SU1620877A1 - Bed for testing cylinder blocks of i.c.engines - Google Patents

Abstract

The invention speeds up fatigue testing by increasing the frequency of formation of a periodic load and automating the tuning of the stand. The load is shaped by it.

Description

The invention relates to mechanical engineering, in particular to devices for testing the fatigue of sealed cylinders, and can be used to test the fatigue strength of cylinder blocks of an internal combustion engine (ICE).

The purpose of the invention is to increase productivity by increasing the cylinder loading frequency and automatically adjusting the loading parameters.

FIG. 1 is a diagram of the stand; in fig. 2 is a block diagram of setting phase shift angles; in fig. 3 is a block diagram for setting the pulse duration; in fig. 4 shows a block diagram for determining the duration of the leading and trailing edges of a pressure pulse; in fig. 5 is a diagram of a proportional control signal generation unit; in fig. 6 is a diagram of a matching unit.

The bench contains technological sleeve 2, block cover 3 and piston 4 with rod 5 connected kinematically connected with technological shaft 6, installed in test block 1 of cylinders, with sleeve 2, cover 3 and piston 4 forming a closed cavity 7. The length of rod 5 sets the position of the piston 4, corresponding to the moment of reaching the maximum pressure in each cylinder when the engine is running.

The closed cavity 7 is connected to the output channel 8 of the relay electro-hydraulic converter 9, the distribution spool of which is two-edged and occupies only two stable extreme positions. When the spool is switched, the output channel 8 commutes with the pressure 10 or drain 11 channels of the electro-hydraulic converter 9.

In the discharge and discharge channels of each electro-hydraulic converter 9, chokes 12 and 13 are installed with remote proportional control.

The throttles 12, 13 provide the opening of the throttle slit, proportional to the electrical control signal, and are embedded directly into the housing of the electro-hydraulic converter

9, jointly forming a monoblock 14, which is mounted directly on the cover 3 of the block of the tested cylinder block 1 in order to maximally reduce the volume of the output channel 8 of the converter 9.

Pump station 15 contains a pump of adjustable capacity 16, a pneumo-hydraulic accumulator 17 and a safety valve 18 installed in a pressure line 19. and a retaining valve 20 installed in a drain line 21. Both valves 18 and 20 are made with remote proportional control. The safety valve 18 limits the maximum pressure in

pressure line 19, and retaining valve 20 & provides a minimum value of pressure in the drain line 21. The setting of valves 18 and 20 is set remotely by electrical signals

management Liquid batteries 22 are installed in the pressure line 19 directly next to each monoblock 14. Driver unit 23 contains a generator of 24 square-shaped clock pulses and adjustable frequency. The generator is connected to the block 25 setting the phase angle and the first inputs of the blocks 26-26 setting the pulse width, the number of which is equal to the number of loading channels. The outputs of the phase angle setting unit 25 and the pulse duration setting units are connected to the inputs of the control signal drivers 29-31, the outputs of which are connected to the second inputs of blocks 26-28 and are the outputs of the electronic master unit 23. The outputs of block 23 are connected to the control circuits electro-hydraulic converters 9 through power amplifiers 32-34.

The sets 35, 36 of setting the maximum and minimum values of the pressure pulse, respectively, are connected to the block 37 for determining the magnitude of the pressure change. The output of the latter is connected to the first inputs of the two blocks 38 and 39 of the formation of proportional control signals, the second inputs of which are connected to the block 40 for determining the duration of the leading and trailing edges of the pressure pulse, the input of which, in turn, is connected to the output of the imaging unit 31. The outputs of the blocks 38 and 39 connected via power amplifiers 41 and 42 to the control circuits of chokes 12 and 13. The outputs of blocks 35 and 36 are connected via matching blocks 43 and 44 to the control circuits of safety 18 and retaining 20 pumping valves with stations 15. Blocks 35 and 36, respectively, setting the maximum and minimum values of the pressure pulse are made in the form of blocks for manually entering a digital code corresponding to the selected values of the parameters of the pressure pulse. In the cavity 7, a load sensor 45 is installed, made in the form of a pressure sensor, the output of which through an amplifier is connected to the measuring and recording unit 46.

The block 25 provides the setting of the phase offset angle of the control pulses on different charging channels in the range from 0 to 360 ° relative to the reference channel and includes (Fig. 2) a three-decade binary-decimal pulse counter 47 with a given conversion factor of 360. the counter 47 is connected through a three-decade decoder 48 to the inputs of a group 49 of three-decade switches, and the outputs of each of the decades are connected to the corresponding logic elements And 50, 51 and 52, the outputs of which are the output channels of the block 25. The key switches of group 49 are one less than the number of loading channels, and the output of the first support channel of block 25 is aligned with the output of the last bit of counter 47.

