HU180938B - Apparatus for measuring the power of internal combustion engines - Google Patents

Abstract

An inductive pick-up generates impulses dependent on the speed of rotation of the drive shaft of an i.c. engine and feeds them to a pulse shaper. A speed lever selector is connected to the latter and feeds the control unit for the ignition and the control for the measuring unit. Both controls are synchronised with clock pulses from a clock pulse generator which also governs an normalised pulse train generator. A further pulse train generator is coupled to the control unit to generate an output corresponding to the pulse count from the motor during a given time interval. A subtraction circuit counts the difference between the two pulse trains and this value is recorded.

Description

Specialist Office of Design and Engineering Office of Sibirskov Office of the Professor Wesayajnoy Akademy Selective House of Lenin V. Krasnoyobsk, USSR

Apparatus for measuring the power of internal combustion engines

More particularly, the present invention relates to an apparatus for measuring the power of internal combustion engines.

The invention can be successfully applied in all spheres of economic life, where internal combustion engines 5 are manufactured or used, such as in the production of internal combustion engines, in vehicle service stations and repair shops, in machine and tractor stations, etc.

The automotive and tractor industry is currently evolving at a rapid pace and requirements for accuracy, standby reliability and ease of use of devices for controlling internal combustion engine parameters are increasing. i®

When measuring the power of an internal combustion engine, it becomes clear from the following relationships that it is sufficient to measure the engine speed, from which power can clearly be stored.

It is also known that

M _k p I _n p

(2) where I _np = reduced moment of inertia d.9 —— = angular acceleration of the rotary axis

From this we can conclude that

Ιγγρ X n dw dm

716.2 ^X dt ^x dt (3)

In terms of engine power in hp, the following equation applies:

Ne =

_Mp xn

716.2 (1) where M _kp = torque n = speed 30

From equation 3, it can be seen that it is sufficient to determine the do / dt angular acceleration for the measurement of power N _e if the engine speed, n is known.

For the measurement of the performance of internal combustion engines, the above equations are used for a solution according to Soviet Authorization 314 088, where the angular acceleration dw / dt is determined as follows:

A series of pulses containing a number of pulses proportional to the rotational speed, i.e. angular velocity, of the internal combustion engine is derived, the difference between two angular velocities, i.e., two pulses, is determined and divided by the time elapsed. If the time above is set to a value of 180938 then it is sufficient to know the difference in angular velocities, i.e. the difference between the two revolutions, and the constant C for the particular engine to determine power. 5

No. 314,088. The power meter described in the Soviet copyright certificate comprises, in accordance with the above, the following elements: a serial switch transmitter for recording the speed of the internal combustion engine, an electric pulse generator, a speed selector for selecting the internal speed of the internal combustion engine, a control unit for controlling the level, a control unit for controlling the unit, together with a clock generator associated therewith, for measuring the difference between two successive pulse sequences and for recording the measurement data. The apparatus 20 further comprises a digital-to-analog converter coupled to the aforementioned unit for evaluating the difference between two adjacent pulse sequences; and a voltage divider connected to this converter and connected to a unit for recording the measurement results.

However, in this apparatus, when the impulse periods are not divisible, the actual residual portions of the electrical impulse periods are lost. The pulse frequency is proportional to the speed of rotation of the internal combustion engine shaft and is within the time domain defined by the unit control unit. This causes a significant error in determining the speed of rotation of the motor shaft.

In addition, for this apparatus, errors due to the time intervals determined by the control unit of the apparatus and due to the indivisibility of the periods of electrical pulses from the pulse generator cannot be reduced to a predetermined value. When approaching the transition process curve in a straight line during engine start-up, significant 45 methodological errors are made. In addition, the fact that a small number of measured values are used during measurement also leads to a significant error in determining the speed dependence due to approximate interpolation.

In the known apparatus, the measurement results are displayed in the desired unit (e.g., horsepower) of the analog-to-digital converter and voltage divider with alkaline power whose electrical parameters vary with time and temperature fluctuations. Sensing also causes errors in the measurement of internal combustion engine performance.

On the other hand, the installation of a rotary speed transmitter in the known apparatus is costly because it requires a change in the design of the motor and thus reduces the possibility of immediate use of the apparatus.

