1.3431-0.8003) / 316.5 (583-323) = 0.445, that is, a value not achievable in conventional steam-powered plants without heating the feed water in the cylinder water jacket from expanding steam condensing inside it.

If there is a limited temperature difference between steam and water in the water jacket of the cylinder, the heating of the water in the water jacket and thermal efficiency will decrease somewhat.

When the water in the water jacket is heated not to 583K, but to 573K, i.e. 10K less, the heat content of water at the inlet to the steam boiler will drop from 334.9 kcal / kg to 321.2 kcal / kg and the thermal efficiency will drop to

η = 0.445 (r + 321.2) / (r + 334.9) = 0.445 · 0.979 = 0.435,

that is, insignificantly.

To calculate the parameters of a reciprocating steam engine with steam condensation inside the cylinder, a theory was developed according to which it was determined that at constant shaft speeds and average effective pressure, the cylinder diameter depends on the temperature difference Δt to the degree of 0.6: d = C ₁ Δt ^{0 , 6} , and the ratio of the piston stroke length to its diameter is proportional to the power S / d = C ₂ N / d ³ .

For example, at Δt = 10 ° the shaft speed is 150 rpm and the average effective steam pressure is 8 kg / cm ² , d = 90 mm, and S / d at N = 15 hp and 60 hp respectively equal to 5 and 20, which is much higher than conventional steam engines, where S / d is not more than 2.

Claims (2)

1. A steam-powered installation with a reciprocating steam engine, comprising a steam boiler connected hydraulically in series, a reciprocating steam engine, a condenser and a feed water pump, characterized in that the reciprocating steam engine is made with a water jacket around its cylinder, bridges connected to each other, an input the jacket is located at the end of the cylinder and is hydraulically connected to the outlet of the pump, and the outlet is located at the beginning of the cylinder from the side of the working chamber and is hydraulically connected to the inlet of the steam boiler, jumpers, fastening the water jacket and cylinder, are made in a spiral with an increasing step from the entrance of the jacket to the exit from it, the inlet and outlet of the steam of the reciprocating steam engine are located on the cylinder at its beginning and end, respectively. 2. Steam-powered installation, characterized in that the cylinder of the reciprocating steam engine is made with a ratio of the piston stroke length to the inner diameter in the range from 5 to 20.