Blocks 26,27 and 28 (Fig. 3) provide for the formation of a control pulse after a predetermined period of time after the arrival of the control signal at the first input of block 26, the latter includes an AND 53 logic element associated with the input of a three-decade binary decimal counter 54, the outputs of which connected to a three-decoder decoder 55, and the latter to a three-decade switch 56. The output

5 each decade of the switch 56 is connected to the logical element AND 57, the output of which is the output of each of the blocks 26, 27 and 28 and connected to the reset input of the counter 54.

0 Shapers 29, 30 and 31 are made in the form of RS-flip-flops.

Block 40 (Fig. 4) digitally generates values corresponding to the durations of the front and rear, respectively.

5 fronts of pressure pulse, set by parameters of electrical signals for controlling electro-hydraulic converters 9. Block 40 includes two logic elements, And 58 and 59, quartz

0 generator 60 and two counters 61 and 62 pulses. The first inputs of the AND 58 logic elements are combined with the input of the block 40. The second inputs of the AND 58 and 59 logic elements are connected to the generator 60, and their outputs are connected to the inputs of the counters 61 and 62. The input of the synchronization generator 63 is combined with the input of the block 40. The driver 63 made as an element of fixing the change in the signal from the value O to 1 and the single vibrator.

Blocks 38 and 39 (Fig. 5) are made in the form of a two-input converter 64 connected by an information channel to memory block 65 and digital to analog converters 66. Block 65 is connected to task block 67, and the control channels of all blocks are connected to control block 68, the input of which is connected to the output of the block 40. The matching blocks 43 and 44 (Fig. 6) are made in the form of a digital-to-analog converter 69, an amplifier 70, an input resistor 71 and feedback resistors 72 and 73.

The stand works as follows.

5 The signals U ™ from the output of the generator 24 are fed to the input of the block 25, the output of the decoder 48 of which generates a signal in decimal form about the number of pulses received at the input of the counter 47. When the number of clock pulses specified by N at the outputs of the elements 50, 51 and 52 signals G are generated, which are output signals UyC | block 25. Since the conversion factor of the counter 47,

5 is assumed to be 360. After every 360 pulses at the output of the control channels, a signal is formed with a period equal to 360 periods of clock pulses from the genre of the generator. Uyet signal on the first reference

the loading channel is formed by the high-order discharge of counter 47 with the arrival of 360 clock pulses. In this case, the signals Uyci along the remaining channels are shifted relative to the reference one by the number of clock pulses specified for each channel. The signals from the outputs of block 25 are fed to the first inputs of the corresponding blocks 29, 30 and 31, at the outputs of which signals 1 are generated that allow the passage of clock pulses to the inputs of counters 54 of blocks 26,27 and 28 of setting the control pulse width. The control pulse duration is set using the switch 56 according to the number of n clock pulses. Output signals UyC | from the outputs of the blocks 26, 27 and 28 provides for resetting the triggers of blocks 29.30 and 31, respectively. As a result, at the outputs of blocks 29, 30 and 31, square-shaped signals are formed with a period of 360 clock pulses, the phases of which are shifted relative to the reference channel by given Ni, and the signal durations are given by the number n.

The signals Ui are the output signals of block 23 and are fed through amplifiers 32, 33 and 34 into the control circuit of each electro-hydraulic converter 9. At a control signal value equal to level 1, the transducer spool 9 connects the output channel 8 to the pressure channel 10, and when changing the control signal to the level O, the spool switches to another extreme position, switching the output channel 8 to the drain channel 11. As the pressure and drain channels of the electro-hydraulic converter through the throttles 1 2 and 13 are connected, respectively, to the pressure 19 and the drain 21 lines of the pumping station 15, then during the periodic movement of the valve of the electro-hydraulic converter 9 in the closed cavity 7, pressure pulses are generated. The electro-hydraulic control system of the spool in the converter is made relay with an additional correction device, which ensures the switching of the spool in a short period of time, and the magnitude of the displacement of the spool provides the area of the working windows of the spool pair of the converter, which does not substantially resist the flow of the working fluid.

