CN212379757U - Synchronous acquisition system for three-axis five-degree-of-freedom measuring head data of machine tool - Google Patents

Abstract

The utility model discloses a synchronous collection system of lathe triaxial five degree of freedom gauge head data, lathe triaxial five degree of freedom gauge heads divide into X axle gauge head, Y axle gauge head and Z axle gauge head, the axial measurement principle of three gauge head is the same, the X axle gauge head, Y axle gauge head and Z axle gauge head constitute by laser emission end and laser receiving end, the synchronous collection system of data includes power supply and control cabinet, host computer and numerical control system, laser emission end and laser receiving end all are connected through the shielding twisted pair line with power supply and control cabinet, power supply and control cabinet are connected through the serial port line with the host computer, the host computer passes through transmission line connection with numerical control system.

Description

Synchronous acquisition system for three-axis five-degree-of-freedom measuring head data of machine tool

Technical Field

The utility model belongs to lathe multi freedom error measurement data acquisition field, especially the data acquisition system of five degree of freedom gauge heads of lathe triaxial.

Background

The machine tool is a working master machine for machining, the multi-axis linkage high-precision numerical control machine tool and the like are important means for realizing high-efficiency high-quality machining, the machining precision is one of main indexes for reflecting the level of the national manufacturing industry, and the improvement of the precision of the machine tool by adopting an appropriate method has very important significance. The basic methods for improving the accuracy of the machine tool include an error prevention method and an error compensation method, wherein the error compensation method reduces an original error by measuring the original error of the machine tool and calculating a compensation amount through a machine tool error model algorithm. The method does not need to modify the existing hardware equipment, can reduce the hardware cost, and is economical and effective and high in compensation precision. The measurement of errors is the basis of an error compensation method, and a common numerical control machine tool is a three-axis machine tool and comprises 21 geometric errors, namely six-degree-of-freedom errors corresponding to all axes and orthogonal errors between every two axes. At present, there are many instruments for measuring machine tool errors at home and abroad, such as laser interferometers, laser tracking interferometers, ball rod instruments and the like, but the instruments cannot be integrated in a numerical control machine tool due to the factors of complex installation and adjustment process, long measurement period, high manufacturing cost, large volume and the like. Patent No. 2019109776237, in "a receiving and transmitting split type five-degree-of-freedom measuring device with optical path drift compensation" proposes a machine tool three-axis five-degree-of-freedom measuring head for realizing measurement based on laser collimation and auto-collimation principles, which can simultaneously measure machine tool three-axis five-degree-of-freedom errors and laser angle drift, and can be integrated in a numerical control machine tool. The principle is shown in fig. 1.

At present, a data acquisition system of a three-axis five-degree-of-freedom measuring head of a machine tool has the problem that real-time synchronous acquisition cannot be realized, acquired machine tool error information is not data at the same moment, the precision of machine tool space error calculation is influenced, and the wide application and popularization of the three-axis five-degree-of-freedom measuring head of the machine tool are hindered. In order to simultaneously acquire a plurality of angles and displacement data and analyze error information of multiple degrees of freedom of the machine tool, a plurality of measuring devices are required to simultaneously acquire data, so that each data acquisition system is required to set a uniform time reference, if the synchronization precision of each system is not high, the acquired data has large errors, and therefore the error compensation value obtained by resolving has large errors, and the machining precision requirement of the high-precision machine tool under the modern environment is difficult to meet. Meanwhile, a data acquisition system of the machine tool three-axis five-degree-of-freedom measuring head mostly utilizes a high-performance central processing unit in an upper computer to process, detect and analyze error signals. Although this processing method is simple, the cpu has a large computational burden and the high-performance cpu is expensive, which increases the cost of the detection system. Even if a high-performance central processing unit is used, the computing capability and computing resources of the high-performance central processing unit are very limited, so that an upper computer is difficult to simultaneously acquire, transmit and process machine tool error data of a plurality of channels.

The error acquisition of the machine tool is usually multi-channel data acquisition of a tiny angle or a tiny displacement, the change of an error signal is very weak, and a certain processing method is required to be used for amplifying the signal and filtering noise; the circuit of the acquisition system also has the characteristics of low drift and strong anti-interference capability; certain mutual interference exists among all sampling channels, and the stability of data acquisition and the accuracy of measurement are also influenced. Therefore, the development of a data acquisition method and system for machine tool error high-precision, multi-degree-of-freedom and real-time synchronous acquisition is of great significance.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the not enough among the prior art, provide a lathe triaxial five degree of freedom gauge head data synchronization acquisition system. The system has the functions of acquiring, amplifying and filtering micro signals, and simultaneously performs electromagnetic compatibility design on the system, so that the anti-interference capability is improved; the synchronous acquisition of the machine tool errors is realized, and the accuracy of machine tool space error calculation is improved. By the data multi-stage processing method, high-efficiency data processing is realized, and the real-time performance is improved.

