DE2247890A1 - ELECTRONIC INDICATING DEVICE FOR PISTON POWER MACHINES, IN PARTICULAR LARGE DIESEL ENGINES - Google Patents

Description

Electronic.Indication device for reciprocating engines, in particular Large diesel engines The invention relates to an indicating device for piston engines, especially large-size motors.

As is well known, the measurement of the indicated power of a piston engine made with the help of a chart-writing indicator. With this indicator the individual cylinders are tested one after the other and then the ones obtained Indicator diagrams evaluated with the help of a planimeter.

The practical implementation of such an indicator measurement represents a real procedure: the indicature is on the cylinder cover Indicator socket attached. Then the leash is used for the pulley drum operation Connected to the indicator linkage of the engine over a distance of several meters, see above that the cylinder pressure / piston-and-piston-dependent indicator diagram is now recorded in the indicator will. This very carefully prepared and carried out procedure is repeated with all the details and handgrips of each of the cylinders to be tested.

Subsequently, the areas of the obtained indicator diagrams measured with the help of a planimeter and the measurement results with the code number of Indicator spring and converted to the dimension PSi using the recording scales will.

Not only does it come down to the -rtihiq when measuring the surface area Hand of the person measuring, but already contain the already very small diagrams Transmission inaccuracies caused by the greater or lesser degree of flexibility and vibration amplitude of the more or less long and more or less strong accelerated union.

Now, after painstaking detailed work, the individual cylinder outputs are finally there in different numerical values, so no one can say for sure whether the differences really from the different functions of the individual cylinder sections Or maybe they stem from an unfortunate accumulation of measurement inaccuracies or fluctuations in the power output between the individual measurements are due. Thus the real sense of the measurement becomes izilusory, because the measurement of the indicated power should give exactly reliable information over the entire engine output and also over the proportions of the cylinder outputs on the overall performance.

In practical use, large diesel engines always have a constant speed settled. This means that the engine is always demanded that power which is necessary to maintain the constant operating speed. After this the operating power of the motor with a percentage of the maximum continuous power is extended, this situation is by no means critical. It only becomes critical if one or more injection nozzles of the engine no longer spray exactly or if different piston leaks have occurred. Then namely, have the cylinder sections that have remained intact; the failures of those who have become ineffective To bring cylinder sections with and get into an uncontrolled load area.

The situation becomes even more critical if decisions are made at short notice must, the engine within the time intervals allowed by the manufacturer with increased Speed at the overload limit. In order to be able to determine at all, with which speed increase the upper load limit of the most stressed cylinder section is reached, an indicator measurement would first have to be carried out. But since the conventional measuring method takes at least an hour and yet the results do not promise an exact statement, the measurement is omitted and speeds up the engine as you see fit, waving yourself according to the top speed oriented.

The bottom line is the regular check of the indicated engine performance of great importance for the service life and for the trouble-free operation of the Engine. On the one hand, the indexed cylinder powers should provide information about the function the injection nozzles and piston leaks and thus information about the proportions of the individual cylinder sections in the total output. On the other hand, the Indexed total power - with the effective engine power measured on the output shaft put in relation - significant conclusions about the internal bearing friction conditions to. All in all, however, the conventional measuring method is very cumbersome, inconvenient, inaccurate and time-consuming, so that one is reluctant to take the measurement when does not completely omit for a long time. Then you use the conventional one Indicator finally, one usually discovers revealing changes, such Changes that should definitely have been made immediately after they appeared must be discovered and eliminated.

With the invention, an electronic indexing device is presented, which for the duration of the actuation of a push button continuously the finished in PSi calculated cylinder outputs and at the same time with the last cylinder output the firing order also prints the total power.

The button can be held down as long as you like, or the Button can be pressed as often as required. In each case, they are in chronological order the firing order is printed out reliable indexed power, exactly exact electronic Calculation results which are not - as with the known measuring method - individual Constitution of a measurer are subject.

