WO2006066567A1 - Test data detection device for test stands - Google Patents

Abstract

Disclosed is a test data detection device (1) for test stands, especially in the domain of vehicle safety. Said test data detection device (1) is used for detecting physical parameters such as force, torque, or pressure. A central control unit (2), a signal line (3, 9A, 9B, 9C, 9D, 14A, 14B, 14C), and a plurality of test data detection units (10A, 10B, 10C, 10D, 15A, 15B, 15C) are provided, the test data detection units being connected to the central control unit (2) by means of the signal line.

Description

 Measurement data acquisition device for test benches

Field of the invention

The invention relates to the field of

Measurement data acquisition devices for test stands for the acquisition of physical quantities. Specifically, the invention relates to the field of measurement data acquisition devices for test stands in the vehicle safety area, in particular for vehicle impact systems.

State of the art

Measurement data acquisition for test benches in the vehicle safety area has hitherto been carried out by a plurality of sensors, each of which is individually connected to a memory module by means of a signal line. The data detected by the sensors are guided via the j mean signal line to the memory module and stored by the latter. After the measurement has been carried out, the stored measured data are read out of the memory module.

The previous data acquisition has the disadvantage that with a large number of sensors, the functionality of each individual sensor is difficult to verify. But even if it is recognized that the functionality of a sensor is not given, the troubleshooting in practice due to the large number of signal lines and sensors is extremely difficult. The same applies to the detection of incorrect connections, in which a sensor is connected to the wrong memory element of the memory module.

Presentation of the invention

It is an object of the invention to provide a To provide measurement data acquisition device, in which an improved measurement data acquisition is given and in particular the reliability of the measurement data acquisition is improved with regard to possible sources of error.

This object is achieved by a measurement data acquisition device having the features of claim 1.

The measurement data acquisition device according to the invention has the advantage that a plurality of

Measurement data acquisition devices can be connected by means of a signal line to the central control device. In this case, two or more signal lines may be provided, at which in each case a plurality of

Measurement data acquisition devices is connected. In this way, the number of signal lines of the measurement data acquisition device can be significantly reduced. This also results in a significantly lower total inertial mass of the measured data acquisition device. When using the measurement data acquisition device for moving test specimens that hit an obstacle, this results in a reduced influence on the impact process. This also applies to initially stationary test specimens, which are accelerated during the impact.

The measures listed in the dependent claims advantageous developments of the above-mentioned measurement data acquisition device according to the invention are possible.

It is advantageous that the measurement data acquisition device of the measurement data acquisition device has at least one sensor which serves to detect a physical quantity and outputs a measured value as a function of the currently detected value of the physical variable, and a memory element which is used to store a part of the output from the sensor Measured values are used. The measurement data acquisition device can be designed as an integrated module, so that the sensor and the memory element within a common housing are arranged and these are provided in particular on a common semiconductor board. The memory element can store the measured values in the immediate vicinity of the sensor, which prevents the influence of external disturbances on the recording process.

It is also advantageous that the

Measurement data acquisition device that stores measured values acquired by the measurement data acquisition device in the storage element during a predetermined test duration. The readout of the measurement data, which comprise the acquired measured values, can then be carried out by means of the central control device after the experiment has been carried out.

The control device advantageously reads the measured values stored in the memory element after the end of the test period via the signal line.

Advantageously, a central power supply is provided, the signal line is designed for transmitting data and energy and are the

Measurement data acquisition devices connected via the signal line to the central power supply. The design of the signal line for transmitting data and energy, a data bus is given, which also takes over the function of the power supply. For the measurement data acquisition device, this results in an extremely compact design, which also can be reliably assembled and disassembled in a short time by reducing the required connection points.