The utility model aims at realizing through the following technical scheme:

a machine tool three-axis five-degree-of-freedom measuring head data synchronous acquisition system is characterized in that the machine tool three-axis five-degree-of-freedom measuring head is divided into an X-axis measuring head, a Y-axis measuring head and a Z-axis measuring head, the axial measurement principles of the three measuring heads are the same, the X-axis measuring head, the Y-axis measuring head and the Z-axis measuring head are all composed of a laser transmitting end and a laser receiving end, the data synchronous acquisition system comprises a power supply and control cabinet, an upper computer and a numerical control system, the laser transmitting end and the laser receiving end are both connected with the power supply and control cabinet through a shielded twisted pair, the power supply and control cabinet is connected;

the circuit part of the laser receiving end comprises three branches, wherein the first branch consists of a 1# four-quadrant detector, a 1# trans-impedance amplifier, a 1# low-pass filter, a 1# A/D converter, a 1# single chip microcomputer and a 4# single chip microcomputer which are sequentially connected; the second branch circuit consists of a 2# four-quadrant detector, a 2# trans-impedance amplifier, a 2# low-pass filter, a 2# A/D converter, a 2# single chip microcomputer and a 4# single chip microcomputer which are connected in sequence; the third branch circuit consists of a 1# position sensitive detector, a 3# trans-impedance amplifier, a 3# low-pass filter, a 3# A/D converter, a 3# single chip microcomputer and a 4# single chip microcomputer which are sequentially connected;

the circuit part of the laser emission end comprises two branches, wherein the first branch consists of a 2# position sensitive detector, a 4# trans-impedance amplifier, a 4# low-pass filter, a 4# A/D converter, a 5# single chip microcomputer and a 7# single chip microcomputer which are sequentially connected; the second branch circuit consists of a 3# position sensitive detector, a 5# trans-impedance amplifier, a 5# low-pass filter, a 5# A/D converter, a 6# single chip microcomputer and a 7# single chip microcomputer which are connected in sequence.

Furthermore, an 8# single chip microcomputer is arranged in the power supply and control cabinet.

Compared with the prior art, the utility model discloses a beneficial effect that technical scheme brought is:

(1) the utility model provides a lathe triaxial five degree of freedom gauge head multisensor data synchronization acquisition's problem, the error information that can real-time synchronization acquisition lathe carries out the space error and resolves, has improved the precision that the lathe space error resolved, provides reliable data support for the compensation of lathe error.

(2) The utility model discloses distribute data acquisition, data processing, synchronizing signal send task to singlechips at different levels, reduced the hardware requirement to the single chip microcomputer, improved the stability of data acquisition with handling, overcome the shortcoming that traditional lathe triaxial five degree of freedom gauge head data acquisition system needs high performance high-cost central processing unit simultaneously, reduced system cost.

(3) The system has simple structure and small volume, can be integrated in the numerical control machine tool and can directly communicate with the numerical control system, thereby overcoming the defects that the traditional machine tool error measuring system such as a laser interferometer, a ball rod instrument and the like can not be integrated with the machine tool and is difficult to be put into practical application.

Drawings

Fig. 1 is an overall structure diagram of a transmitting-receiving split type five-degree-of-freedom measuring head.

Fig. 2 is a schematic diagram of a machine tool three-axis five-degree-of-freedom measuring head data synchronous acquisition system.

Reference numerals: 1 is a laser, 2 is a first prism reflector, 3 is a first beam splitter, 4 is a second beam splitter, 5 is a third beam splitter, 6 is a # 1 four-quadrant detector, 7 is a first convex lens, 8 is a # 1 position sensitive detector, 9 is a second prism reflector, 10 is a fourth beam splitter, 11 is a # 2 four-quadrant detector, 12 is a second convex lens, 13 is a # 2 position sensitive detector, 14 is a third convex lens, 15 is a # 3 position sensitive detector, 16 is a laser emitting end, 17 is a laser receiving end, 18 is a # 1 transimpedance amplifier, 19 is a # 2 transimpedance amplifier, 20 is a # 3 transimpedance amplifier, 21 is a # 1 low pass filter, 22 is a # 2 low pass filter, 23 is a # 3 low pass filter, 24 is a # 1A/D converter, 25 is a # 2A/D converter, 26 is a # 3A/D converter, 27 is a # 1 singlechip, 28 is a # 2 singlechip, 29 is a # 3 singlechip, 30 is a # 4 singlechip, 31 is a # 4 transimpedance amplifier, 32 is a # 5 transimpedance amplifier, 33 is a # 4 low pass filter, 34 is a # 5 low pass filter, 35 is a # 4A/D converter, 36 is a # 5A/D converter, 37 is a # 5 singlechip, 38 is a # 6 singlechip, 39 is a # 7 singlechip, 40 is an X-axis measuring head, 41 is a Y-axis measuring head, 42 is a Z-axis measuring head, 43 is a # 8 singlechip, 44 is an upper computer, and 45 is a numerical control system.