SUMMARY OF THE INVENTION The object of the present invention is to provide an apparatus for measuring the power of internal combustion engines, the additional components of which allow for greater accuracy and rapid measurement of the power of the internal combustion engine, and for greater reliability of the apparatus. >

This is achieved with an equipment for internal combustion engines of measuring the power rating * s, which has the following sections: a serial recording of the internal combustion motor ⁴ shaft rotational speed of the switching station, electrical impulzusformálót, the engine shaft speed determining rotational speed level selecting ^ OT and it's linked to IC a control unit for controlling the operating mode of the motor, a control unit for controlling the unit and a clock generator connected thereto, one unit for determining the difference between two adjacent pulse sequences and for recording the measurement results. The invention itself is based on the use of an additional number of pulse emitting auxiliary units connected to one of the clock generator input bins, the other input connected to the output of an electrical pulse generator and connected to an input of a unit for determining the difference between two adjacent pulses in addition, a building element is added; wherein the number of pulses in each pulse sequence is proportional to a portion of the period within the time interval defined by the device control unit / the electrical input pulse generator / first input of the pulse is connected to the electrical input pulse output of the second input to the second control input is connected to the other input of the difference generating unit, and the input of the speed selector unit for determining the speed of the internal combustion engine shaft is led to the clock generator.

In an internal combustion engine power measurement device, an adder may be additionally used to sum up two adjacent pulse sequences, the first input is connected to the output of a standard number of electrical pulses, the second input is connected to the output of the control unit, the third input is connected to and the output is connected to the input of the measurement recorder and an additional input of this recorder is connected to the unit control unit.

It is also desirable to use a system of the internal combustion engine which provides information about the respective angular position of the internal combustion engine as a transmitter for measuring the rotation speed of the internal shaft of the internal combustion engine.

In an internal combustion engine power measurement system, the AC generator of the test engine may conveniently be selected from systems which provide information about the angular position of the internal combustion engine. 5

In the case of devices for measuring the power of internal combustion engines, it is expedient to choose among the systems which provide information on the position of the internal axis of the internal combustion engine, the ignition structure of the tested internal combustion engine. 10

The invention makes it possible to measure a portion of the pulse periods within the time intervals determined by the device control unit. As a result, the accuracy of power measurement of internal combustion engines is greatly increased.

The invention also makes it possible to shorten the time intervals defined by the control unit of the apparatus and thereby to keep the methodological error of approximating the curve of the transient process 20 at the start of the internal combustion engine small.

It is also possible with the invention to significantly increase the number of readings during the measurement, thus more accurately saving the engine speed as a function of engine speedTval.0.

The invention will now be described in more detail with reference to the following examples, and with reference to the accompanying drawings. Here is

1 shows an example of an apparatus for measuring power of internal combustion engines according to the invention. a block diagram of an embodiment of the present invention in conjunction with a pulse transducer for recording the speed of rotation of a motor shaft for effective power measurement; the

Figure 2 is a block diagram of an embodiment of an apparatus for measuring internal combustion engine power according to the invention, wherein the power of internal combustion engines is measured as a function of speed and a pulse transmitter is used to record the rotational speed of the motor shaft; the

Figure 3 shows an example of an apparatus for measuring power of internal combustion engines according to the invention. a block diagram of an embodiment in which the apparatus is capable of measuring the effective power of internal combustion engines and using an alternating current generator of said engine to record the speed of rotation of the motor shaft; the

Fig. 4 is a block diagram of an exemplary embodiment of an apparatus for measuring internal combustion engine power in which the power of internal combustion engines is plotted against engine speed using an alternating current generator of the engine under test to record the speed of rotation of the motor shaft; 60

Fig. 5 is a block diagram of an exemplary embodiment of a device for measuring internal combustion engine power in which the effective power of the internal combustion engine is measured and the ignition structure of the engine under test is used to record the rotational speed of the engine shaft; the

Figure 6 is a block diagram of an exemplary embodiment of a device for measuring internal combustion engine power, in which the dependence of the power of internal combustion engines on the engine speed is investigated and the ignition structure of the engine being engineered to record the rotational speed of the motor shaft; the

Figure 7 is a block diagram of a standard number of electrical pulse emitting units

FIG. 8 is a block diagram of an electrical pulse generating unit, wherein the number of pulses in each pulse sequence produced in the unit is proportional to a portion of the period within the time intervals specified by the device control unit; the

9. Figures a, b, c, d are time diagrams of a device for measuring the power of internal combustion engines; the

10. Figures a, b, c, d, e, f, g, h, i, jk, 1, m are time diagrams of the signals in the unit producing electrical pulse sequences.