Equipping the engine with the indicating device according to the invention allows maintenance personnel to effortlessly maintain operational health at any time of the engine and to monitor the individual performance of the cylinder sections.

So far, a large diesel engine was able to take into account the unsupervised indicated power only constant speed and driven in the partial load range it is easily done with the aid of the indexing device according to the invention possible to keep the motor constant with a monitored maximum continuous output travel. This is done by changing the engine speed while the indicating device is in operation is increased until the most popular cylinder section is the Corresponding number of cylinders Individual performance is printed out. on In this way, the investment object large diesel engine can always be fully undamaged can be used1 without taking into account the uncertainty factors - as has been the case up to now the use of power reserves must be dispensed with.

This modified driving principle of a large diesel engine steers intuitively the maintenance staff's eye for careful monitoring of the nozzle function and the piston tightness, because only with evenly spraying nozzles and evenly sealing piston can be the maximum continuous power, or the initiating Extend the upper load capacity optimally. So far, this possibility has only existed directly after a conventionally performed indicator measurement, and it still passed only for a short time, unless the entire maintenance staff, supported by additional Auxiliary staff, is constantly busy recording indicator diagrams and to evaluate.

Extending the engine optimally right away has not been practical so far possible, precisely because the measurement is seldom carried out due to the inconvenience and thus the measurement that is now carried out in the event of a sudden need Certainly different nozzle and piston functions that have gone unnoticed so far reveals.

The economic benefit of the electronic indexing device according to the invention can be found on two levels. On the one hand, it can be done without harm to the engine a significantly higher power output related to the effective operating hours achieve, whereby the service-related investment costs are reduced. To the others should have a single engine failure from a source of damage that was not discovered in time In terms of downtime alone, it can be greater than the cost of the entire delta tronic indexing device.

The invention will be explained in more detail with reference to the drawing. It Fig. 1 is Fig. 6 shows the mode of operation of the principle according to the invention with the aid of the indicator diagram of a piston steam engine, Fig. 7 the practical construction of the electronic indexing device, FIG. 8 the indicator diagram of a charged Four-stroke engine, Fig. 9 shows the electronically determined calculation result of the intake stroke of a supercharged four-stroke engine3 Fig. 10 the electronically determined calculation result of the compression stroke of a supercharged four-stroke engine, FIG. 11 the subtotal from the calculation results recorded in FIG. 9 and FIG. 10, FIG. 12 that electronically Calculated result of the expansion stroke of a turbocharged four-stroke engine, 13 shows the subtotal of the in flight. 9, 10 and 12 recorded calculation results, 14 shows the electronically determined calculation result of the exhaust cycle of a charged one V1-stroke engine, Fig. 15 the final cylinder output of a supercharged four-stroke engine after passing through all four working cycles Fig. 16 that for a six-cylinder Engine with the firing order 1-6-2-4-3-5 designed circuit diagram of the entire electronic Indication equipment.

In the following, the principle according to the invention is initially applied to elementary ones Way explained on the basis of the symbolized representations in Fig. 1 to Fig. 6, wherein for the purpose of demonstrating the individual mathematical calculations of simplicity half the indicator diagram of a piston steam engine is used.

The rod P symbolizes an alternating positive or negative impact Ladder, which is equipped with any number of grids with a specific pitch is. The electronic storage mechanism R is influenced by the cylinder pressure Sensor R 'equipped, which touches the zero mark of conductor P in FIG. In This sensor position contains, among other things, the storage unit R the value zero. With beginning Upward movement of R 'as a result of increasing cylinder pressure, conductor P becomes positive applied. If R 'now touches the next grid in the course of its upward movement of the conductor P, the storage unit R is given the positive value by this pulse a entered. In the course of the further upward movement of R 'wira with each grid contact, a positive value a is added in the storage unit R. So for example R 'at the twenty-ninth grid, the storage unit R is twenty-nine times has been assigned the positive value a and thus contains the value + 29a, If the feeler R 'returns to any previously held position (in the explanatory example + 29a) reverses its direction of movement as a result of falling cylinder pressure, so it already becomes in the first phase of the inversion of the conductor P negatively charged, and with each Contact with the grid during the downward movement of Rt is released from the storage unit R the value a subtracted out. Finally the sensor R 'comes back to the If the zero mark is on, twenty-nine negatively charged rasters are touched one after the other and the storage unit R is back in money.

