DE102019119715A1 - Measuring system with a measuring instrument and with a transmitter and receiver unit - Google Patents

Abstract

Measuring system with a measuring instrument and with a transmitting and receiving unit, wherein data can be transmitted wirelessly to the measuring instrument with the transmitting and receiving unit and data can be received wirelessly from the measuring instrument, the transmitting and receiving unit being designed to send a measuring signal captured by the measuring instrument receive and process, wherein the transmitting and receiving unit is designed to transmit to the measuring instrument configuration parameters for setting the measuring instrument to the measuring instrument, wherein the measuring instrument is designed to receive and process the configuration parameters, the transmitting and Receiving unit has an interface, wherein the transmitting and receiving unit is designed to communicate via the interface with a machine tool and / or a measuring machine, so that a control unit of the machine tool and / or a control unit of the measuring machine to the transmitting and receiving unit aschine the configuration parameters for setting the measuring probe can be transferred via the interface.

Description

State of the art

A measuring system comprising a measuring probe and a transmitting and receiving unit is known. In this measuring system, the measuring instrument and the transmitting and receiving unit communicate wirelessly, for example, via a light signal transmission in the infrared range. In this known system, the measuring probe is configured manually on the measuring probe.

A disadvantage of such a system is that the configuration of the measuring probe is comparatively complex and comparatively confusing.

Object and advantages of the invention

The invention is based on the object of providing an improved measuring system with a measuring instrument and with a transmitting and receiving unit, in which configuration of the measuring instrument is facilitated.

The object is achieved by the features of claim 1.

In the dependent claims, advantageous and expedient embodiments of the invention are specified.

The invention is based on a measuring system with a measuring instrument and with a transmitting and receiving unit, the transmitting and receiving unit being designed to receive and process a measuring signal detected by the measuring instrument.

The measuring instrument is designed, for example, as a measuring probe, as a distance measuring device, as a coating thickness measuring device, a material hardness measuring device, as a temperature measuring device and / or as a distance measuring device, e.g. as a line scanner. The transmitting and receiving unit is available as a receiver, for example.

The essence of the invention is seen in the fact that data can be transmitted wirelessly to the measuring instrument with the transmitting and receiving unit and data can be received wirelessly from the measuring instrument, the transmitting and receiving unit being designed to send configuration parameters for setting the measuring instrument to the measuring instrument The measuring instrument is designed to receive and process the configuration parameters, the transmitting and receiving unit having an interface, the transmitting and receiving unit being designed to communicate with a machine tool and / or with a measuring machine via the interface communicate, so that the configuration parameters for setting the measuring probe, in particular via the interface, can be transmitted to the transmitting and receiving unit from a control unit of the machine tool and / or a control unit of the measuring machine.

The machine tool is designed, for example, as a CNC machining center. For example, the machine tool is designed as a turning and / or milling center. The measuring machine is available, for example, as a coordinate measuring machine.

Advantageously, a configuration parameter is to be understood as a delay time, a triggering force, a triggering path, a triggering angle, an on and / or off time, an on and / or off delay and / or a filter setting, e.g. a trigger filter.

For example, the transmitting and receiving unit and the measuring instrument communicate via a wireless communication channel. For example, the transmitting and receiving unit and the measuring instrument communicate by means of optical signals and / or by means of radio signals. The optical signals are, for example, infrared signals. The radio signals are, for example, Bluetooth signals.

The interface is advantageously designed as a serial interface. The communication between the transmitting and receiving unit and the machine tool and / or the measuring machine is advantageously based on a synchronous, serial protocol. It is also conceivable that the interface is designed as a standard interface, e.g. as a standard data bus. For example, the interface is available as a Profinet interface, as an EnDat interface or as an SPI (Serial Peripheral Interface).

It also proves to be advantageous that the interface is a wired interface. This results in a comparatively safe transmission path.

