DE2359067A1 - METHOD AND DEVICE FOR MEASURING THE FREQUENCY OF EVENTS - Google Patents

Description

Description Procedure and method for measuring the frequency of occurrence of events There are monitoring systems for monitoring the production of a Machine. For example, U.S. Patent No. 3,242,320 discloses a system in which the Number of activations of a machine measured during an entire production day will. This measurement is compared with the number of actuations that then occur if the machine was uninterrupted during the entire production day would be in operation. The purpose of the well-known system is to determine the amount of failure - or Measure dead time of the machine. The system is not set up to monitor the frequency of work, i.e. to measure the number of actuations per unit of time; in the known system the work frequency would be either 100% or 0%, depending on whether the machine is working or not. The known system is therefore not suitable for to measure the frequency of operation of a machine that operates at different frequencies.

Other monitoring systems have also been proposed, using which can be used to measure the output speed or quantity of a process the output and measurement of the feed measure or monitor leaves. These values are then compared to determine the losses in the system. Even with such a system, the frequency can vary for a relatively short time Time interval cannot be measured.

With a machine that changes with different frequency can be operated, e.g. with a manually operated plastic molding machine the operator has to perform certain functions, it is important that To be able to determine the frequency with which the machine is operated. This is It is therefore particularly important to check the efficiency of the operator to be able to. In addition, because the frequency of work of a machine is very high is often an indication of the degree of wear and tear on the machine.

The invention is accordingly as an object to provide a Process based on which the frequency of occurrence of events, in particular Measure or monitor the frequency of work of a machine or a process leaves.

To this end, a device for carrying out this method is to be specified will. The solution to this problem according to the invention is in claims 1 and 2 marked.

Appropriate further developments of the invention are based on the subclaims emerged. In a preferred development, during each acquisition or Measure the frequency of occurrence of a given number of events required time is measured and the measured time is compared with a standard time value.

The following is the invention with further advantageous details explained in more detail using schematically illustrated embodiments. In the drawings demonstrate: 1 shows a block diagram of a preferred monitoring device according to the invention, Figures 2A and 2B taken together a detailed circuit diagram of the The device according to FIG. 1, FIG. 3 shows a pulse diagram for the device according to FIG. 1, FIG. 4 shows a detailed circuit diagram of an alternative embodiment of part of the device According to FIGS. 2A and 2B, FIG. 5 shows a detailed circuit diagram of an alternative embodiment of another part of the device according to Figures 2A and 2B.

The device or the system of FIG. 1 is used in conjunction with a cyclically operated machine or a cyclically operated process whose or whose work frequency is to be monitored This can be any conventional machine or process or even one act another cyclically repeated series of events, details in in this regard do not form part of the invention. It should also be noted that the invention in the following with reference to electronic components and electrical signals is described, but also a corresponding device with flow-controlled components (fluidic technology) and corresponding signals could be used.

To obtain an indication of the frequency of activity or work a machine can either count the number of duty cycles or cycles during one Sample time interval, the amount of time between cycles, or the time to occur a certain number of cycles can be measured.

In any case, the work cycles of the machine are scanned ' will creates a standard time interval and becomes a ratio between cycles and one Time unit formed. In the embodiment of FIG. 1, the latter is Principle applied.

Figures 1 to 3 show a complete digital device or a complete digital system for monitoring the frequency of work of a Machine or process. The device comprises, see Fig. 1, a frequency selection circuit 201, which are set by hand to a working frequency by means of an adjusting knob 202 which is to be regarded as the standard or optimal frequency. The circuit 201 controls the operation of a high-precision oscillator 203 of variable frequency in such a way that that the frequency of the oscillator 203 can be adjusted by means of the adjusting knob 202. After setting the adjusting knob 202 to a selected value, this setting is made maintained while monitoring the operation of the machine.

The output of the oscillator 203 becomes a frequency divider circuit 204 and a frequency range selector switch 206, with which a lets you choose from two frequency ranges. The output of oscillator 203 is also connected via a line 205 to a sequence control and counting circuit 207, which also receives impulses according to the mode of operation of a monitored machine or a monitored process. The machine or the process is a transducer 208 is assigned to actuate once for each duty cycle will. An editing circuit 209 receives the output of the pickup 208 and provides one square pulse per duty cycle. At the output of the editing circuit 209 a pulse shaper 211 is connected, which for each of the editing circuit 209 originating pulse emits a pulse of uniform, fixed duration. The exit of the pulse shaper 211 is connected to the sequence control and counting circuit 207.

The monitoring system is activated by switching on the supply voltage and activated by actuation of a reset or start switch 212. Then, pulses from pulse shaper 211 become the counter in circuit 207 fed.

At the same time, the signal from oscillator 203 is passed through the circuit 204 and the selector switch 206 are fed to a counter 213.

When the counter in circuit 207 reaches a certain value, which is 10 cycles in the present exemplary embodiment, it sets the sequence control part of circuit 207 in operation.