The shape of the pressure pulses is determined by the compressibility characteristics of the working fluid and the character is changed and

flow rate of this fluid in the output channel of the electro-hydraulic converter. The flow rate of the working fluid in the output channel of the electro-hydraulic

The converter is determined by opening the throttles of the throttles 12.13 with remote proportional control and the pressure drop across them. As the pressure changes in a closed cavity during the formation of the leading or trailing edge of the pressure pulse, the pressure drop across the corresponding gap decreases and the flow rate of the fluid in the output channel 8 also decreases.

5 Thus, with periodic relay switching of the spool of the electro-hydraulic converter 9 in the closed cavity 7, pressure-shaped pulses are formed. Controlling the opening of the throttles of the throttles 12 and 13, the opening pressure of the safety valves 18 and the retaining 20 pumping station 15 and the ratio of the durations of the front and rear edges

5 of the pressure pulse provides the ability to control the shape of the pressure pulse approximated to the shape of the indicator chart of the engine.

Adjusting the throttles 12, 13 and valves 18, 20 with remote proportional control is carried out by electrical control signals generated by the second part of the electronic driver unit 23. The required devices for the maximum and minimum pressure of the generated pulses are set by two devices 35 and 36. At the outputs of these blocks, signals are generated in digital form about the values of specified pressures, each of which is fed to the input of a digital-to-analog converter 69 of the corresponding matching unit 43 and 44. With the arrival of the synchronization pulse 11is, each digital-to-analog converter converts a digital code into a proportional electrical signal UK an output that is supplied to a power amplifier 70 tuned to a specific gain factor by

0 voltage

For a power amplifier that generates a control signal for the retaining valve 20, a voltage gain equal to is adjusted.

5 Therefore, its electric output signal Ukpod adjusts the retaining valve to the pressure Ppod, equal to the minimum pressure pulse Pmin. With the adopted stand operation scheme, the pressure in the closed cavity during the formation of the trailing edge of the pressure pulse decreases to the pressure Ppod. maintained in the drain line 21, thereby setting the desired value of the minimum pulse pressure RMHH.

For the power amplifier, which generates the control signal for the safety valve 18, the gain is adjusted to 25-1.3 in voltage. Therefore, its electrical output signal UK pr sets the safety valve to a pressure Pdr greater than the maximum pulse pressure Pmax in 1.25-1.3 times. This provides a pressure drop across the throttles of the throttles 12 during the formation of the leading edge of the pressure pulse, giving it the necessary slope.

From the outputs of blocks 35 and 36, signals in digital form about specified values of the maximum and minimum pressure of the pulse are fed to the inputs of the block 37, which with the arrival of the synchronization pulse ensures the calculation of the difference between the digital codes supplied to its inputs, i.e. differences are the maximum and minimum pulse pressures.

At the same time, block 40 generates digital signals that determine the duration of the front gate and the rear T3 front of the pressure pulse. The input of block 40 is supplied with a signal from the output of one of the control signal drivers, for example, the signal Ui, via the first loading channel, which is fed to the first inputs of logic gates And 58 and 59. The second inputs of these logic gates are fed from a crystal oscillator 60 with a frequency fs of 0.1-0.5 MHz, characterized by high frequency stability. When the value of the signal Ui is equal to 1, pulses of the crystal oscillator are transmitted to the output of the logic element And 58, generating a signal UTTI. When the signal value Ui is equal to 0, the quartz oscillator pulses, forming the signal Ur3, are transmitted from the output of the AND 59 logic element.

When the signal value Ui is equal to 1, the pulses from the generator arrive at the input of the counter 61 through the element And 58, form the signal hn, and otherwise - to the input of the counter 62 through the element 59, form the signal T3, reset the counters 61 and 62 into the original the state is effected by the synchronization driver 63.

The signals NTn and NTS from the outputs of the counters 61 and 62 are fed to the first inputs of the 38 m 39 blocks, respectively, and the second inputs of the blocks 38 and 39 receive a signal from the block 37.

Block 37 provides the calculation according to the program laid down in memory block 55 of the magnitude of the opening of throttle slits of throttles 12 and 13. Moreover, since all channels

5 loading, pressure pulses of the same form are formed, then the control circuit of all the throttles 12 installed in the pressure channels of the monoblocks 14 is given a signal Unn, which determines the opening of the throttles during the formation of the leading edge of the pressure pulse, and the control circuits of all the throttles 13 installed in the drain monoblock channels 14 is the Una signal, which specifies the opening of the chokes during the formation of the trailing edge of the pressure pulse.