It is also conceivable that the interface is present as a wireless interface. For example, the interface is designed as a radio interface. For example, as a WLAN interface, as a Bluetooth interface and / or as a mobile radio interface, for example as an LTE interface. For example, the interface includes an antenna. It is conceivable that the transmitter and receiver unit will operate in the frequency range between 700 and 2600 Megahertz or in a frequency range around 2.4 gigahertz, for example in the range between 2.3 and 2.5 gigahertz, or in a frequency range around 3.6 gigahertz or in a frequency range around 60 gigahertz can send and receive information by means of the interface.

It is also proposed that the transmitting and receiving unit and the measuring instrument communicate with one another by means of a radio link.

The transmitting and receiving unit advantageously comprises a transmitting and receiving element. The transmitting and receiving element includes, for example, an antenna. It is conceivable that the transmitting and receiving organ in the frequency range between 700 and 2600 megahertz and / or in a frequency range around 2.4 gigahertz, e.g. in the range between 2.3 and 2.5 gigahertz, and / or in a frequency range around 3, Can send and receive 6 GHz and / or in a frequency range around 60 GHz. For example, the transmitting and receiving unit and the measuring instrument communicate based on a transmission protocol in accordance with the IEEE 802.15.4 standard.

The transmitting and receiving unit and the measuring instrument preferably communicate by means of a WLAN interface, a Bluetooth interface and / or a cellular radio interface. The mobile radio interface is available, for example, as an LTE interface.

It also proves to be advantageous that the interface has a signal line for a power supply of the transmitting and receiving unit and a signal line for a measurement signal transmission.

The interface advantageously comprises at least two signal lines. The interface advantageously comprises three signal lines. For example, a clock pulse is transmitted via a first signal line. Via a second signal line, for example, the machine tool and / or the measuring machine can transmit information, especially exclusively to the transmitting and receiving unit, coordinated with the cycle of the first signal. Via a third signal line, for example, the transmitting and receiving unit can transmit information to the machine tool and / or to the measuring machine in accordance with the cycle of the first signal. For example, the interface comprises a signal line for a particularly exclusive transmission of a measurement signal from the transmitting and receiving unit to the machine tool and / or to the measuring machine. The interface preferably comprises a further signal line for a particularly exclusive transmission of data, e.g. configuration data for the measuring instrument, from the machine tool and / or from the measuring machine to the transmitting and receiving unit.

It is also advantageous that the interface has a signal line for serial data communication with the machine tool and / or the measuring machine. The interface is designed, for example, as a serial and / or parallel interface. The interface is advantageously in the form of a USB interface. It is conceivable that the transmitting and receiving unit is designed in the form of a USB stick.

In an advantageous modification of the invention, several bits, for example more than two bits, are transmitted via the signal line for transmitting the configuration parameters. One bit can advantageously be transmitted per cycle. Eight clocks and thus eight bits are advantageously combined into one byte. Each information item that can be transmitted advantageously comprises at least 8 bits. For example, each piece of information that can be transmitted comprises exactly 8 bits, exactly 16 bits and / or exactly 32 bits. Preferably, each information comprises the same number of bits, e.g. 8 bits, 16 bits or 32 bits.

For example, two different groups of information are defined, with a first group of information having the same number of bits, for example 8 bits or 16 bits, and a second group of information having the same number of bits, for example 16 bits or 32 bits, the Number of bits of information in the second group is different from the number of bits in information in the first group.

The first group of information advantageously includes control commands for controlling and / or monitoring the measuring system, in particular the measuring instrument. For example, a control command is present as a switch-on command or as a switch-off command. It is also conceivable that a control command is in the form of information about the state of charge of an energy supply of the measuring instrument, e.g. energy low or energy sufficient.

The second group of information preferably includes measurement information from the measurement system, in particular the measurement instrument. For example, measurement information is available as a measurement value. The measured value can advantageously be determined by measuring the measuring system, in particular the measuring instrument. The measured value is available as a distance value, for example. For example as a distance between the measuring instrument and the object to be measured and / or as a thickness of an object to be measured, for example a distance between two outer surfaces of an object to be measured and / or a layer thickness, for example a coating thickness. It is also conceivable that the measured value can be used as a sound transit time measured value Temperature measured value, a distance measured value, a material thickness measured value and / or as a material hardness measured value is present.