The sequence control part first gives a pulse on a line 214 which resets part of the counter 213. Then the sequence control and counting circuit 207 from a pulse on line 216 which is the output a count decoder circuit 217 to a memory and frequency decoder circuit 218 transferred. The circuit 217 forms a temporary memory for the counter reading the counter 217; a signal on line 216 causes the information to be transferred from circuit 217 to permanent memory in circuit 218.

Circuit 218 actuates one of three displays 219, 220 and 221 depending on the information received from the counter 213. Another impulse on the Line 214 resets the remainder of counter 213. Finally, the sequence control and counting circuit 207 itself and forwards a new monitoring and sampling period a.

It has already been mentioned that the sequence control and counting circuit 207 counts ten work cycles of the machine or process and at the end of the tenth Cycle transfers the count of counter 213 to circuit 218. Because the frequency of the oscillator 203 at a fixed value during the sampling period of 10 cycles is held, the count of the counter 213 depends on the Time taken for the machine or process to complete ten work cycles are required.

The count of the counter 213 is therefore a measure of the frequency of work of the machine or the process. For everyone preset setting With the setting button 202 the oscillator generates ~ 203 pulses of a certain frequency and the counter 213 needs a certain period of time to reach a count, which represents 100% of the specified nominal value.

If the machine or process completes ten complete Cycles, circuit 218 speaks at the time the counter is reset 213 responds to the fact that the nominal count has been reached and is actuated the display 221. If between 90% and 100 ffi of the nominal value is reached, the Display 220 is switched on, while when less than 90% of the nominal value is reached the display 219 is turned on. This way of working has the very important advantage that the count decoder circuit and the memory circuit 218 only determine must, whether a certain count in the counter 213 has been reached; these circuits do not need to determine the exact meter reading. It's just the destination necessary whether the counter reading reaches or exceeds a certain value Has. Such a way of working simplifies the construction and the operational flow the device, which is associated with a corresponding cost saving.

The system further preferably comprises components for displaying, whether the time between successive work cycles of the machine or the Process exceeds a predetermined value. This part of the system includes a gate circuit 226 which controls the pulses taken from the machine or process via a line 227 which is connected to the output of the pulse shaper 211 is. Furthermore, a counter 228 is provided, which pulses from the counter 213 via a Line 229 receives. The pulse frequency on line 229 is a function of the Frequency of the oscillator 203. The counter 228 counts during each duty cycle of the Machine pulses and is reset at the end of each work cycle and for one new count triggered.

If the count of the counter 228 during a duty cycle of the Machine reaches a certain value, an alarm Blink generator 231 actuated, the output of which is connected to the decoder circuit 218. Preferably the blink generator and the decoder circuit are connected to one another so that the Display 219 for indicating an excessively long period of time between successive stages The machine's work cycles flashes.

For manual actuation of the display 219, a manually actuatable one is used Switch 232 is provided. There is also a manually operable switch 233 for canceling the alarm provided with which-the gate circuit 226 and the Blillkgenerator 231 after actuation of the latter are reset and with which of the counters 228 and the flashing Display 219 can be switched off. The decoder circuit 218 then holds one of the three Displays 219, 220 or 221 continue to be switched on, which means that the before actuation of the Blink generator 231 displayed information is displayed again. If either the display 221 or the display 222 switched on before triggering the blink generator 231 it remains switched on even while display 219 is flashing.

In FIGS. 2A and 2B, the system shown in FIG. 1 is shown with others Details shown. The pulse shapes shown in FIG. 3 are underlined Letters marked, which in Figures 2A and 2B at the points of the circuit appear at which the respective pulse shapes occur. As oscillator 207 any high-precision oscillator type with variable frequency is suitable; in the exemplary embodiment, a voltage-controlled oscillator is used. Means the setting button 202 is used to set a highly precise variable resistance, which is switched in such a way that the frequency-determining voltage on the The input of the oscillator can be controlled. The oscillator 203 can, for example, on a frequency between 1 KHz and 10 KHz can be set and generates an output signal P, which has a 50% duty cycle and fluctuates between 0 and 5 volts.

The output of the oscillator 205 is connected to the trigger input of a flip-flop 240 of the frequency divider circuit 204 and, to a permanent contact 241 of the frequency range selector switch 206 is connected. The output of the oscillator 203 is also connected to the sequence control and counting circuit 207 via a line 205 tied together. The flip-flop 240 is connected to a second flip-flop 242 and forms together with this a 1: 4 divider, the output Q of the second flip-flop 242 is connected to a second fixed contact 243 of the selector switch 206. When the switch 206 is in the position shown in FIG. 2A, in which the movable contact rests on the fixed contact 241, has that supplied to the counter 213 Signal the frequency of the oscillator 203, while when the moving contact is applied at the other fixed contact 243 the signal fed to the counter 213 by the The frequency of the oscillator is divided by a factor of 4.