In the following, the use of a device for measuring the power of an internal combustion engine will be described in more detail on the basis of a specific example, to measure the effective power of an internal combustion engine and to determine the relationship between power and engine speed.

In the case of measuring the effective power, the apparatus for measuring the power of the internal combustion engine 1 has an electric pulse generator 2 and an input 3 of which has a transmitter for recording the speed of rotation of the axis of the internal combustion engine. The transmitter is designed as an induction transmitter 5 and is electromagnetically coupled to the motor 1 along its axis 4. It is connected to the output 6 of the pulse generator 2 by the input level selector input 8 of the burner level. At the output of the selector 7 there are inputs 9 and 10 for the control unit 11 for controlling the operation of the internal combustion engine 1 and the control unit 12 for the unit. The output 13 of the control unit 11 is connected to the ignition device 14 of the motor 1, the shaft 4 of the motor 1. Its igniter 14 and its alternator 15 are kinematically connected to each other. The output 6 of the pulse generator 2 is connected to a standard number of electrical pulse emitting units 18 and an electrical pulse train unit 19 with inputs 16 and 17, respectively, and the number of electrical pulses in . A clock generator 23 is connected to select inputs 7, control unit 12 and unit 18 for further inputs 20, 21 and 22, respectively. The outputs of the units 18 and 19 of the control unit 12 are connected by means of the inputs 24, 25 and 26, respectively, which produce a difference between two adjacent pulse sequences. The input of the unit 19 is connected to the output of the control unit 12. The output of the unit 27 is connected to the input 30 of the unit 29 which registers the measurement results.

In the case of measuring the dependence of the power of the combustion engine 1 on the speed of the engine 1, the apparatus for measuring the power of the internal combustion engine 1 further comprises 31 addition units with which two adjacent pulse sequences are added (see Figure 2). The input of the addition unit 31 is connected to the outputs of the control units 12 and 18 respectively. The other two inputs 35 and 36 of the unit 29 are connected to the outputs of the control unit 12 and the addition unit 31.

In one embodiment of the apparatus for measuring the power of an internal combustion engine (see fig

3 and 4), the actuator for transmitting the rotational speed of the shaft 4 of the internal combustion engine 1 uses a system of the internal combustion engine 1 which transmits the angular position information of the internal axis of the internal combustion engine 1, which is an AC generator 15. The input 3 of the pulse generator 2 is connected to the output of the alternator 15.

In another embodiment (Figures 5 and 6) of the internal combustion engine 1, the ignition device 14 is used as a system for carrying this information about the angular position of the axis 4 of the internal combustion engine. The input 3 of the pulse generator 2 is then located directly at the outlet of this ignition device 14.

The 18 units emitting a standard number of electrical pulses (Figures 1, 2, 3, 4, 5 and 6) are connected in series with the following elements: 37 flip-flops (Fig. 7), 39 at its 38 inputs OR gate 40, AND gate 40, the output of which is also the output of unit 18 (Figures 1, 2, 3, 4, 5 and 6) and 42 counters (Fig. 7) for its 43 inputs The OR gate 39 is connected, as well as the decoding circuit 44 which is connected to the IN port 45 of the OR gate 39 and can be used to set the initial state by inserting a second push button 47 of the latter.