Advantageously, the

Measurement data acquisition devices arranged in series. In this case, it is furthermore advantageous that at least one measurement data acquisition device has a switching element which, in the opened state, interrupts the signal line from the central control device to a downstream measurement data acquisition device and in the closed state the signal line from the central one Control device to a downstream measurement data acquisition device manufactures that in an initial state of the measurement data acquisition device, the switching element is open, that the central control device outputs an initialization signal via the signal line and that the

Measurement data acquisition device confirms the initialization signal with an acknowledgment signal and actuates the switching element, so that the switching element is closed. It can be one, several or all

Measurement data acquisition devices have such a switching element. By the initialization signal, the first measurement data acquisition device of the measurement data acquisition devices arranged in series is initialized. Since the still open switching element interrupts the signal line to the downstream measurement data acquisition devices, the downstream measurement data acquisition devices receive no initialization signal. The

Measurement data acquisition device can perform a series of operations for startup and verification due to the initialization signal. In addition, the switching element is actuated, so that the switching element is closed. The actuation of the switching element is preferably carried out with or before the issue of

Confirmation signal. The central control device again outputs an initialization signal on the basis of the confirmation signal obtained, wherein the already initialized measurement data acquisition device sends the initialization signal to the next one without its own answer

Transfers data acquisition device. The next measurement data acquisition device in turn performs the above-mentioned operating functions. By successively outputting the initialization signal, the entire row of the measurement data acquisition devices can thereby be initialized. In addition, at the end of the series of measurement data acquisition devices, a measurement data acquisition device embodied as an end element can be connected, which returns a special acknowledgment signal to the central control device so that it signals the end of the data acquisition device Series arranged measuring data acquisition devices recognizes.

In addition, an annular arrangement of the measurement data acquisition devices is possible, in which the last measurement data acquisition device is connected at the end to the central control device.

Preferably, the measurement data acquisition device has an operating state display device which indicates whether the switching element is in the open state or in the closed state. This operating state display device can be formed, for example, by means of a light-emitting semiconductor diode. When an error occurs in which the central control device receives no confirmation signal due to an initialization signal, the error that occurs can be quickly limited. In particular, a faulty connection of a measurement data acquisition device to the control line can be detected quickly or the exchange of a measurement data acquisition device can take place in a targeted manner. The reliability of the measurement data acquisition device is further increased in this way and further improves the verifiability of a fault-free operation and the elimination of errors.

It is advantageous that the measurement data acquisition device has an identification device which serves for outputting an identification code, and that the measurement data acquisition device confirms an initialization signal of the control device with an acknowledgment signal generated on the basis of the identification code. Depending on the identifier, a certain transmission delay for the output initialization signal can also be specified. In this way, the central control device can also detect whether an acknowledgment signal is output on an initialization signal from only one or more measurement data acquisition devices. As a result, for example, a malfunction of the switching element can be detected. In addition, this is the initialization of several Branches of series connected

Measurement data acquisition devices possible. The

Identification device can the

Identification mark as a randomly generated

Issue license plate, so that the

Measurement data acquisition devices are constructed of identical components, whereby the production is facilitated.

However, the identification means can also output individual identification marks, whereby a unique recognition of

Measurement data acquisition devices is made possible.

Brief description of the drawings

An embodiment of the invention will be explained in more detail in the following description with reference to the accompanying drawings. It shows :

Fig. 1 shows an embodiment of a measurement data acquisition device of the invention;

Fig. 2 an embodiment of a

Measurement data acquisition device of FIG. 1 shown

Measurement data acquisition device and

Fig. 3 shows an exemplary embodiment of a connection element of the embodiment shown in FIG. 2 shown measurement data acquisition device.

Description of the embodiment

Fig. 1 shows an exemplary embodiment of a measurement data acquisition device 1 according to the invention

Measurement data acquisition device 1 is used to acquire measured values, in particular measured value series, at a multiplicity of measuring points. In particular, the force, the acceleration, the moment, the pressure, a voltage, the temperature or another physical variable can in each case be measured at a test body at several points on a test stand for the vehicle safety area, wherein a Place several of these sizes can be detected side by side. The inventive

Measurement data acquisition device 1 is, however, also suitable for other applications.