The electronic storage unit R always holds that multiple from a, which the sensor R 'shows on the scale of the conductor P.

This multiple of a is - and that is for further utilization of the memory content is important - always positive according to the dimension ate.

The memory content of R is queried by means of error S 'des electronic summation memory S on the way over the conductor bar H.

The sensor S 'of the summation memory S is influenced by the piston stroke and extends in its path delimitation from the top dead center OT of the conductor H to its bottom dead center UT. Likewise, if conductor P, conductor H is the same with grids Division and is alternately acted upon positively or negatively. With the downward movement of the piston finds the sensor S 'in its direction of movement from OT to UT the conductor H is always positive öeaufschlagi and in his Opposite direction from UT to OT always negatively applied.

If the sensor S 'is now moving as shown in FIG. 2 with the piston descending from his turning point OT in the direction of UT and he comes up with the first grid of the ladder - in contact, with this impulse the memory R becomes its current one Content requested. This value (in Fig. 2 it is + 29a) goes over the positively charged one Head H in the summation memory S as a summand + 29a -ein. Feeler S 'arrives in the course of the Piston downward movement according to FIG. 3 on the second grid of the conductor H, so the memory R interrogated in turn.

This time, as a result of an increase in the compression pressure, he likes the value + 30a include. This value also has a positive sign in the summation memory S so that the total content of the sum memory S is now + 29a + 30a = + 59a. With each grid reached by the sensor S 'on the conductor H, the respective content goes of the memory R as a summand in the summation memory S until finally, as shown in FIG. 4 the sensor S reaches the bottom dead center BDC.

As FIG. 1 to FIG. 4 demonstrate, with the aid of the In principle, a finite number of area ordinates electronically to form a total area integrated. The respective content of the memory R therefore represents a surface element of the width a and the height P, where a = piston stroke H = delta H (m) grid number n and P = effective piston pressure (ke) Jolllit respective contents of the memory R I = a x P = delta H x P = delta L (mkg) The summation memory S continuously asks the the power elements associated with the individual grids of the conductor H from the variable Delta L and sums it algebraically. So that the size L in the dimension PSi can appear; the quantity a also contains the corresponding dimensionless one Conversion factor.

With the start of the upward movement of the piston at turning point BDC, changes the conductor H has its polarity and is negatively applied in FIGS. 5 and 6.

The positive ones queried with a negative orientation with the polarity change Power elements of the memory R now go according to the mathematical Law as subtrahends in the summation memory S. Finally reached the Sensor S 'returns to its starting position OT, so the summation memory S contains 6 shows the total indexed power PSi from the finite sum of all algebraically received power elements delta PSi.

In OT, a pulse generator located there causes the content of the Summing memory S printed out in a printer and at the same time the summing memory is deleted for the next run that now follows. This way it becomes continuous after each full rotation of the crankshaft, the induced power of the piston engine concerned (here steam engine) in the dimension PSi.

Di with reference to the drawings Fig. 1 to 6 made explanation of the Principle according to the invention with the help of the indicator diagram of a piston steam engine, is intended again in FIGS. 8 to 15 using the example of a supercharged four-stroke internal combustion engine be demonstrated. In the case of a four-stroke engine, the sequence is Ansougen-Kompresslon * Expanslon-Extension all queried performance elements entered one after the other in the sum memory S. Only that is printed out after all four work cycles according to FIG. 15 have elapsed The final result present in the summation memory S.