The counter 213 comprises two components 246 and 247 which are so interconnected are connected so that they form either a 1:18 divider or a 1:36 divider. The movable contact of the switch 206 is connected to the trigger inputs of both components 246 and 247 connected, while the transfer output of the component 246 via a Line 248 is connected to an input of component 247. The delete inputs the two components 246 and 247 are connected to an input 251 via a line 249 a NAND gate 252 connected. Connections A and C of component 246 are connected to two inputs of a NAND gate 253, and the connection A of the component 247 is connected to a further input of the NAND gate 253. A fourth The input of the NAND gate 253 is optionally with the connection via a switch 255 B of the component 246 or the connection B of the component 247 can be connected. The exit of the NAND gate 253 is connected to an input of a further NAND gate 254, that with a second input 256 to one of two conductors forming the line 214 is connected, which goes off from the sequence control and counting circuit 207. Of the The output of the NAND element 254 is connected to an input of a further NAND element 257 connected, the output of which is connected to line 249 and which has a second input which has a fixed positive voltage Vcc is applied. The NAND gate 252 has a second input 258, the via a line 259, which forms the second conductor of line 214, a preparatory or receive an enable signal from the sequence control and counting circuit 207 if the Switch 255 is connected to terminal B of component 247, as shown in Fig. 2a appears for every 36, via switch 206 to components 246 and 247 incoming pulses a pulse at the output of the NAND gate 253. If the Switch 255 is connected to terminal B of component 246, a pulse appears for every 18 pulses supplied via switch 206. Provided, that the input 256 of the NAND gate 254 has a high switching value appears each of these output pulses from the NAND gate 253 also at the input 251 of the NAND gate 252 and also deletes the two components 246 and 247.

When signal D at input 258 has a high switching value, appears at the output 261 of the NAND gate 252, a pulse train C which has the same frequency as which have the impulses originating from the 1:36 divider. -For each 36 pulses on the movable Contact of the switch 206 thus appears a pulse at the input 251 and at the output 261 of the NAND gate 252. The output 261, see Fig. 2B, is connected to the trigger inputs of five components 262, 263, 264, 265 and 266 connected, which are a BCD counter (binary coded decimal counter), which form the number of the NAND gate 252 passing Impulse counts. Output signals appear while this counter is counting the pulses on conductors 268 connected to outputs A and B of components 262-266 are.

These output signals transmit information to the counter reading decoder circuit 217, which includes a temporary memory.

The pickup 208, see again FIG. 2A, also includes a switch one moving contact and two fixed contacts.

It can be mechanical, electronic, or otherwise trained Act switch. The moving contact is coupled to the machine and moves with each work cycle of the machine on the one hand fixed contact and then back on the other hand, firm contact. The stationary contacts are at the inputs of two NAND gates connected in the editing circuit 209, which are interconnected to form a flip-flop are. As a result, a square pulse is generated for each work cycle of the machine.

The output signal A of the editing circuit 209 appears on a Conductor 271, which is connected to an input of a multivibrator 272. The output signal B of the multivibrator 272 appears and persists on a conductor 273 from a pulse 270 of fixed duration or width for each duty cycle of the Machine or process. The duration or width of the pulse depends according to the values of a capacitor 274 and a resistor 276, which to the Multivibrator 272 belong.

The sequence control and counting circuit 207 receives the pulses 270, and at the trigger input of a flip-flop 281. The clear input of the flip-flop 281 is connected to the manually operated start or reset switch 212. When switch 212 is closed, the reset input is connected to ground, while when switch 212 is open, the clear input is at a positive voltage Vcc Switch 212 is short-circuited once at the start of the system start-up. This generates a pulse 277 which clears the flip-flop 281. The sloping one The edge of the next following pulse 270 from pulse shaper 211 sets the flip-flop 281, whereby the signal D receives a high switching value at its output 282. Of the Output 282 is via one conductor of line 214 to input 258 of the NAND gate 252 connected. As a result, when the switching value of signal D is high, it becomes the NAND element 252 opens and lets incoming oscillator pulses C at input 251 to the output 261 and from there to the meter.

The conductor 273 at the output of the pulse shaper is also connected to an input 286 of a NAND gate 287 connected, while the Q output 282 of the flip-flop 281 is connected to a second input 288 of the NAND gate 287. If the Output 282 has a high switching value, which occurs after the reset switch has been actuated 212 and after the occurrence of the next, machine-generated pulse, this is the case is, therefore, the machine generated pulses pass through the NAND gate 287 and appear as pulses 278 of the pulse train F on a line 291 via an inverter 280 is connected to an input 292 of a counter 293. The counter 293 is connected with its extinguishing input to output 5 of component 281. The counter 293 generates an output pulse 279 (pulse shape G) at an output terminal 294 for 10 input pulses each or 5 input pulses each from pulse shaper 211, depending on the position of a switch 295. The component 293 is a combination of one 1: 2 counter and a 1: 4 counter and has an output A, which is the output for the Series connection of the two parts or the 1:10 counter.