The electrical pulse train unit 19 (Figures 1, 2, 3, 4, 5, and 6) has 48 flip-flops (Fig. 8), one of its 49 outputs having 53, 54 and 55 AND gates, respectively. It has inputs 50, 51 and 52 and 57 pulse generator inputs 56, and other 58 outputs 62, 63, and 64 gates 59, 60 and 61 and 66 pulse generator inputs 65. AND gates 54 and 62 are connected to another input OR gate 69. The 70 gs 71 inputs of the AND gates 55 and 64 have an additional 72 gate. Frequency divider input 74 and counter 76 input 75 are connected to the AND gate 63 output, and the AND port 53 output is connected to a further frequency divider input and counter 80 input. Frequency splitters 74 and 78 are connected to counters 81 and 82, respectively. The counters 81 and 82 are connected to the other AND gates 64 and 55 with other inputs 83 and 84, respectively. The counters 81 and 76 are connected to the pulse generator output 57 with inputs 85 and 86, and the counters 80 and 82 are connected to the pulse generator output 66 with inputs 87 and 88. Counter 76 and 80 are connected to additional inputs 89 and 90 to the outputs of AND gates 54 and 62, respectively. The ORs 93 and 92 are connected to the outputs of the counters 76 and 80 and the ORs 96 and 94 to the outputs of the counters 81 and 82 respectively. At the output of OR 96, an input 97 of a summing circuit 98 is disposed. The output of the OR gate 93 is connected to the input 99 of the feedback counter 100, and at the output of the summing circuit 98 an additional input 101 of the counter 102 is disposed. The other input 103 of the feedback counter 102 and the input 104 of the flip flop 105 are connected to the output of the AND gate 72. The output of the AND gate 107 is connected to the output of the flip-flop 105 and the remaining input 103 of the feedback counter 102 to the output of the AND gate 107. A generator is connected to the inputs 109, 110, 111 of the AND gates 53, 63 and 107 as well as the inputs 112 of the AND gate 113 for 114 hours, respectively. Finally, the input 115 of the feedback counter 100 is connected to the output of the AND gate 113. The AND gate 72 and the flip-flop inputs 116 and 117 are interconnected and form the unit 19 (Figures 1, 2, 3, 4, 5 and 6). The AND gates 72 and 113 with inputs 118 and 119 (Fig. 8) and pulse generator inputs 121 121 are also interconnected and form the input of unit 19 (1, 2,

3, 4, 5 and 6). The output of pulse generator 121 (Fig. 8) is provided with input 122 of OR 69. At the outputs of the feedback counters 100 and 102, decoding circuits 123 and 126 respectively. 124 inputs are led. At the outputs of the decoding circuits 125 and 126, pulse generators 129 and 130 are provided with inputs 127 and 128, respectively. The pulse generator output 129 is connected to the other input of the OR gate 69 and the additional 132 inputs of the AND gate 133, and the pulse generator output 130 is connected to the other 134 inputs of the flip flop 105 and ^{1 to} the 135 inputs of the AND gate 133. The output of the AND gate 133 is led to 136 flip-flop inputs 136. With the output of the flip-flop 137, the AND gates 62, 107, 64, 55 and 54 are connected to additional inputs 138, 139, 140, 141 and 142, respectively.

The operation of the device for measuring the power of the internal combustion engine 1 is as follows.

The transducer (Fig. 1) for rotating the shaft 4 of the internal combustion engine 1, which is itself known as an induction transmitter 5, produces signals. Their frequency is proportional to the speed of rotation of the shaft 4 of the internal combustion engine 1. These signals are applied to the input 3 of the electrical pulse generator 2. The latter, according to the signals, produces pulses of standardized amplitude and duration as shown in Fig. 9a. The pulse 143 pulses-4180938 are provided at a plurality of selector inputs 8 of the rotation speed level (Fig. 1) and 16 inputs of unit 18. This unit, which receives pulses from the clock generator 23 at 20 and 22 inputs, emits a standard number of electrical pulses.

As soon as the axis 4 of the internal combustion engine 1 reaches a certain predetermined speed at start, the selector 7 gives a signal to the input 10 of the control unit 12 and the pulse of the clock generator 23 to the input 21 of the control unit 12. In addition, the control unit 12 outputs a series of pulses in which the pulses 144 shown in Fig. 9b are located at defined time intervals Δτ. These pulse sequences are on the 24 inputs (27) of the unit 27, which determine the difference between the two adjacent pulse series, and on the 28 inputs of the 19 units producing the electrical pulse series.

In the 19 units, period periods are defined such that the unit 19 produces a series of 145 pulses proportional to the length of each period, comprising pulses m, n ₂ , n ₃ , n ₃ , n ₃ and n ₆ , and the lengths of these periods over the time interval Δτ within, the period time is proportional to the portions Δΐι, Δί2, Pass ₃ , Δΐί, Δtg and Δte, both at the beginning and at the end of the time interval Δτ (see Figures 9 b, c, and d).

When measuring the periods ti, Δί ₂ , At ₃ , Δί4, Δίδ, Δίβ, the degree of division always varies according to the required measurement accuracy, and for 143 pulses from the 2 pulse generators (Fig. 1 a) ) is equal to a certain portion of its pepper cycle, such as 0.1, regardless of engine speed 1.