The subtotals shown graphically in Fig. 11 and flight 13, should only provide the viewer with a clear skylight.

In order to be able to practice the principle of the present invention, more suitable ones are required Components, which the conditions of the different working principles of piston engines must be adapted In Fig. 7 is a solution tailored to four-stroke engines shown. An application example is a six-cylinder engine with the ignition sequence 1-6-2-4-3-5 selected, the fifth cylinder section is shown with the compression stroke rising piston. The individual components involved and their functions are explained as follows On the indicator connection on the cylinder cover of the motor is a spring-loaded pressure cell 1 of known design, with adjusting device 2, arranged.

The conventional indicator stopcock has been replaced by an electric one remotely operated magnetic three-way valve 3 of known design. Illustrated in the drawing is the electromagnetic state of the three-way valve.

In the unpressurized state, the interior of the pressure can is with the Connected to the atmosphere Lifting movement of the pressure can stamp in rotary movement of the feeler disk 4 to. The one with Feeler disk 4 firmly connected feeler R 'conductively scans the grid of the grid segment P from. The spaces between the individual grids of the grid segment P are expediently filled with abrasion-resistant, non-conductive plastic.

Covered by the feeler disk 4, is on the rear wall of the housing the pole changer 5 rotatably mounted. The leaf spring firmly connected with pole changer 5 6 rests on the circumference of the feeler disk 4, s that between the feeler disk 4 and Polwender 5 established a weak, electrically conductive Mltnehmer-Rutschver connection is.

If the sensor R 'is now shown by increasing cylinder pressure offset in a clockwise rotation, the pole reverser 5 is already in aer alierste Phase of clockwise rotation at the positive pole and has a positive effect on sensor R '. All the following raster pulses are positive in the arithmetic memory R, that is, as summands a. As well as the sensor R 'with falling cylinder pressure its clockwise rotation in counter-clockwise rotation uml (EhrJc3 is immediately after the turning point is exceeded by the moving Pole inverter 5 applied negatively, whereby all now following raster impulses in the rake? E'icher R negative, i.e. as subtrahends.

The angle of rotation of the sensor R 'should be as large as possible and the grid division of the grid segment P should be as small as possible. Optionally, P can be considered full Grid ring are formed. For the function of the device described above it is unimportant on which grid the sensor fl is under AXmosa spherical pressure stationary pressurized can comes to a standstill. It is only important that in this "zero state", i.e. when the Ma-net three-way valve is closed 3 the computing memory R contains the value zero. This is done every time the electronic Indexing device ensured by automatic deletion of the computing memory R.

At the beginning of the description, FIGS. 1 to 6 were referred to for the better Understanding explains that the conductor rod H, influenced by the piston stroke, depends on the direction of movement the piston is alternately acted upon positively or negatively. This changing The polarity of the conductor bar H had the effect that the always positive content of the Computing memory R with descending piston as positive information and with uplift Piston is received as negative information in the summation memory S.

The construction according to FIG. 7 does not change this principle, but it does there is not an alternating loading of the pulse generator here, but rather neutral pulses are generated, which the content of the computing memory R means Selenium cells either in the positive or in the negative recording of the accumulation memory Bring in S. It is also not just a single impulse generator (previously head H) exists, but each of the four work cycles has its own impulse generator. These pulse generators - called slot segments in the following - occur one after the other in function.

For the purpose of the aforementioned piston stroke-dependent impulse output, the circular perforated disk 7 from the camshaft of the motor with the reduction ratio driven by 1: 1, so that it rotates with half the crankshaft drive. The perforated disc 7 acts as a light barrier and for this purpose is shown with four Scblltzsegmenten equippedq The four slot segments are the four work cycles assigned namely slot segment X to the intake stroke, slot segment II to the compression stroke. Slot segment III to the expansion cycle and slot segment IV to the extension cycle. the Slot segments I and III are on an inner pitch circle, the slot segments II and IV are arranged on an outer pitch circle of the perforated disk 7.