The output D of component 293 is assigned to the 1: 5 counter alone. Either output A or output D can be selected using switch 295. The pulse 279 at the output terminal or conductor 294 becomes the trigger input of one Flip-flops 296 are supplied, which is connected to the switch 212 with a set input is, so that the flip-flop 296 is set simultaneously with the deletion of the component 281 will. The flip-flop 296 is also connected to its clear input via a break contact switch 297 connected to a reset line 298. Switches 212 and 297 are for simultaneous actuation is mechanically coupled to one another. The output Q (pulse shape H) of the flip-flop 296 is connected to the clear inputs of six flip-flops 301, 302, 303, 304, 305 and 306 connected, which are interconnected to form a shift register are. The flip-flops are through a Reset pulse on the Line 298 cleared on the falling edge of pulse 279.

The trigger inputs of all flip-flops 301 to 306 are on together connected to the line 205, which is connected to the output of the signal P carrying the Oscillator 203 goes off. The output i of the flip-flop 301 ending the signal If is connected to the input 256 of the NAND gate 254 via one of the lines 214. The output Q of the flip-flop 303 carrying the signal K is via a line 307 connected to one input of the memory and frequency decoder circuit 218. The signal M leading output Q- of the flip-flop 305 is connected to an input of a NAND gate 308 connected. The output Q of the flip-flop carrying the signal M 306 is connected to an input of the flip-flop 301, while the output VE of flip-flop 306 is connected to line 298. The at the output of the Line 309 connected to the NAND gate 308 is connected to a further input of the counter reading decoder circuit 217 connected.

In the timing diagram of FIG. 3, the waveforms are above that with 280 with a certain time scale and the remaining pulse shapes applied underneath with a different, greatly enlarged time scale. The pulse shape -P represents the signal of oscillator 203, while pulse shape C represents the same Signal, but with a much lower frequency due to the 1:36 divider circuit with components 246 and 247 and, depending on the position of switch 206, the 1: 4 divider circuit 204 represents. The upper group of pulse shapes G to N corresponds to the lower group of pulse shapes G to N, but of course with one different time scale.

It has already been mentioned that the outputs of the flip-flops 262 to 266, which form the counter for the oscillator signal, at entrances the count decoder circuit 217 are connected. The circuit 217 comprises two NAND gates 315 and 316 to which the output of the counter is fed. the NAND gates 315 and 316 can be connected in various ways so that they respond to the achievement of each desired counter reading. In the exemplary embodiment the NAND gate 315 is connected so that it has a count of 10 001 Pulses responds while the second NAND gate 316 is connected so that it responds to a count of 11,112 oscillator pulses being reached. Each of the components 262 to 266 has four output connections A, B, C and D, which are at deleted component lead to a low switching value. A high switching value at the connection A corresponds to a count of 1. A high switching value at connection B corresponds to a count of 2. A high switching value at connection C corresponds to a count of 4. A high switching value at connection D corresponds to a count of 8.

The NAND gate 315 has two inputs, one of which is connected to the connection A of flip-flop 262 and the other of which to terminal A of the flip-flop 266 is connected. The output of NAND gate 315 is normally high Switching value, but changes to a low switching value when both inputs have a high switching value. This only occurs when the counter reads the number Reached 10 001. Similarly, the inputs of NAND gate 316 to the Output terminals A of the four components 263 to 266 and also ara the output terminal B of component 262 connected. Because of these connections, the output of the NAND gate 316 normally has a high switching value and only then takes a low Switching value on when a count of 11 112 is reached.

The outputs of the two NAND gates 315 and 316 are each with connected to the trigger input of a component 317 or a component 318. The delete inputs these components are connected to conductor 309. The outputs Q of the two Components 317 and 318 are connected to two flip-flops 321 and 322, respectively.

Each of the two flip-flops 321 and 322 is also provided with a trigger input connected to line 307. The output Q of the flip-flop 321 is connected to the inputs two logic elements 323 and 324 connected, while the output zi on the input of a NAND gate 325 is connected. The output Q of the flip-flop 322 is connected to an input of the logic element 324 while being Output Q is connected to the inputs of the two NAND gates 323 and 325. The outputs of the NANO elements 323 to 325 are connected to additional logic elements 327, 328 and 329 connected, the outputs of which show the operation of three power circuits 331, which in turn control the actuation of the three displays 219, 220 and 221 steer.

If in the embodiment shown in FIGS. 1 to 3 the switches 255 and 295 assume the position shown, are 10 work cycles of the machine or the process are counted, and during this counting of the ten work cycles the pulses from the oscillator are also counted. As mentioned earlier, form the components 246 and 247 a 1:36 counter. If the switches 255 and 295 by hand are moved to their other position finds a frequency scan for each 5 work cycles of the machine take place, and components 246 and 247 form a 1: 18 counters. Of course, you could also choose other values.

Assuming that the machine is at its nominal or optimal speed works, the counter for the oscillator pulses reaches a count of 10 000 during the time during which the machine has ten complete work cycles executes.