Detailed Description

The present invention will be described in further detail with reference to the following drawings and specific embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The machine tool single-shaft five-degree-of-freedom measuring head is divided into a laser emitting end and a laser receiving end, as shown in fig. 1, the laser emitting end 16 and the laser receiving end 17 comprise optical parts, a laser 1 emits laser, the laser is reflected by a first prism reflector 2 and then divided into two laser beams through a first spectroscope 3, the laser penetrating through the first spectroscope 3 is divided into two laser beams through a second spectroscope 4, the laser penetrating through the second spectroscope 4 is divided into two laser beams through a third spectroscope 5, and the laser penetrating through the third spectroscope 5 irradiates a 1# four-quadrant detector 6, so that the measurement of horizontal straightness and vertical straightness is realized and is used as a two-dimensional straightness measurement result of the device; laser reflected by the third beam splitter 5 is focused on a 1# position sensitive detector 8 through a first convex lens 7, and measurement of a pitch angle and a yaw angle is achieved; laser reflected by the second beam splitter 4 is focused on the 2# position sensitive detector 13 through the second convex lens 12, and laser angle drift measurement penetrating through the second beam splitter 4 is realized; the laser reflected by the first spectroscope 3 is reflected by the second prism reflector 9, the laser reflected by the second prism reflector 9 is divided into two beams of laser after passing through the fourth spectroscope 10, the laser after passing through the fourth spectroscope 10 irradiates on the 2# four-quadrant detector 11, and the measurement of the horizontal straightness and the vertical straightness is realized, and the device only utilizes the vertical straightness of the 2# four-quadrant detector 11 and combines the vertical straightness of the 1# four-quadrant detector 6 to realize the roll angle measurement; the laser reflected by the fourth spectroscope 10 is focused on the 3# position sensitive detector 15 through the third convex lens 14, so that the measurement of the laser angle drift through the fourth spectroscope 10 is realized;

meanwhile, when the laser penetrating through the second spectroscope 4 drifts, the measurement of a pitch angle, a yaw angle, horizontal straightness, vertical straightness and a roll angle is influenced; when the laser passing through the second spectroscope 10 drifts, the vertical straightness measurement at the 2# four-quadrant detector 11 is influenced, and further the roll angle measurement is influenced; the measurement light path angle drift can be compensated by the change of the light spot positions on the 2# position sensitive detector 13 and the 3# position sensitive detector 15.

The embodiment provides a machine tool three-axis five-degree-of-freedom measuring head data synchronous acquisition system, wherein the machine tool three-axis five-degree-of-freedom measuring head is divided into an X-axis measuring head 40, a Y-axis measuring head 41 and a Z-axis measuring head 42, the axial measurement principle of the three measuring heads is the same, the X-axis measuring head, the Y-axis measuring head and the Z-axis measuring head are all composed of a laser transmitting end 16 and a laser receiving end 17, the data synchronous acquisition system comprises a power supply and control cabinet, an upper computer 44 and a numerical control system 45, an 8# single chip microcomputer 43 is arranged in the power supply and control cabinet, the laser transmitting end 16 and the laser receiving end 17 are both connected with the power supply and control cabinet through shielding multi-strand twisted pairs, the power supply and control.

The circuit part of the laser receiving end comprises three branches, wherein the first branch consists of a 1# four-quadrant detector 6, a 1# trans-impedance amplifier 18, a 1# low-pass filter 21, a 1# A/D converter 24, a 1# single chip microcomputer 27 and a 4# single chip microcomputer 30 which are sequentially connected;

the second branch circuit consists of a 2# four-quadrant detector 11, a 2# trans-impedance amplifier 19, a 2# low-pass filter 22, a 2# A/D converter 25, a 2# single chip microcomputer 28 and a 4# single chip microcomputer 30 which are connected in sequence;

the third branch consists of a 1# position sensitive detector, a 3# trans-impedance amplifier 20, a 3# low-pass filter 23, a 3# A/D converter 26, a 3# single chip microcomputer 29 and a 4# single chip microcomputer 30 which are connected in sequence;

the circuit part of the laser emitting end 16 comprises two branches, wherein the first branch consists of a 2# position sensitive detector 13, a 4# trans-impedance amplifier 31, a 4# low-pass filter 33, a 4# A/D converter 35, a 5# single chip microcomputer 37 and a 7# single chip microcomputer 39 which are connected in sequence; the second branch circuit consists of a 3# position sensitive detector 15, a 5# trans-impedance amplifier 32, a 5# low-pass filter 34, a 5# A/D converter 36, a 6# single chip microcomputer 38 and a 7# single chip microcomputer 39 which are connected in sequence.