At the height of the two circles of the slits, both rare with the perforated disc 7, the light sources 8 and 9 and the selenium cells 10 and 11 are fixed in place.

The light source 8 and selenium cell are located in the horns of the inner circle of slots 10 opposite each other, and on the outer circle of holes are the light source 9 and selenium cell 11 across from each other. The selenium cells 10 and 11 are in the manner shown with arithmetic memory R and summation memory S conductively connected the The previously described light barrier group 8/9/10111 is only for the cylinder section Z5, i.e. shown for the fifth and last cylinder of the ignition tank. The same The light barrier group for the remaining cylinders is located at the cylinder section Z1, Z6, Z2, Z4 and Z3.

In addition to the perforation of the four slot segments, the perforated disc is also given 7 at the transition between slot segment IV of the extension cycle and slot segment I. of the intake stroke a contact strip 12, which when the perforated disc rotates in each of the six cylinder sections the contact lug 13 and also only in Cylinder section Z5 (of the last cylinder in the firing sequence) touches the contact lug 14.

When pushbutton 15 is pressed, relay group 16/17118 charged with control current. The relay immediately acts on the sensor R 'of all six Pressure measuring devices of the engine. Half a second later, relay 16 also extinguishes the remaining content of all six arithmetic memories R. The deletion takes place as long as the sensor R 'is still under the influence of the atmospheric pressure are in their original position. Only after that - another one half a second later - relay 18 acts on all six actuators of the magnetic three-way cocks 3, whereby now all six sensors R 'on the respective pressure of their cylinder react.

In this way the electronic indexing device is in operation taken; the further functional sequence is described as follows: From the in Fig. 7, for example, the switched-on position of the system is shown as the perforated disc 7 circumnavigated to the left until contact strip 12 is on the mark for cylinder section Z5, the last cylinder of the firing order 1-6-2-4-3-5, has arrived. The here The implementation phase will be examined in detail at the end of this consideration. The reactions to the triggering of the contacts at that moment should also be expected 13 and 14 are initially disregarded.

Immediately after crossing the Z5 mark through the contact strip 12, becomes the first slot of slot segment I (intake stroke) of light source 8 X-rayed and selenium cell 10 conductive for the duration of this light pulse. Of the in front of selenium cell 10 as the current cylinder pressure always positive content of the computing memory R, thus arrives as positive information in the summation memory S and is stored positively there.

rtzso all others are triggered by the intake slot segment I. Inquiry pulses in the summation memory S summed up as positive information.

With the passage of all slots of the suction slot segment I, the summation memory S contains a positive performance fragment from the one shown in Fig. 9 demonstrated greatness.

After the last slot of the suction slot segment I the light source 8, the first slit of the compression slit segment tt becomes the light source 9 is transilluminated and selenium cell 11 is conductive for the duration of this light pulse. the The function triggered by this, however, is different from the previous one for the suction slot segment I described. The current cylinder pressure before Selenze, le 11, always positive content of the arithmetic memory R, comes in as negative information the summation memory S and is thus stored negatively there. So will all further query pulses triggered by the compression slot segment II in the summation memory S added algebraically as negative information. The summation memory S was now input a negative performance fragment of the size demonstrated in FIG. Summing memory S does, however, because Yes is continuously added algebraically - a smaller negative performance fragment and indeed of the one demonstrated in FIG Size.

in the further sequence of the crankshaft rotation run again - this time dusyeiöst from the expansion slot segment III - positive information in the accumulation memory Being. A performance questionnaire from the one in FIG. 12 is added algebraically demonstrated greatness. However, since the positive irregularities dominate, it remains after the passage through the expansion slot segment III a positive Lelstungsfragment of the size demonstrated in FIG.