For the output of a standard number of electrical impulses defined by the unit 18, the number of pulses 143 (Fig. 9a) emitted by the pulse generator 2 and appearing in the time interval Δτ (Fig. 9b) is multiplied by the number Δΐι, At ₂ , At ₃ , Δί4, Δΐδ and Δ te (Fig. 9c) are inversely proportional to the splitting value, that is to say 10, and the pulses are then displayed on the 25 inputs of the 27 units producing the difference between two adjacent pulse sequences.

The 27 units of the two pulse series are extracted from a number of pulses which is proportional fits into the whole periods, and the first and second Δτ interval (Figure 9c) Ati, At _2, At _3, Ati, At _3, Atg period sections. This difference, which determines the power of the motor 1, is given to the unit 29 which records the result of the measurement.

When measuring the period periods Atj, At ₂ , At ₃ , At4, Δίδ Δίβ (Fig. 9c), the dividing value and the time interval Δτ are chosen taking into account the required measurement accuracy and the dependence on power and acceleration: the result of the performance measurement is, for example, in horsepower.

From the output of the selector 7 to the signal given to the input 9 of the control unit 11, the internal combustion engine is brought to a predetermined operating mode by actuating the ignition device 14 when a certain speed is reached.

When measuring the dependence of the power of the internal combustion engine 1 on the engine speed, the device for measuring the power of the internal combustion engine 1 is supplemented with the addition unit 31 (Figures 2, 4 and 6), thus adding two adjacent pulse sequences. The signals of the control unit 12, the units 18 and 19 are then output to the input unit 32, 33, 34.

In this mode, the apparatus operates in a manner similar to the measurement of the effective power, except that two adjacent pulse sequences are subtracted in the 27 units. The number of pulses is then proportional to the pulse-forming pulse periods of ₂ , taking into account the periods Δΐι, At ₂ , At ₃ , At ₁ , At ₅ , Δίβ (Fig. 9 c), which are in the time interval Δτ (Fig. 9 b). In unit 31 (Figures 2, 4 and 6), these pulse sequences are summed.

The result of subtracting 27 units proportional to the power of the internal combustion engine 1 and adding 31 units! The result of the measurement, which is proportional to the average rotation speed of the shaft of the motor 1 during the measurement time, is transmitted to the unit 29 for recording the measurement results. This is controlled by the signal given to the input 24 and the control unit 12 of the unit,

The 18 units emitting the standard number of electrical pulses (Figures 1, 2, 3, 4, 5, and 6) operate as follows.

The push button 47 (Fig. 7) is used to reset the flip flop 37 and counter 42 via the OR gate 39 and inputs 38 and 43 respectively. The flip-flop 37 then gives the AND gate 40 a prohibit signal. When the 143 pulses (Fig. 9a) from pulse generator 2 (Figures 1, 2, 3, 4, 5 and 6) appear on input 16, the state of flip-flop 37 (Fig. 7) changes and, in the meantime, pulses of the clock generator 23 (FIGS. 1, 2, 3, 4, 5, 6) applied to the input 22 of the AND gate 40, passing through the AND gate 40 from the output 41 to the counter 42. come. Simultaneously, these pulses emitted at output 41, i.e. the output of unit 18, also appear at input 25 of unit 27.

When the counter 42 (FIG. 7) has accumulated a certain number of pulses (e. G., Ten), the decoding circuit 44 is actuated and drives the flip-flop 37 through its OR 39 gate. As a result, the pulses of the clock generator 23 at the input 22 of the AND gate 40 (Figures 1, 2, 3, 4, 5 and 6) can no longer pass through the AND gate 40 to the counter 42. Subsequent pulses 143 (Fig. 9a) from pulse generator 2 repeat this process in unit 18.

Thus, in unit 18, a plurality of pulses from pulse generator 2; pulse

-511, the number of which is determined by the state of the decoding circuit 44 (FIG. 7) (thus, in the exemplary case, the clock generator 23 will emit 10 pulses).

The operation of the 19 pulses generating units is as follows.