When the final count for the oscillator pulses is smaller than 10,000, it means that the machine or process is faster than with Nominal speed works while a final count greater than 10 001 means that the machine or process is running at less than 100 96 nominal speed works as the machine or process works for a longer period of time to the Requires ten full duty cycles to complete. The system is therefore like that designed so that reaching a count of 10 001 is recognized. As before mentioned, the system is also designed so that the reaching of a count of 11,112 oscillator pulses is detected, indicating that the machine works at 90 96 nominal speed or even slower. Since the system always 10 (in the exemplary embodiment shown) work cycles of the machine or of the process counts and since a counter reading of 10,000 always indicates the nominal working speed, the structure of the system is greatly simplified. The operator can use various working speeds to be regarded as nominal value in a simple manner by changing the frequency of the oscillator. The system is also based on the fact simplifies that the exact detection of the count of the counter for the oscillator pulses is not necessary. It only needs to be determined whether a selected Meter reading or specific, selected meter readings can be reached. The above explained Counting of the oscillator pulses always remains the same, regardless of the respective Setting of switches 255 and 295. These two switches are preferred for a simultaneous actuation mechanically coupled.

To start up the system, the operator applies the supply voltage and sets the frequency of the oscillator using the adjusting knob 202 203 according to a desired nominal operating frequency of the machine. Afterward the operator actuates the reset switch 212, whereby the pulse ~ 277 is produced. The next following impulse from the switch operated by the machine 208 triggers the flip-flop 281, whereby the NAND gate 252 opens will and the oscillator pulses to the one of the five components 262 to 266 formed counter for the oscillator pulses.

The machine-generated pulses also reach counter 293.

During the eighth work cycle of the machine, a pulse 279 appears (pulse shape G) at the output of this counter 293. Actuated on the tenth cycle of the machine the falling edge 279a of the pulse 279 the flip-flop 296. By this process a pulse (pulse shape H) is generated at the output Q of the flip-flop 296, which clears the six flip-flops 301 to 306. Then the oscillator pulses counted on line 205 by means of flip-flops 301-306. After the occurrence of the first oscillator pulse on line 205 takes the signal I at output 5 of the Flip-flops 301 have a low switching value, resulting in a high switching value at the output of the NAND gate 254 and to a low switching value at the input 251 of the NAND gate 252 leads and prevents further oscillator pulses from reaching counter 213. The second oscillator pulse on line 205 generates the pulse of the pulse shape J, which, however, serves to create a time delay. The next oscillator pulse generates a pulse in the pulse form K, which is sent via line 307 to the inputs of the two components 321 and 322 is supplied.

This causes a shift in the two components 317 and 318 temporarily stored information about the logic elements 323 to 325 and 327th to 329 to the power circuits 331 and thus to switch on a of displays 219 to 221.

The next pulse on line 205 generates a pulse in the Pulse shape L, which in turn is only used to generate a time delay serves. The next oscillator pulse on line 205 generates a signal in the Pulse shape M, which has a low switching value at output 309 of the NAND gate 308 and thereby the deletion of components 262 to 266 and components 317 and 318 causes. The next oscillator pulse on line 205 results in the positive Pulse of pulse shape N and a negative pulse at output 8 of flip-flop 306, through which the flip-flops 296 and 301-306 are cleared or reset. At the end of one the tenth machine-generated pulse, the sequence control is initiated and on At the end of the sequence control, the reset pulse clears the flip-flops 296 and 301 bis 306 so that all sequencing was machine generated before receiving the next Impulse is complete. The system then goes through another frequency scan.

After the machine has performed ten full work cycles, the meter reading information is in turn from components 1 and 322 to permanent memory and a power circuit 331 and a different or the same display switched on.

During the sequence control, the pulse prevents the pulse shape I the supply of pulses to components 262 through 256.

However, since the entire flow control within a very short Time of only six oscillator pulses (pulse shape P) takes place, this is de-r errors introduced into the count of components 262 to 266 are negligibly small.

The system described so far shows the frequency of work or speed of the machine or process, averaged over ten complete work cycles. However often it is also desirable to determine whether the time required to complete a work cycle exceeds a certain limit. For example, the fact that a machine has jammed can be displayed relatively quickly. The invention makes this possible by means of determining an excessive amount of time. In detail the machine-generated pulses on line 227 are NAND gates 341 and 342 and the shutdown counter 228 supplied. The NAND gate 341 is single input to the line 227 and with a second input via a resistor 343 to a positive voltage connected. When the alarm clear switch 233 is operated however, the second input is connected to ground. If both inputs of NAND gate 341 lead a high switching value, which is when switch 233 the case for part of each work cycle of the machine or process is, the output of the NAND gate 341 is low and the output of the NAND gate 342 has a high switching value. Conversely, when line 227 is low Leads switching value, the output of the NAND gate 342 has a high switching value. Of the The output of the NAND gate 342 is connected to a line 343 which leads to the Clear inputs of four BCD counters 344, 345, 346 and 347 in the shutdown counter 228 leads. The trigger inputs of the four BCD counters 344 to 347 are on line 261 connected, which leads the oscillator pulses from the output of the NAND gate 252. The output A of the BCD counter 347 is connected to the trigger input of a flip-flop 351 connected. If during a certain work cycle of the machine or the Process the number of oscillator pulses on line 261 reaches the value 1000, the output A of the BCD counter 347 assumes a high switching value. If the number reaches the value 2000, the output A goes to a low switching value. A meter reading of 2000 indicates that at least twice the normal length of time for a complete machine cycle has elapsed, since a counter reading of 10,000 as a display of Nerm operation during ten machine cycles, a counter reading of 1000 represents the normal value for one cycle. Therefore shows a counter reading of 2000 indicates in counter 228 that a machine cycle requires twice the normal amount of time Has.