The measuring instrument and the transmitting and receiving unit are advantageously designed in such a way that the measuring instrument transmits a number of probes carried out by the measuring instrument and / or a number of battery changes carried out on the measuring instrument to the sending and receiving unit. The measuring instrument and the transmitting and receiving unit are advantageously designed in such a way that the transmitting and receiving unit can query and / or collect a number of probes carried out by the measuring instrument and / or a number of battery changes carried out on the measuring instrument from the measuring instrument. The transmitting and receiving unit preferably comprises a computing unit with a memory in order to process and / or store information from the measuring instrument and / or information from a control unit of the machine tool and / or information from a control unit of the measuring machine. For example, the control unit is designed to process configuration parameters for the measuring instrument that were received from the control unit and to forward them to the measuring instrument.

An advantageous embodiment of the invention is a measuring unit consisting of a measuring instrument and a control unit, the control unit being designed to control a machine tool and / or a measuring machine, the control unit being designed to wirelessly transmit data to the measuring instrument and data from the measuring instrument to be able to receive, and wherein the control unit is designed to transmit configuration parameters to the measuring instrument in order to configure the measuring instrument. The interface of the transmitting and receiving unit is preferably physically connected to the control unit.

It is also advantageous that the control unit is designed to receive and process a measurement signal recorded by the measurement instrument.

For example, the control unit comprises a transmitting and receiving unit and / or a transmitting and receiving element in order to communicate with the measuring instrument by means of this. For example, the transmitting and receiving unit and the control unit are designed to be coordinated with one another. For example, the transmitting and receiving unit is designed as a module that can be arranged, e.g., attached, to the control unit. For example, the transmitting and receiving unit is designed as a printed circuit board and / or as a semiconductor component with an electronic circuit and / or as a semiconductor component with an integrated circuit.

The control unit and the transmitting and receiving unit are advantageously designed in such a way that the transmitting and receiving unit sends a number of probes carried out by the measuring instrument and / or a number of battery changes carried out on the measuring instrument and / or a measuring signal, e.g. a measured value, to the Control unit transmitted. The control unit and the transmitting and receiving unit are advantageously designed in such a way that the control unit receives a number of probes carried out by the measuring instrument and / or a number of battery changes carried out on the measuring instrument and / or a measurement signal, e.g. a measured value, from the sending and receiving unit can query and / or pick up.

In an advantageous modification of the measuring unit, a transmitting and receiving unit is an integral part of the control unit, the transmitting and receiving unit of the control unit being designed to wirelessly transmit data to the measuring instrument and to be able to receive data from the measuring instrument. For example, the control unit is designed as a circuit board and / or as a semiconductor component with an electronic circuit and / or as a semiconductor component with an integrated circuit and the transmitting and receiving unit as a module, in particular as a functional part, on and / or on the circuit board and / or the semiconductor component present. For example, the interface of the transmitting and receiving unit is designed as a soldering point and is physically connected to the control unit.

Another advantageous embodiment of the invention is a machine tool and / or measuring machine with a measuring system according to one of the aforementioned embodiments or a measuring unit according to one of the aforementioned embodiments.

Figure list

• 1 zeigt in einer schematischen Darstellung eine Werkzeugmaschine mit einem erfindungsgemäßen Messsystem umfassend ein Messinstrument und eine Sende- und Empfangseinheit.

An exemplary embodiment is explained in more detail with reference to the following schematic drawings, specifying further details and advantages.

• 1 shows a schematic representation of a machine tool with a measuring system according to the invention comprising a measuring instrument and a transmitting and receiving unit.

In 1 is a machine tool 1 shown schematically, which a processing table 2 and a control unit 3 includes. Further components of the machine tool 1 such as a machining tool are not shown for reasons of clarity. On the processing table 2 a workpiece is also shown schematically 4th arranged.

On the machine tool 1 is also a measuring system according to the invention 5 arranged. The measuring system 5 includes a measuring instrument 6 which is in 1 is shown by way of example in the form of a measuring probe, and a transmitting and receiving unit 7th .