After changing the loading parameters, the system generates proportional signals Un to control throttles 12 and 13 for several periods T formed by the cyclic load bench, gradually changing them from the value determined by the set of previous loading parameters to a new one. When forming the trailing edge of the pressure pulse in

5 of each closed cavity, the spool of the electro-hydraulic converter 9 closes the pressure channel 10, and the energy of the working fluid supplied by the pump to the pressure line 19 is accumulated in

0 in battery 22. In the next phase of operation, this energy is used to form the leading edge of a pressure pulse in a closed cavity, right next to which this battery is located. The completion of batteries with liquid batteries ensures their high speed. The battery 17, installed in the discharge line of the pumping station 15, serves to smooth the pressure pulsations in this line and is made pneumatichydraulic. The sensors 45 provide continuous measurement of the loading parameters of the test object, and the registration of the sensor signals of the sensor 5 is unit 46.

The proposed stand reproduces the loads that are identical to the operational ones with a high loading frequency, which speeds up the resource testing of the internal combustion engine components. At the same time, a significant increase in the frequency of loading on this stand is achieved through the joint use of relay electro-hydraulic converters and chokes with.

5 remote proportional control, controlled by a special master device.

Claims (3)

Claim 1. Test stand for cylinder blocks of an internal combustion engine, comprising a pumping station, made in the form of a pump, a working fluid accumulator connected to a pump, retaining and safety valves, connected to a pumping station by electro-hydraulic converters according to the number of load channels , power amplifiers for the number of electro-hydraulic converters, load sensors for the number of loading channels associated with the measurement unit, and a master unit equipped with a unit for specifying angles phase, blocks of setting the pulse duration and drivers of control signals, the number of the latter two is determined by the number of loading channels, and a clock pulse generator whose output is connected to the input of the phase shift angle setting block and the first input of each pulse duration setting block phase shift and the output of the corresponding pulse width setting unit are connected respectively to the first and second inputs of the corresponding control drivers, the outputs of which They are combined with the outputs of the task block and connected each through a power amplifier to the control circuit of one electro-hydraulic converter, characterized in that, in order to improve performance, the retaining and safety valves of the pumping station are made with remote proportional control, the electro-hydraulic converters are relay and each of them is equipped two throttles with remote proportional control, installed in its pressure and drain channels, and the task block with abnormally sets the maximum and minimum values of the pressure pulse, the pressure change range with two inputs, the front and rear edges of the pressure pulse with two outputs, two proportional control signals with two inputs each, the first and second additional power amplifiers and the first and second matching blocks, the control circuits of the retaining and safety valves of the pumping station, respectively, through the first and The second matching blocks are connected to the outputs of the maximum and minimum pressure pulse sets, respectively, the control circuit of each throttle with remote proportional control, installed in the pressure channel of the electro-hydraulic converter, is connected via the first additional power amplifier to the output of the first proportional control signal generation unit, and the control circuit each drossel with remote proportional control, installed in the drain channel e electro-hydraulic converter connected via a second additional amplifier 0 power to the output of the second block forming a proportional control signal, with the first inputs of the block forming the proportional control signals connected to the output of the block 5 determine the range of the pressure change, and their second inputs - to the outputs of the block determining the duration of the leading and trailing edges of the pressure pulse, the input of which, in turn, is connected to the output of one of the control signal formers. 2. A stand according to claim 1, characterized in that the block for determining the duration of the leading and trailing edges of the pressure pulse comprises a high-frequency crystal oscillator, the first and second logic elements AND, the first and second pulse counters and the synchronization pulse driver, and the determination unit input the duration of the leading and trailing edges of the pressure pulse is combined with the input of the synchronization pulse shaper, the forward input of the first logic element And and the inverting input 5 of the second logic element I, the second inputs of which are connected to the output of the high-frequency crystal oscillator, and their outputs to the information inputs of pulse counters, and the installation inputs of the counters are connected to the output of the pulse driver, and the outputs of the first and second counters are combined respectively with the first and second the outputs of the block determining the duration of the front and rear fronts. 3. A stand according to claim 1, characterized in that the proportional control signal generation unit comprises a converter with two inputs, an information channel, a memory block with an information channel and an additional input, a task unit, a digital-analog converter, each of the specified blocks provided with a control channel for connection to the control unit, the output of the task unit is connected to the auxiliary input of the memory unit, the information channels of the latter and the converter are interconnected, the output of the converter through a digital-to-analog converter is connected to the output of a proportional control signal generating unit, the first and second inputs of which are combined respectively with the first and second inputs of the converter. W 48 P Pt / t2  I Umu 4U M Fig.Z 4wy five/ 52. Uyet v Vti / f, 55 56 yt / pu and 58 59 63 Theb.4 FIG. five 61 P . I I Uuc 73 & Uh