The measured data acquisition device 1 comprises a central control device 2, which is connected by a line 3 to a distributor device 4. The

Distribution device 4 has in this embodiment connection contacts 5, 6, 7, 8. At the connection contact 5, a measuring data acquisition device 10A is connected via a line 9A. The measurement data acquisition device 10A is connected via a line 9B to a measurement data acquisition device 1OB. The measurement data acquisition device 1OB is connected via a line 9C to a measurement data acquisition device IOC, which is connected via a line 9D to a measurement data acquisition device 10D. The measurement data acquisition device 10D is designed as an end member and has, in contrast to the

Measurement data acquisition devices 10A, 1OB and IOC only a single terminal 11. The

Measurement data acquisition devices 10A, 10B, 10C each have two connections, wherein in FIG. 1 only the terminals 12, 13 of the measurement data acquisition device 10A are marked. In the manner described, a number of measurement data acquisition devices 10A, 10B, 10C, 10D are connected to the connection contact 5 of the distribution device 4. In this case, the line 3 and the lines 9A, 9B, 9C, 9D form a signal line from the central control device 2 to the measured data acquisition devices 10A, 10B, 10C, 10D.

At the connection contact 6 of the distributor device 4, measurement data acquisition devices 15A, 15B, 15C are connected via lines 14A, 14B, 14C. In this case, the lines 14A, 14B, 14C together with the line 3 form a further signal line between the central control device 2 and the measurement data acquisition devices 15A, 15B, 15C. According to the measurement data acquisition device 10D is in In this series of measurement data acquisition devices 15A, 15B, 15C, the measurement data acquisition device 15C is designed as an end element.

To simplify the illustration, in FIG. 1 of each of the illustrated branches of measurement data acquisition devices 10A, 10B, 10C, 10D and 15A, 15B, 15C respectively, four and three measurement data acquisition devices. However, a larger number of measurement data acquisition devices can also be provided; in particular, a number of 32 data acquisition devices can be provided in each branch.

Although the measurement data acquisition devices 10A, 10B, 10C, 10D are arranged in series, current technology results in a parallel connection, as described with reference to FIG. 3 is described in more detail. With a current flow of 50 to 100 mA of the measurement data acquisition device, this results in a power requirement of up to 3 A branch for a number of 32 measurement data acquisition devices.

The connection contacts 7, 8 serve to connect further branches of measurement data acquisition devices.

In addition, the distributor device 4 has a connection contact 16 which serves to connect a further distributor device (not shown) corresponding to the distributor device 4. In this case, the further distributor device and the distributor device 4 can also be connected to one another via a suitable line (not shown).

The measurement data acquisition device 1 also has a central power supply 20, which is connected via a line 21 to the central control device 2. On the one hand, the power supply 20 serves to provide energy for the central control device 2. On the other hand, the central control device 2 couples part of the energy provided by the power supply 20 into the power supply 20 Line 3 to power the measurement data acquisition devices 10A, 10B, 10C, 10D, 15A, 15B, 15C, the transmission of the energy and the data preferably via the same signal line 3, 9A, 9B, 9C, 9D, and 3, respectively; 14A, 14B, 14C.

The measurement data acquisition device 1 also has a measurement data processing device 22. On the measurement data processing device 22, which is part of an electronic computer, for example, the measured values acquired by the measurement data acquisition devices 10A, 10OB, 10C, 10D, 15A, 15B, 15C can be processed, for example, by means of a computer program.

Fig. 2 shows the measurement data acquisition device 10A of the measurement data acquisition device 1 of the exemplary embodiment of the invention in a schematic representation. In this and in all other figures, corresponding elements are provided with matching reference numerals, whereby a repetitive description is unnecessary.

The measurement data acquisition device 10A has a connection unit 25, wherein the connection unit 25 is connected via a line 26 to the terminal 12 and is connected via a line 27 to the terminal 13. The terminal unit 25 is adapted to receive a signal via the line 26 and output this signal via the line 27, whereby a part of the signal can be coupled out and the forwarding to the line 27 can be interrupted. Accordingly, the terminal unit 25 is also configured to receive a signal through the line 27 and output this signal via the line 26. The connection unit 25 can decouple both a supply voltage and a high-frequency signal which is obtained via the line 26 or the line 27. The construction of the connection unit 25 is described below with reference to FIG. 3 described in detail.