The sender and receiver unit 7th includes a computing unit 8th , a sending and receiving organ 9 and an interface 10 . the interface 10 includes, for example, 3 signal lines 11-13 .

The signal lines 11-13 are by means of a cable 14-16 for example firmly with the control unit 3 wired. It is conceivable that the interface 10 in particular has exactly twelve signal lines. For example, a first signal line is designed to be the transmitting and receiving unit 7th through the control unit 3 to provide energy. For example is a second signal line 12th designed to receive data, in particular information, for example configuration parameters, from the control unit 10 to the sender and receiver unit 7th transferred to. It is also conceivable that a third signal line 13 designed to receive data, in particular information, for example a measured value, from the transmitting and receiving unit 7th to the control unit 10 transferred to.

The sender and receiver unit 7th communicates with the measuring instrument 6 wirelessly, for example by means of a radio frequency.

List of reference symbols

1

Machine tool

2

Machining table

3

Control unit

4th

workpiece

5

Measuring system

6th

Measuring instrument

7th

Transmitter and receiver unit

8th

Arithmetic unit

9

Sending and receiving organ

10

interface

11

Signal line

12

Signal line

13

Signal line

14th

electric wire

15th

electric wire

16

electric wire

Claims (10)

Measuring system (5) with a measuring instrument (6) and with a transmitting and receiving unit (7), the transmitting and receiving unit (7) wirelessly transmitting data to the measuring instrument (6) and wirelessly receiving data from the measuring instrument (6) The transmitting and receiving unit (7) is designed to receive and process a measurement signal detected by the measuring instrument (6), wherein the transmitting and receiving unit (7) is designed to send configuration parameters for the measuring instrument (6) to transmit the setting of the measuring instrument (6), the measuring instrument (6) being designed to receive and process the configuration parameters, the transmitting and receiving unit (7) having an interface (10), the transmitting and receiving unit (7) is designed to communicate with a machine tool (1) and / or a measuring machine via the interface (10), so that the transmitting and receiving unit (7) is sent from a control unit (3) r machine tool (1) and / or a control unit of the measuring machine, the configuration parameters for setting the measuring probe can be transferred. Measuring system (5) according to one of the preceding claims, characterized in that the interface (10) is a wired interface. Measuring system (5) according to one of the preceding claims, characterized in that the transmitting and receiving unit (7) and the measuring instrument (6) communicate with one another by means of a radio link. Measuring system (5) according to one of the preceding claims, characterized in that the interface (10) has a signal line (10) for a power supply of the transmitting and receiving unit (7) and a signal line for a measurement signal transmission. Measuring system (5) according to one of the preceding claims, characterized in that the interface (10) has a signal line (11) for serial data communication with the machine tool (1) and / or the measuring machine. Measuring system (5) according to one of the preceding claims, characterized in that via the signal line (11) for serial data communication for transmitting the Configuration parameters several bits, for example more than two bits, are transmitted. Measuring unit consisting of a measuring instrument (6) and a control unit (3), the control unit (3) being designed to control a machine tool (1) and / or a measuring machine, the control unit (3) being designed to transmit data wirelessly to be able to transmit to the measuring instrument (6) and receive data from the measuring instrument (6), and wherein the control unit (3) is designed to transmit configuration parameters to the measuring instrument (6) for configuring the measuring instrument (6). Measuring unit according to the previous one Claim 7 , characterized in that the control unit (3) is designed to receive and process a measurement signal detected by the measuring instrument (6). Measurement unit according to one of the preceding Claims 7 or 8th , characterized in that a transmitting and receiving unit (7) is an integral part of the control unit (3), the transmitting and receiving unit (7) of the control unit (3) being designed to wirelessly transmit data to the measuring instrument (6) and to be able to receive data from the measuring instrument (6). Machine tool (1) and / or measuring machine with a measuring system (5) according to one of the preceding Claims 1 to 6 or a measuring unit according to one of the preceding Claims 7 to 9 .

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