It is assumed that a count of 2000 has been reached. then the flip-flop 351 is triggered by the falling edge of the signal at output A of the BCD counter 347 triggered and thereby causes the output Q of the flip-flop 351 has a low switching value and output 5 assumes a high switching value.

The rising edge of the signal at output 5 passes a capacitor 352 and a resistor 353, whereby a pointed, positive impulse appearing at the base of a transistor 354 and at the collector this transistor causes a negative current pulse with which the set input a flip-flop 356 is applied. The Q output of flip-flop 356 is on one input of a NAND gate 357 connected between the NAND gates 324 and 329 is inserted. The output to the flip-flop 356 is at an input another NAND gate 358 connected between the NAND gate 329 and another NAND gate 359 is inserted. The NAND gate 359 is single input to a voltage Vcc and with a further input to the output of the NAND gate 324 connected. The negative pulse at the set input of the flip-flop 356 leads to a high switching value at the output Q of this flip-flop and thus to operate the Advert 219.

Simultaneously with this process, the Q output of the flip-flop picks up Q 351 has a low switching value and thereby switches off a transistor 361, which is normally switched on. With transistor 361 turned off a capacitor 362 is charged through a resistor 3g3 until the breakdown voltage of a uni-junction transistor 364 is reached, which is conductive at this time and the capacitor 362 discharges. Capacitor 362, resistor 363, and the transistor 364 form a blocking oscillator, which generates a square wave signal, with which the base of a transistor 366 is applied. This transistor amplifies and inverts the square wave signal and sends it to the trigger input of the Flip-flops 356 off.

Accordingly, the outputs Q and 5 of this flip-flop 356 lead alternately high and low switching values in the rhythm of the square wave signal from the blocking oscillator and cause the display 219 to flash. This flashing display causes an excessive amount of time between successive work cycles of the machine displayed. A previously switched on display 221 or 220 remains switched on.

To switch off a flashing signal and to return the system in the normal operating state, the operator closes the switch 233, whereby the NAND gate 341 is blocked and a low switching value on the line 366 is generated, which is connected to the set input of the flip-flop 351 and the clear input of flip-flop 356 is connected. This will reset these components and the blinking operation of the display 219 ends.

A special exemplary embodiment was shown on the basis of FIGS the invention explained. Of course, similar systems could be with different Designations are used. In Figures 2A and 2B, component numbers are in the Drawing entered, but this does not mean that with other logical basestones the same results could not be achieved.

In the embodiment described with reference to FIGS the sampling time is exactly 10 work cycles of the machine, but as before mentioned, can be switched to a sampling time of five working cycles. Included is the counter 293 counting to ten in one to five and one to two Divided counter, and the switch 295 can be operated so that the flip-flop 296 is triggered with the output signal of the counter that counts up to five. In this In this case, switch 255 should also be thrown so that the frequency of the Components 262 to 266 supplied signal is doubled, which is achieved by that a 1:18 counter is formed from components 246 and 247 instead of 1:36 counter will.

Of course, the connection of displays 219 and 220 could also be changed in this way be that the transition from. from one to the other display not at 90, but at 80% or any other desired percentage of the nominal speed. Before laying this transition, for example, a very clear view can be seen in FIG. 4 shown switch by changing the connections to the outputs of the counter components 262 to 266 can be achieved. There could also be a switch between the shutdown counter 228 and the Component 351 can be provided, with which the length the length of time until the actuation of the component 351 could be selected.

Fig. 4 shows a circuit in place of part of the circuit can be used according to Fig. 2B. As already mentioned, a switch arrangement can be provided with the help of which the operator determined percentages other than 90% the nominal speed or frequency can choose. Fig. 4 shows a corresponding one Arrangement.

The circuit of FIG. 4 comprises a NAND cell 401 and five components 402 to 406, which correspond to the NAND gate 252 or the components 262 to 266 in FIGS 2A and 2B correspond. The connections to the NAND gate 401 are the same as for the NAND gate 252 and the connections to the inputs of the components 402 to 406 are also the same as for components 262-266. There is also another NAND element 408 is provided which, including its connections, corresponds to the NAND element 308 in Fig. 2A corresponds.

A selector switch 411 for the percentage has a movable one Contact 412 and three switch positions with fixed contacts 4-, 3, 414 and 415. The contact 412 is connected to ground, while the contacts 413 to 415 each have an inverter 417, 418 and 419 are connected to inputs of three NAND gates 421, 422 and 423, respectively are. These inputs of the NAND gates 421 to 423 are also Uher each Resistance 426, 427 resp.