The connection unit 25 is connected via a line 28 with a Control unit 29 connected. When the connection unit 25 receives an initialization command from the central control device 2 (FIG. 1) via the line 26, it forwards it to the control unit 29 via the line 28. Thereafter, the control unit 29 transmits commands for performing initialization operations to a measurement data acquisition unit 31 via the line 30. After performing these initialization operations, the control unit 29 sends a request for obtaining an identification mark to an identification device 33 via a line 32, and the identification device 33 responds to this request via line 32 an identification mark to the control unit 29 back. The identification device 33 can the

Output identification as a randomly generated identifier. However, the identification device 33 can also output the identification code as an identification tag that is individual for the respective measurement data acquisition device 10A. The control unit 29 generates a confirmation signal based on the identification mark and outputs this confirmation signal via the line 28 to the connection unit 25, which couples the confirmation signal into the signal line and returns it via the line 26 to the central control device 2 (FIG. 1). In this case, the control unit 29, for example based on a value calculated from the identifier by a hash algorithm, determine an individual delay for the measurement data acquisition device 10A for the output of the acknowledgment signal, so that when a malfunction, in particular a short circuit, of two or more

1), within a range of, for example, 0 to 64 ms, to be returned to the central controller 2 for ease of detection.

After the confirmation signal is output, the Control unit 29, an operating state display device 34 formed by a light-emitting semiconductor diode. Upon the occurrence of a fault, the control unit 29 may leave the operation status indicator 34 turned off or periodically turn it on and off.

The measurement data acquisition device 10A also has sensor elements 35, 36, 37. The sensor elements 35, 36, 37 are used for detecting physical variables, in particular an acting force, an acceleration, a rotational or moment of inertia, a pressure, a temperature, of stresses, in particular bending stresses, and of lengths, in particular changes in length. If necessary, different directions can be detected separately, for example in the X, Y and Z directions. The sensor 35 outputs analog measured values to a conversion device 39 at regular intervals as a function of the currently detected value of the physical variable via a line 38. The conversion device 39 may comprise, for example, an amplifier, a filter and an analog / digital converter. The conversion device 39 outputs a digitally coded measured value via the line 42 to the measured data acquisition device 31 on the basis of the measured value obtained from the sensor element 35. This digital measured value can be coded, for example, with a resolution of 16 bits and output to the measured data acquisition device 31 at a rate of 20 kHz. The sensor element 36 is connected in a corresponding manner by means of a line 40, a conversion device 41 and a line 43 to the measurement data acquisition device 31, and a sensor element 37 is connected via a line 44, a conversion device 45 and a line 46 to the measurement data acquisition device 31.

It should be noted that each of the sensor elements 35, 36, 37 can be set up individually for a specific purpose, in particular the sensor elements 35, 36, 37 can detect the same or different physical quantities. In addition, it is also possible that one or a plurality of the sensor elements 35, 36, 37 are replaced by an active element. For example, instead of the sensor element 36 and the conversion device 41, a positioning means may be provided which is formed by a semiconductor laser in order to allow the adjustment and alignment of the measurement data acquisition device 10A with respect to a predetermined spatial direction.

The measurement data acquisition unit 31 receives from the sensor elements 35, 36, 37 digital measurement data and outputs them via a line 47 for at least temporary storage to a storage element 48. The memory element 48 is preferably designed as a ring memory in order to enable a continuous recording of the digital measurement data, the most recent measurement data overwriting the oldest measurement data. In this case, due to a stop command received from the central control device 2, the measurement data acquisition unit 31 may stop the storage process. Alternatively, it is also possible for the measurement data acquisition unit 31 to wait for a predetermined period of time after a start command and to stop the current recording after this. This period can be for example 10 s.