10 is a pulse 143 of period 143), T ₂ , T ₃ , T ₄ , Tr ₁ , T _c , T ₇ shown in FIG. 10a from the output 6 (1, 2, 3, 4, 5, 6) of the pulse generator 2. 4) are inserted into the 117 inputs of the flip-flop 48 (FIG. 8). Now, the state of the flip-flop 48 changes with each 143 pulses (Fig. 10a). The outputs 49 and 58 of the flip-flop 48 appear in the form of 146 pulse sequences (Fig. 10b) and 147 pulse sequences (Fig. 10c) applied to the 50 inputs of the AND gate 53 (Fig. 8) and 60, respectively. to your input. At the other inputs 109 and 110 of the AND gates 53 and 63, respectively, pulses of the clock generator 114 are provided. Thus, the pulse sequences 148 (Fig. 10 d) from the clock generator 114 in the periods Ti, T ₃ , T ₃ , T ₇ (Fig. 10 a) and the pulse sequences 149 from the same clock generator 114 (Fig. 10 e) are the T ₂ , T ₄ , In periods of perβ, the counters 76 and 80 are transmitted through the AND gates 63 and 53 to the inputs 75 and 79, respectively, and the frequency divisions 74 and 78 to the counters 81 and 82 respectively. The contents of the counters 76, 81, and 80, 82 are erased by the pulse generators 150 and 151 (Figures 10 f and 10 g, respectively) emitted by the pulse generators 57 and 66, so that deletion always occurs at the end of the following period. .

When the pulse train 152 (FIG. 10h) emitted by the control unit 12 (FIGS. 1, 2, 3, 4, 5, 6) during period At appears, pulse generator 121 (FIG. 8) at the end of the time interval (Fig. 10h), it generates 153 pulses (Fig. 10i) which passes through the OR gate 69 (Fig. 8) to the 67 gates of the AND gate 54 and the 68 gates of the AND gate 62. Pulses 146 (Fig. 10b) and Pulses 147 (Fig. 10c) pass from the outputs 58 and 49 of the flip flop 48 to the other inputs 51 and 59 of the AND gates 54 and 62, respectively. When the pulses 153 (Fig. 10i) appear simultaneously with the pulses 146 (Fig. 10b) or the pulses 147 (Fig. 10c), the AND gate 54 (Fig. 8) or the AND gate 62 is The contents of one of the counters 80 (for example, the counter 80) are transferred through the OR 93 to the counter 100. On the other hand, the control unit 12 (Figures 1, 2, 3, 4, 5 and 6), by its 154 pulse series (Fig. 10j), enables the AND gate 113 (Fig. 8), which thus pulses the clock generator 114 which are now fed to the 115 inputs of the counter 100.

If the content of the counter 100 is then zero, the pulse generator 129 generates a pulse on the signal from the decoder circuit 125 which transmits the contents of the other counter 76 via the AND gates 69 and 54 to the counter 100, again subtracting, until it reaches zero. Thus, the output of the pulse generator 129 is represented by the pulses 155 shown in FIG. 10k having a T ₂ . The periods T ₃ , T ₄ (Fig. 10k) are the pulse generators 2 (1, 2, 3, 4,

5, 6) are equal to the T ₂ , T ₃ , T ₄ periods of the 143 pulses and the beginning of the T ₂ period (Fig. 10 k) coincides with the end of the time interval Δt (Fig. 10 h). These pulses 155 (Fig. 10k) are passed to input 132 (Fig. 8) of AND gate 133.

When the signals appear on the inputs 116 and 118 of the AND gate 72, the AND gate 72 permits pulses 156 (Fig. 101). When these pulses 156 are simultaneously displayed with the signals at the outputs 49, 58 of the flip-flop 48 (FIG. 8), which are transmitted through AND gates 55 and 64, the pulses 156 (FIG. the contents of one of the counters (such as the counter 81) are transferred to the summing circuit 98 via the 96 gates.

The state of the counters 81 and 82 will not coincide with the state of the counters 76 and 80 only if an appropriate division ratio is set on the frequency divider 74 and 78, e.g. 0.1 at. Simultaneously with the transfer of the duration of the counters 81 and 82 to the summing circuit 98, the state of the summing circuit 98 is itself transferred to the feedback counter 102. As a result, the pulses of the generator 114 are transmitted through the AND gate 107 to the input 108 of the feedback counter 102. When the content of the feedback counter 102 becomes zero, the decoder circuit 126 starts to operate and actuates pulse generator 130. The pulse generator 130 sets the flipflop 105 to such a state that the pulses of the clock generator 114 cannot reach the feedback counter 102. When the subsequent signal appears at the input 116, the duration of the other counter 82 is transferred to the summing circuit 98, otherwise the processes are performed as described above.