428 at a positive voltage Vcc.

As already mentioned, a NAND-Olled can only be negative provide directional signal transition at its output if all of its Inputs are at high potential. In the position of the shown in Fig. 4 Selector switch 411 leads the output of the inverter 417 to a high level and the outputs the inverters 418 and 419 each have a low switching value. Therefore only speaks the NAND gate 421 to voltage changes at one of its inputs at. If switch contact 412 was in contact with contacts 414 or 415, Correspondingly, only the NAND element 422 or 423 would respond to voltage changes.

Each of the NAND gates 421 to 423 has two further inputs, which are connected to certain, selected outputs of the components 404 and 405. The selected outputs determine the ones to be reached by components 402 to 406 Counter reading at which all inputs of a specific NAND element 421, 422 or 423 have a high switching value or are at high potential. The corresponding Meter readings correspond to different percentages of the nominal operation of the Machine.

The output A of the component 406 is via an inverter 431 to a Input of a flip-flop 432 connected, which is the flip-flop 317 in Fig. 2B is equivalent to. If the count is 10,000 or less, output Q des Flip-flops 432 have a low switching value and one of the display 221 corresponding The display is switched on, which shows 100, the nominal operating mode.

The output Q of the flip-flop 432 is also via a line 433 connected to an input of a further NAND gate 434, which is connected with pus Inputs to the outputs of the NAND gates 421, 422 and 423 is connected. The outputs of these NAND gates 421 to 423 normally each carry one high switching value, with the selected NAND-Glled at a low switching value changes when the count assigned to it is reached. The output of the NAND gate 434 is connected to an input of a flip-flop 437 via an inverter 436, which corresponds to flip-flop 318 in FIG. 2B.

If the count is 10 0On or less, output Q des Flip-flops 432 have a low switch value, and a Display is switched on, which shows 100% or more of the nominal operating mode. When a meter reading of 10 001 is reached, output Q assumes a high switching value and switches the ad. The high switching value also appears at the NAND gate 434. Then there all inputs of this NAND gate have a high switching value, a high one appears Switching value on the flip-flop 437 and leads to the switching on of one of the display 220 Display showing a percentage of the nominal operating mode that is less than 100%.

When the through the connections of the NAND gate 421 to the components 404 and 405 specified counter reading, 6r is reached, carry all inputs of this NAND element 421 has a high switching value so that its output changes to a low switching value.

This takes place at a count of 10,000 plus another Counter reading instead, which is, for example, a percentage below 90% the nominal mode of operation. The output of NAND gate 434 then takes one high switch on and a third display corresponding to display 219 is switched on, to indicate this percentage below 90%. Of course it is to a particular one Time only one of the three displays is switched on.

When the switch 411 is in one of the contacts 414 and 415 is brought to certain switching positions, the output of the NAND gate 434 with a different counter reading, which is determined by the connections of the NAND gates 422 resp. 423 depends on the components 404 and 405, switch to a high switching value. The counter readings can, for example, correspond to 80% and 70% of the / mode of operation. The operator can thus select whether or not by setting the switch 411 the system makes the machine work with less than 90 96, less than 80 % Should indicate 0 or less than 70% of the nominal operating mode.

In the exemplary embodiment explained with reference to FIGS a high-precision oscillator 203 with variable frequency is used, the oscillator is set to a value by the operator with the setting knob 202, which should be considered as the nominal workload. As the frequency increases, so does this The value is increased because the counter reading is then reached, which is 100% of the nominal operating mode corresponds to a shorter period of time is required. When using the in Fig. 5 circuit shown eliminates the need for an expensive, high-precision oscillator, without the operator having to forego the oscillator frequency to be adjusted according to a certain nominal working method.

The circuit of FIG. 5 includes a line 451 which is connected to the output an oscillator is connected, which is similar to oscillator 203, but not needs to be a high-precision oscillator, the line 451 can, for example, to the movable contact of the switch 206 be connected. Line 451 is on the inputs 452 of three components 453, 454 and 455 are connected. These three components also have clear inputs 457, which are connected to a line 458, and Scan or trigger inputs 459, which are connected to a line 461. Three Displays 462, 463 and 464 are connected to the output lines 466 of one component each 453, 454 or 455 connected. The display 462 shows biners, the display 463 tens and the display 464 hundreds. The components 453 to 455 form a decade Counter for the signal on line 451, a sample hold and memory circuit and a decoder driver for displays 462 through 464.

The circuit also includes one connected to the alternating current network for example 60 Hz connected full-wave rectifier 471, which one accordingly rectified signal generated. A voltage divider is off at its output two resistors 472 and 473 connected, being the junction point of these two Resistances is connected to the base of a transistor 474.