The last thing to do is push-out slot segment IV. This information is in turn negative in the summation memory S, namely from the size demonstrated in FIG. The now remains in the summation memory S final cylinder performance of the magnitude demonstrated in FIG.

before the intake slot segment I is set to the second passage, must be the cylinder output of the first run just created in the summation memory S. printed out in printer D and at the same time the summation memory 5 deleted. This is done by means of the contact strip 12 which be on the perforated disk 7 between Push-out slot segment IV and A-nsaug-ßc-hiitzs-segment I is attached. After this the last slot of the eject slot segment IV its requested information has delivered to the summing circuit S, the contact strip 12 touches the contact lug 13 which triggers the function of printing and deleting.

Since here the cylinder section Z5 is the last of the firing order 1-6-2-4-3-5 is considered, contact strip 12 fulfills another function. With the touch the contact lug 14, which is only present in cylinder section Z-5, is given to a printer D the command, all cylinder outputs printed since the last contact - namely the cylinder outputs of the firing order - to be summed up and as a total output of the engine.

In this connection it is recalled that the cylinder sections Z1 to Z6 consequently and at a mutual distance of 60 degrees rotation angle around the Perforated disc 7 are grouped. In addition to its own computer memory, each cylinder section has its own memory R also has its own summation memory S. After the individual cylinder sections one after the other are traversed by the slot segments I to IV, they promote each after full passage of the slot segment IV their cylinder power in the common Printer D. So gives contact strip 12 via contact lug 14 to print out its command the total engine power, all six individual powers are already in printer D printed out and still saved. Otherwise, the six are stored in the printer D. Individual services are automatically deleted when the total service is printed out.

Exhaustive information about these processes is given in FIG Circuit diagram of the entire system designed for a six-cylinder engine. For purposes of illustration, the perforated disk is shown here clockwise.

The processes in the start-up phase of the System.

This is to be made up for in the following.

At the moment when the feelers R 'start their activity and the not sources b / 9 affect their selenium cells 10/11, there is the contact strip 12 ar any point in its orbit and under no cylinder station ZI bis Z6 is exactly the first slot of one of the four slot segments. Though the contents of the six memory storage units R were correct from the start and thus were the individual information requested from the associated memory is correct, but for none of the six cylinder sections is the total information of the relevant one cut work cycle completely. Consequently, when driving over the individual Contact lugs 13 through contact strip 12 incomplete cylinder performance and ultimately an incomplete overall performance is also printed out.

Since when the arithmetic operations begin, the contact strip 12 is not was exactly on the mark for cylinder section Z1, this first run is already incomplete with regard to the number of cylinder outputs printed. Of the The second pass, which is now beginning, leaves printer D for each of the six Cylinder is an expression of performance, but here are all those cylinder performances incorrectly printed out which first pass has not yet been printed on the print strip have appeared. All other cylinder outputs are correctly printed out. Consequently at the end of this second pass is the total output printed out in cylinder section Z5 still not right. Only in the third round that is now beginning will be without exception all cylinder outputs and at the end also the total output correctly printed out.

For a better understanding of the preceding description of the in the start-up phase, is then the one from the Printer D recorded and annotated leaking print strips. Here is assumes that the system starts exactly in the situation shown in FIG. Here contact strip 12 has already passed the mark Z6, so that it has the associated Contact lug 13 no longer touched.

Until the total output is printed out in Z5, only incomplete data will be displayed Individual outputs of cylinders 2, 4, 3 and 5 are printed out. The brands Z1 and Z6, on the other hand, are only run over by the contact strip 12 for the first time in the second pass. It is also assumed that the first slot of the suction slot segment I in Z6 is just not emitting an interrogation pulse any more.