After stopping the recording, the measurement data acquisition device 10A outputs the digital measurement data stored in the storage element 48 via the terminal unit 25 and the data base 12 based on a read command from the central control device 2, which refers to the identification tag output by the identification device 33 for addressing the measurement data acquisition device 10A Line 26 to the central control device 2 (Fig. 1). In this case, the physical unit is coded in the digital measurement data in addition to the detected physical quantity as a function of the type of the sensor element 35, 36, 37. Since, after the test procedure, any amount of time is available for reading out the measured data acquisition devices 10A, 10B, 10C, 10D, 15A, 15B, 15C, this is the case successive readout of the measurement data from the various measurement data acquisition devices 10A, 10OB, 10C, 10D, 15A, 15B, 15C together with further additional information, such as the physical value associated with the measurement values and the identification mark of the respective measurement data acquisition device 10A, 10OB, 10C, 10D, 15A, 15B 15C, does not pose a problem in terms of time, so that the reliability of the measurement data acquisition apparatus 1 is further improved.

Above is with reference to FIG. 2, the measurement data acquisition device 10A has been described in detail. The

Measurement data acquisition devices 1OB, 10C, 10D, 15A, 15B, 15C are constructed in accordance with the measurement data acquisition device 10A, wherein the respective sensor elements 35, 36, 37 can be configured individually, so that each individual sensor of each individual data acquisition device 10A, 10B, 10C, 10D, 15A, 15B, 15C can be set individually to measure the force, acceleration, moment, pressure, rotational speed, in particular yaw rate, or other physical quantity.

Fig. FIG. 3 shows the connection element 25 of the measurement data acquisition device 10A of FIG

Measurement data acquisition device 1 of the embodiment of the invention in a detailed representation. According to the construction of the terminal unit 25, the terminal units are also the others

Measurement data acquisition devices 1OB, IOC, 10D, 15A, 15B, 15C, wherein an additional termination element 50 is provided for the measured data acquisition devices 10D, 15C configured as end members, as described in detail below.

The connection unit 25 has a power supply branch 51 and a signal branch 52.

The power supply branch 51 is used for decoupling a low-frequency signal or DC voltage to ensure the power supply of the measurement data acquisition device 10A (FIGS. 1, 2). For this purpose, the power supply branch 51 of the connection unit 25 has a first low-pass filter 52 and a second low-pass filter 53, which are designed as lambda / 4 lines for passing a DC or low-frequency voltage and for blocking a high-frequency signal. In addition, the connection unit 25 has a switching element 54. In this case, the first low pass 52 is connected on the one hand to the line 26 and on the other hand via a line 55 to the switching element 54. The second low-pass filter 53 is connected on the one hand to the line 27 and on the other hand via a line 56 to the switching element 54. The switching element 54 interrupts in the opened state the connection between the line 55 and the line 56, so that the signal line from the central control device 2 (FIG. 1) to a downstream measured data acquisition device 1OB, IOC, 10D (FIG. 1) is interrupted. In the closed state of the switching element 54, the line 55 is connected to the line 56, so that the signal line is made by the central control device 2 via the measurement data acquisition device 10A to the downstream measurement data acquisition device 1OB. The switching element 54 also has an output 57, at which the operating voltage for the measured data acquisition device 10A is output. There is always a connection between the line 55 and the output 57 and / or the line 56 and the output 57, wherein optionally separate lines are available at the output 57.

The signal branch 52 has a high-pass filter 60 which is connected on the one hand to the line 26 and on the other hand to the line 27, whereby the signal branch 52 is blocked for DC and middle frequency signals. From the line 26 branches off a line 61 which is connected to a coupling element to achieve a weak coupling to the line 26 of, for example, 1%. On the other hand, the coupling element 62 is connected via a line 63 to a balun transformer 64, which transmits a symmetrical transmission from the coupling element 62 to a transmitting transformer 62. Ensured / receiver 65, which is connected via a line 66 to the balun transformer 64. The transmitting / receiving part 65 is for receiving analog signals from the coupling element 62 and for transmitting analog signals to the coupling element 62 by means of the Symmetrieübertragers 64. The transmitting / receiving part 65 is connected via a line 67 to a digital interface 68, the a digital / analog converter and an analog / digital converter has. Via the digital interface 68, digital data is transmitted from and to an output 69 of the connection unit 25, the output 69 being connected to the line 28.

