DE1503490B2 - AERODYNAMIC PRESSURE SHAFT MACHINE - Google Patents

Description

The invention relates to a method for operating the compressed cold:, and the to be expanded

an aerodynamic pressure wave machine, the hot gas-in, the high-pressure zone 'and essentially

at least one cellular wheel and frontal distributor lower pressure of the cold gas to be compressed

with inlet and outlet openings for hot and cold compared to the expanded hot gas in the

Includes gas. 5 low pressure zone at least one gas stream in the

In aerodynamic pressure wave machines, the high pressure zone is divided and a partial flow which expands a hot gas from a higher to a deeper flushing of the cells in the low pressure zone under-pressure and supports the thus obtained expansion. A pressure wave machine, which is used for through energy, a cold gas from a guide of this method is suitable, has a lower to a higher pressure to compress. At io additional inlet opening for the partial flow.
These machines are divided into two main groups. In the drawing, two exemplary embodiments are distinguished:. -. · ;. ■ ·; ;. jj of the invention, which will be described in more detail below

a) The pressure exchanger (e.g. to be written after the German. It show

Patent 724 998), in which p, “Ä5p _2v and p _in .s? P _iv Figs. 1 and 3 are schematic representations of the abist. This means that the cold gas is _{compressed from P 1 w} to p _2n 15 windings each of a cylinder section at half height and the hot gas from p ₂ V to p _{17r of} the cells is expanded through the cellular wheel and through the face. (The indices v- and η therefore stand for "in front of the manifold with the inlet and outlet openings and after, 1 and 2. for the lower and higher levels, respectively."
As an energy balance shows, Fig. 2 and 4 show the associated wave cycles in the expansion pressure-speed diagram that takes place at high temperature,
sion a larger amount of energy available than in the F i g. 1 and 3, the hot gas flows which is required for the compression of the high pressure inlet openings 2ν of the pressure waves of the cold gas with the same mass flow rate. To compensate for this, either the mass processed in the pressure exchanger or openings In must exit again from the machine. The cold gas flows through the cold gas be greater than that of the hot 25 low-pressure inlet ports 1 ν to and exits from the gas, or it must be the excess portion of the hot high pressure exhaust ports 2 η .wieder from _v geGases in another machine relaxed The dashed line illustrates the dividing front, with one for this by mixing with cold gas. ting _; hot and cold. G.as.vCDhe movement direction machine permissible temperature is reached, which is the direction of the cells is indicated by an arrow,
but means a thermodynamic devaluation. 30 "At the beginning of the cycle <3 the cell in field 0 is with

b) The pressure transducer or pressure transformer (e.g. filled with cold gas. Inbekännter -Weise flows -through according to the German patent specification 1 000 132), in which- die_Hochdruck = - inlet opening-2-ii - der_jy [main flow for the Pressure exchanger applicable restricting the hot gas from pressure p _2v in Fejjdern 1, conditions with regard to pressure equality not on ^ · - 3; 5-into the cell, compressing the cold gas on the step. According to the current state of the art 35 is _2RT pressure p and pushes it in the fields 2, 4 by doing a large pressure difference (p _ln -p _lv), only the high-pressure outlet port 2 from η. The pressures attainable, even if (p _2n -P ₂ v) S ^r ° ß i ^st > ^{weu <s} i ° h P 2 ν ^unc ^ Psη ^sm ^ ^only slightly different from one another, otherwise, as from the pressure-velocity slide The outlet opening 2 η becomes when the inlet opening 2 ν grams can be seen, the wave cycle is not closed, so that the cell would be in after rinsing. If a higher pressure 4 ° of the high pressure zone, the high: X> jerk in the field 6 ratio is to be achieved for the cold gas, i.e. p _2n / p _{1 v} ^> P _{2 v} / p _{t n} remains. In field 7 there is therefore a part of the expanded, can also be, with the same mass throughput. mean. Gas with high speed. In the cold and hot gas, the energy balance between the low-pressure outlet opening In ' and sucked in to balance compression and expansion energy. Field 8 from the low-pressure inlet port 1 ν 'cold

For some, thermal processes would be a pressurized 45 gas after. But because the pressure in field 8 is much lower

wave machine desired, at the p. _2n ^ p _2V and as is in field 7, reflections of the waves would die

P ₁ " > P _{1 v} , the expansion in a possible flushing in the low-pressure zone quickly comes to a standstill

high temperature area takes place and the mass and bring about reversal. To prevent this,

throughput of cold and hot gas is approximately the same, the cell will be in time on both sides ... again is. If, for example, the 50 is to be closed in a gas turbine system, and a medium pressure remains