Z1 nothing yet printed Z6 nothing printed yet Z2 ###### wrong Z4 ###### wrong Z3 ###### wrong Z5 ###### wrong sum ###### wrong Z1 ###### wrong Z6 ###### because of missing the first slot of I still wrong Z2 ###### now correct for the first time Z4 000000 now correct for the first time Z3 000000 now for the first time correct Z5 000000 now correct for the first time total ###### still incorrect due to cylinder performance Zl and Z6 Z1 500000 now correct for the first time E6 000000 now correct for the first time 12 000000 correct 14 000000 correct Z3 000000 correct Lb 000000 correct sum 000000 right now for the first time Ditt: Record shows that only the third round gives correct results without exception. For example, drives a four-stroke engine at 120 rpm, in this case the perforated disk 7 rotates with one revolution per Second. This means that after a maximum of three seconds of start-up phase, correct performance results are printed out in printer D. Add one second after pressing the push button 15 for the response time of the relays 16 and 18.

Finally, the effect of the crank drive characteristics would have to be investigated exercises on the measuring principle according to the invention.

With a constant speed of the perforated disk 7 is on the cylinder sections Z1 to Z6 record a constant pulse throughput per unit of time. The pulse throughput however, per centimeter of piston travel is not constant. In the area of the two dead points the impulse throughput related to the piston path is compressed, and moreover it is with finite crank rod length closer in the lower dead center than in the upper Dead center.

If one now looks at the indicator diagram, which is recorded electronically, as it were, this results in an accumulation of ordinates in the dead center areas and, in addition, is the accumulation in the two dead center areas is different. But since before and there is symmetry behind the two dead points, the ordinates coincide of the piston outward path exactly with the ordinates of the piston return path. The crank drive effect does not result in inaccurate calculation results. On the contrary, it comes Accumulation of ordinates in the areas of large cylinder pressure changes in accuracy opposite.

The representations in Fig. 7 related to the application of the electronic Indexing device for four-stroke engines. Comes a two stroke engine for the application into consideration, only the perforated disk changes in such a way that it takes place of the four quarter circle slot segments only receives two semicircle slot segments one of which on an inner circle and the other on an outer circle is arranged. In addition, in two-stroke engines, the perforated disk 7 runs at the crankshaft speed around.

Since the perforated disk 7 is constantly running, the piston stroke-dependent Impulse generation selected the non-contact method by means of a light barrier. As well However, contactless pulse transmission can also be used for cylinder pressure measurement will. In this case, the feeler R 'would be provided with a double slit Replace perforated disc and with the help of the pole changer 5 alternately the one or the other light shaft to the selenium cells is to be dimmed. Last but not least, can contact 12/13 and 12/14 are made in the same way by means of a light barrier, as shown for the slot segments.

Claims (3)

Claims 1.Indicating device for reciprocating engines, especially large diesel engines, d a d u r c h e k e n n n z e i c h n e t that by means of each of the existing Cylinder assigned, cylinder pressure dependent, alternately positive or negative charged pulse generator by scanning an evenly divided pulse generator, alternately constant positive pressure increase units encoded with a conversion factor, or negative pressure drop units of the same size in each of the existing ones Cylinder allocated electronic memory are added algebraically, whereby this always the encrypted number equivalent of the pending Cylinder pressure in the ordinate size delta PSi keeps that a further Piston stroke dependent, positive in piston down gear and negative in piston up gear activated pulse pick-up at uniform angular intervals of the crankshaft rotation, queries the relevant memory for their respective content delta PSi, these queried contents one after the other algebraically into one, each of the existing ones Cylinder allocated summation memory is added, and that finally after each Passing through all the work cycles of each cylinder the contents of their assigned Summaries can be printed out and deleted in a shared printer and after printing out all of these individual cylinder outputs in the dimension PSi the total output of the machine is also printed out in the PSi dimension. 2. Indicating device according to claim 1, characterized in that the impulses for data transmission are contactless by means of light barriers. 3. Indicating device according to claim 1, characterized in that the impulses for the data transmission are generated by grid contact. Blank page