The trained as an end member

Measurement data acquisition devices 10D, 15C have, instead of the output 13 for connecting a line, a terminating element 50 which is connected to the connection 13 via the line 70 that is shown interrupted. The terminating element 50 may be designed, for example, as a 50 ohm terminating resistor, which connects the signal-carrying line 27 to ground.

It should be noted that to simplify the illustration in FIGS. 1, 2 and 3, the corresponding lines are shown in simplified form. Depending on the type of data to be transmitted, the lines may be formed, for example, by coaxial lines or by serial or parallel data lines.

The invention is not limited to the embodiment described.

Claims

claims

1. measurement data acquisition device (1) for test stands, in particular for test stands in the vehicle safety area, for the detection of physical quantities with a central control device (2), at least one signal line (3, 9, 14) and a plurality of measurement data acquisition devices (10A, 10B, 10C, 10D, 15A, 15B, 15C), wherein the

Measurement data acquisition devices by means of the signal line (3, 9, 14) with the central control device (2) are connected.

2. measurement data acquisition device according to claim 1, characterized in that the measurement data acquisition device (10A) at least one sensor (35, 36, 37), which serves to detect a physical quantity and outputs a measured value in dependence on the currently detected value of the physical quantity, and at least one memory element (48) which serves for storing at least part of the measured values output by the sensor (35, 36, 37).

3. Measurement data acquisition device according to claim 2, characterized in that the measurement data acquisition device (10A), which stores measured values acquired by the sensor (35, 36, 37) during a predetermined test duration in the storage element (48).

4. Measurement data acquisition device according to claim 3, characterized in that the central control device (2) reads out the measured values stored in the memory element (48) after the end of the test period via the signal line.

5. measurement data acquisition device according to one of claims 1 to 4, characterized in that a central power supply (20) is provided, that the signal line is designed to transmit data and energy and that the

Measurement data acquisition devices (10A, 10B, 10C, 10D, 15A, 15B, 15C) can be connected via the signal line to the central power supply (20).

6. Measurement data acquisition device according to one of claims 1 to 5, characterized in that the measurement data acquisition devices are arranged in series.

7. Measurement data acquisition device according to claim 6, characterized in that the measurement data acquisition device (10A) has a switching element (54) which in the opened state at least partially interrupts the signal line from the central control device (2) to a downstream measurement data acquisition device (10B) and in the closed state the signal line from the central control device (2) to a downstream measurement data acquisition device (10B) establishes that in an output state of the measurement data acquisition device (10A) the switching element (54) is open, the central control device (2) outputs an initialization signal via the signal line and the measurement data acquisition device (10A) confirms the initialization signal with an acknowledgment signal and actuates the switching element (54) so that the switching element (54) is closed.

8. A measured data acquisition device according to claim 7, characterized in that the measurement data acquisition device (10A) has an operating state display device (34) which indicates whether the switching element (54) is in the open state or in the closed state.

9. measurement data acquisition device according to claim 8, characterized in that the operating state display device (34) comprises a light-emitting semiconductor diode.

10. Measurement data acquisition device according to one of claims 1 to 9, characterized in that the measurement data acquisition device (10A) has an identification device (33) which serves to output an identification code, and that the measurement data acquisition device (10A) a

Initialization signal of the central control device (2) confirmed with a confirmation signal generated on the basis of the identification mark.

11. measurement data acquisition device according to claim 10, characterized in that the identification device (33) outputs the identification mark as a for the j eweilige measurement data acquisition device (10A, 1OB, IOC, 10D, 15A, 15B, 15C) individually predetermined indicator.