Pressure wave machine on the flow side to the compression field 9.

ter downstream or upstream of the gas turbine, according to the F i g. 1 and 2 now flow into field 10

so. , would be ... p ₂ ,, J = AP _{5 v,.} ..da ".dexJQrock loss..in .. the". .Partial flow of .des ,, hot. Gases "from pressure: _p. _2v _ in the

Combustion chamber is relatively small. It could supply high pressure inlet port 2 and charge the cell the whole mass: of the hot combustion gas in 55, in field 11 to a level higher than in field 9

the pressure wave machine expand, and pressure on it. In order to . is. enough energy for one

the air would be sucked in at a pressure level, second flushing in the. Low pressure zone available,

that would be significantly lower than that of the gas outlet. The remaining hot gas flows in fields 12, 14

step. That would mean that the compressor is ent- in the low-pressure outlet port In out, and in would be burdened, so would take up less power and 60 field 13 takes place through the low-pressure inlet port

therefore the useful power and efficiency increase Iv the filling of the cell with cold fresh gas,

would. If necessary, a further high-pressure inlet

A solution to this problem has not been found so far. Opening Iv " and a third flush in the low-

knows. The invention is based on the task of providing a pressure zone, otherwise the cycle an aerodynamic pressure wave machine starts anew in 65 field 15 = 0,

form that they under the conditions mentioned The cycle according to F i g. 3 and 4 is up to

can work. According to the invention, this task is identical to the one after the state in field 9

solved in that at approximately the same pressure Fig. 1 and 2. Then, however, the second flushing takes place

in the low-pressure zone not by recharging the cell with hot gas, but a partial flow of the compressed cold gas which is under pressure P _2n is branched off and fed through the high-pressure inlet opening 2n 'in field 10 of the cell, while the main flow is supplied to the intended use. The energy required for a second flushing of the cell is thus available in the low-pressure zone, so that the remaining hot gases flow out in field 12 through the low-pressure outlet opening In. In the fields 13, 14 there is a thorough flushing and the filling of the cell with cold fresh gas.

In terms of overall efficiency, this process is probably the same as the process according to FIGS. 1 and 2 inferior. However, by using the colder high pressure gas to aid the purge, the hot one becomes Gas is displaced from the cell faster, which means that the cell is better flushed through and cooled.

Here, too, if necessary, a further high-pressure inlet opening In " and a third flushing system can be provided in the low-pressure zone. It is also possible to branch off a partial flow of both the hot and cold high-pressure gas and to add it to support the flushing in the low-pressure zone use.

According to FIGS. 1 and 3 in Field 6 the right end of the cell not quite, -which can be an advantage, since the buffer zone z. B. the heat transfer scaled down. The machine can also be designed in such a way that the separating front is the other end reached.

In the F i g. 1 and 3, a reverse flow pressure wave machine is shown; that is, the gas kicks in on the same side of the cellular wheel on which it occurred. The idea of the invention is natural Can also be used on machines with through-flow, where the gas enters on one side and exits on the other. Also is It does not matter whether the machine has fixed front-end distributors and rotating cellular wheel or with rotating distributors and a fixed cell wheel. Likewise, the and exhaust ducts bifurcated within the machine or several separate lines can be connected be in order.

The pressure wave machine according to the invention can be used in thermal processes to which it was previously not applicable or only with disadvantageous restrictions. The good conditioner

ίο in the low pressure zone allows a higher Degree of purity of the cold gas to be compressed than was previously achievable. Will the pressure wave machine upstream of a gas turbine, its speed can usually be selected optimally. Should However, coordination difficulties can occur in certain partial load conditions Wise gas pockets are used. Further possible uses of the invention Pressure wave machines are used in the chemical industry, in process engineering and in charging of diesel engines available.

Claims (2)

Patent claims: 1. Method for operating an aerodynamic pressure wave machine, which has at least one Includes rotary valve and front distributor with inlet and outlet openings for hot and cold gas, characterized in that at approximately the same pressure of the compressed cold and the hot gas to be expanded in the high pressure zone and much deeper Pressure of the cold gas to be compressed compared to the expanded hot gas in the low-pressure zone at least one gas flow is divided in the high pressure zone and a partial flow is the scavenging of the cells in the low pressure zone. 2. Aerodynamic pressure wave machine for performing the method according to claim 1, characterized by at least one additional inlet opening (2v ', 2n') for the partial flow. 1 sheet of drawings