At the collector of transistor 474, a signal of double appears Mains frequency, e.g. 120 Hz, which is fed to an input of a counter 476 is interconnected with a NAND gate 477 to form a 1:12 counter is. At the output of the NAND gate 477, a pulse appears for every six alternating current periods at the input of the full-wave rectifier 471, which has an input of a monostable Tilting member 478 is supplied. The output of toggle 478 is on the line 461 and also connected to the input of a second monostable flip-flop 479, the output of which is connected to line 458. The NAND link for everyone 477 exiting pulse appears first on line 461 and then a pulse a pulse on line 458. The pulse on line 461 causes storage the counter reading in the counter part of components 453 to 455 in the hold circuit, and the pulse on line 458 then clears the counters, decodes the stored count and switches the displays 462 to 464 on.

So it becomes every sixth alternating current period or every 100 A count of the oscillator frequency on line 451 is performed in milliseconds and displayed. With the help of this visible display, the operator can the Set the oscillator frequency to a value that corresponds to the desired nominal value of the Speed or frequency of work.

It has already been mentioned that instead of that shown in the drawings Systems could alternatively use an arrangement in which the number of the work cycles that occur within a certain time interval or within run on a certain time base, is measured. With such a system a pulse for each work cycle of the machine and a time base can be generated. At the end of the time base, the number of machine-generated pulses is preselected with a Standard value compared. This comparison can be done, for example, by integrating the machine-generated impulses brought about into a voltage will, which represents the number of duty cycles, this voltage is then assigned a Reference voltage, for example compared using Schmidt triggers.

There can also be means of setting the duration of the time base and the duration of the machine-generated pulses so that the duration of the Can change the sampling interval.

Claims

Claims (11)

Palentans E ~ r-lche method for measuring the frequency of occurrence of events in a cyclically repeated sequence of events, in particular the frequency or speed of work of a machine or process, by capturing every event, by capturing a signal generated, which represents a unit of time, that you get a ratio of a number of events and the unit of time forms that this relationship with a value compares which is a standard value of the frequency of occurrence, and that the result of this comparison is displayed. 2. Apparatus for performing the method according to claim 1 g e k e n n z e i n e t by a first device 208, 20 t, which is based on the events responds and generates a first signal representative of a number of events that have occurred corresponds, by a second device (203, 213) for generating a second Signal corresponding to a sampling time interval by a third device (217) for generating a standard comparison value that corresponds to a predetermined frequency of occurrence of the events, with either the first or the second signal as a function the frequency of occurrence of the events is variable and the other signal is constant is held, and by a fourth device (218 to 221) for generating a Display of the comparison of the variable signal with the standard comparison value. 3. Apparatus according to claim 2, characterized in that g e k e n n -z e i c h n e t that the first device has a first counter (207) for generating the first Signal after a fixed number of occurrences includes that the second Device an oscillator (203) and a second counter (213) for the oscillator frequency wherein the second signal is the count output of the second counter, and that the third device by logic elements (217) and their connections with the second counter is formed. 4. Apparatus according to claim 2 or 3, g e k e n n z e i cht n e t by a shutdown device (228), which reacts to the first device (208, 207) and is responsive to a timer (203) and generates an indication when the Duration for the occurrence of an event exceeds a predetermined value. 5. Apparatus according to claim 2, 3 or 4, characterized g e -k e n n z e i c h n e t that the second device (203, 213) has an oscillator (203) and a at its output connected counter (213) and that the fourth device Logic elements (218) and displays (219 to 221), which are connected to the counter and provide an indication of its count as well as a response to the first signal Appealing device for transferring the counter reading to the logic elements and displays and to reset the counter. 6. Apparatus according to claim 5, characterized in that g e k e n n -z e i c h n e t that the device responsive to the first signal is a sequence control circuit (207) which receives the signal output of the oscillator (203). 7. Device according to one of claims 2 to 6, characterized g e k e n n e i c h n e t that the first means (208, 207) for changing the predetermined Number of events that have occurred can be set. 8. Apparatus according to claim 5, 6 or 7, characterized in that g e -k e n n z e i c h n e t that the connection of the oscillator (203) with the counter (213) to change the frequency of the signal received at the counter can be changed. 9. Device according to one of claims 5 to 8, characterized g ek e n n z e i h n e t that the logic elements (218) and displays (219 to 221) a display of the counter reading in the form of a percentage of a standard frequency supply, and that means (411) are provided for adjusting the value of this percentage are. 10. Device according to one of claims 5 to 9, g e k e n nz e i c h n e t by a device connected to the output of the oscillator (203) (Fig. 5) to display the frequency of the oscillator, which is also connected to the network and repeatedly displays the oscillator frequency as a function of the mains frequency. 11. Device according to one of claims 2 to 10, g e -k e n n z e i c h n e t by an oscillator (203), a counter (213), a counter operating device to control the transmission of the pulses to be counted from the oscillator to the counter, which is also connected to a sensor (208) for the events in this way is that an impulse transmission to the counter is only possible during the duration of events takes place, and by a display device connected to the meter (217 to 221) to indicate that the count of the counter has reached a predetermined limit Has.