Consequently, the pulses of the pulse generator 130 are provided with the pulses produced and shown in Fig. 10m, and the 143 pulses of the pulse generator 2 (Figures 1, 2, 3, 4, 5, 6) (Fig. 10a). ) 0.1 T ₂ as shown in Fig. 10 m; 0.1 (T2 + T3); 0.1 (Ti + T ₂ + T ₃ ), etc. they will be shifted with time.

When the pulses produced by the pulse generators 129 and 130 (Fig. 8) appear simultaneously, the AND gate 133 actuates the flip-flop 137 which sends a prohibition signal to the AND gates 62, 107, 64, 55, 54, and this will end the measurement process. Then, the number of pulses 157 (Fig. 10m) appearing at the output of the pulse generator 130 (Fig. 8) is proportional to the predetermined division ratio, with the period period AT shown in Fig. 10m. These pulses 157 (Fig. 10m) are then passed to the inputs 26 (1, 2, 3, 4,

5, 6).

The apparatus for measuring the power of internal combustion engines according to the invention can be put into operation more quickly by using a system of the internal combustion engine 1 which is the transducer for the rotation speed of the shaft 4 of the motor 1.

Provides information on the angular position of the 4 axes of the -613 combustion engine 1.

As shown in Figures 3, 4, 5, 6 as one of the systems of the internal combustion engine 1 which provides information on the angular position of the axis 4 of the internal combustion engine 1, the alternator 15 or the alternator 15 (Figures 3, 4) or the ignition device 14 (Figures 5, 6) is used. In this case, the operation of the apparatus for measuring the power of the internal combustion engine 1 is described above.

The present invention permits the use of less skilled service personnel.

In addition, the apparatus constructed according to the invention has a smaller weight and relatively smaller dimensions, which allows operative application of the apparatus for measuring the power of internal combustion engines.

Claims (5)

PATENT CLAIMS An apparatus for measuring the power of an internal combustion engine, the transducers of which comprise the axis of rotation of the internal combustion engine a. thereby rotating in series the difference between the speed selector of the rotary speed level selector of the internal combustion engine and the control unit connected to the operation mode of the internal combustion engine 30, thereby serially switching between the control unit and the connected clock generator and two successive pulse sequences a result recording unit, characterized in that it has a standard number of electric pulse emitting units (18), a clock generator 40 (23) connected to its input (22), and an electrical pulse generator (2) output to the other input (16). and an output (25) of two successive pulse train units (27) connected to its output, and an electrical pulse train unit (19), each pulse train having ban (145) is the number of pulses (ni, n ₂ , n ₃ , n ₄ , nr 'ne) within the time interval (Δτ) defined by the control unit (12) of the unit with a portion of the period 50 (Δίι, Δΐ ₂ , Δί3, Δίί , Δί ₅ , Δΐβ) proportional, the input (17) of the electrical pulse generating unit (19) is connected to the output (6) of the electrical pulse generator (2), the other input (28) is connected to the output of the control unit (12) connected to the other input (26) of the difference generating unit (27) between two successive pulse sequences, and the input (20) of the rotation speed level selector (7) for selecting the rotation speed of the shaft (4) of the internal combustion engine (1); . (Priority: January 11, 1978) An embodiment of the apparatus according to claim 1, characterized in that a summing unit (31) is provided for summing the two successive pulse sequences, one of its inputs (33) connected to the output of the standard number of electrical pulse emitting units (18). 32) connected to the output of the control unit 12 of the apparatus and the third input 34 of the apparatus to the output of the electrical pulse generating unit 19 and finally connected to the input of the measurement result recording unit 29; its input (35) is connected to the device control unit (12). (Priority: January 11, 1978) Embodiment according to claim 1 or 2, characterized in that the transmitting speed of rotation speed of the shaft (4) of the internal combustion engine (1) comprises a system for transmitting information about the respective angular position of the shaft (4) of the internal combustion engine. (Priority: 11/11/1977) Apparatus according to claim 3, characterized in that the system for transmitting information relating to the angular position of the axis (4) of the internal combustion engine (15) is an alternating current generator (15) of the internal combustion engine (1) under investigation. (Priority: 11/11/1977) An embodiment of the apparatus according to claim 3, characterized in that the system for transmitting information relating to the angular position of the shaft (4) of the internal combustion engine (1) is the ignition structure (14) of the internal combustion engine (1).