Specifically, the method for synchronously acquiring the three-axis five-degree-of-freedom measuring head data of the machine tool according to the synchronous acquisition system comprises the following steps:

(1) and when the machine tool three-axis five-degree-of-freedom measuring head works, the sensor 1# four-quadrant detector 6, the sensor 2# four-quadrant detector 11, the sensor 1# position sensitive detector 8, the sensor 2# position sensitive detector 13 and the sensor 3# position sensitive detector 15 acquire error signals of the machine tool and convert the error signals into current signals.

(2) And the 1# transimpedance amplifier 18, the 2# transimpedance amplifier 19, the 3# transimpedance amplifier 20, the 4# transimpedance amplifier 31 and the 5# transimpedance amplifier 32 convert the current signal collected by the sensor into a voltage signal.

(3) And the voltage signals collected by the transimpedance amplifier are filtered by the 1# low-pass filter 21, the 2# low-pass filter 22, the 3# low-pass filter 23, the 4# low-pass filter 33 and the 5# low-pass filter 34, so that the aliasing of the signals is prevented.

(4) The 1# A/D converter 24, the 2# A/D converter 25, the 3# A/D converter 26, the 4# A/D converter 35 and the 5# A/D36 conversion modules collect the voltage signals output by the transimpedance amplifier and convert the voltage signals into corresponding digital signals.

(5) And the 1# singlechip 27, the 2# singlechip 28, the 3# singlechip 29, the 5# singlechip 37 and the 6# singlechip 38 are used for collecting the digital signals output by the A/D converter and performing digital filtering processing.

(6) And the user operates the program of the upper computer 44, and the upper computer 44 sends an acquisition starting instruction to the 8# single chip microcomputer 43.

(7) And the 8# singlechip 43 sends a synchronous acquisition instruction to the 4# singlechip 30 and the 7# singlechip 39 after receiving the acquisition start instruction number.

(8) After receiving the synchronous acquisition instruction, the 4# single chip microcomputer 30 sends the synchronous acquisition instruction to the 1# single chip microcomputer 27, the 2# single chip microcomputer 28 and the 3# single chip microcomputer 29; and after receiving the synchronous acquisition instruction, the 7# single chip microcomputer 39 sends the synchronous acquisition instruction to the 5# single chip microcomputer 37 and the 6# single chip microcomputer 38.

(9) The 1# single chip microcomputer 27, the 2# single chip microcomputer 28 and the 3# single chip microcomputer 29 synchronously send the acquired machine tool error information to the 4# single chip microcomputer 30 in real time after receiving the synchronous acquisition instruction; after receiving the synchronous acquisition instruction, the 5# single chip microcomputer 37 and the 6# single chip microcomputer 38 synchronously transmit the acquired compensation information to the 7# single chip microcomputer 39 in real time.

(10) And after the 4# singlechip 30 and the 7# singlechip 39 acquire the error information and the compensation information, an acquisition completion instruction is sent to the 8# singlechip 43.

(11) And the 7# singlechip 43 sends an acquisition completion instruction to the upper computer 44 after receiving the acquisition completion instruction sent by the 4# singlechip 30 and the 7# singlechip 39.

(12) And the upper computer 44 sends a data reading instruction to the 4# single chip microcomputer 30 and the 7# single chip microcomputer 39 after receiving the acquisition completion instruction sent by the 8# single chip microcomputer 43.

(13) And the 4# single chip microcomputer 30 and the 7# single chip microcomputer 39 start to send data to the upper computer 44 after receiving the data reading instruction sent by the upper computer 44.

(14) And after the upper computer 44 reads the machine tool error information sent by the 4# single chip microcomputer 30 and the compensation information sent by the 7# single chip microcomputer 39, one-time data synchronous acquisition is completed.

(15) And the upper computer 44 obtains a compensation value through calculation of a machine tool error compensation model.

(16) And the upper computer 44 sends the compensation value to the numerical control system 45.

(17) And after receiving the compensation value sent by the upper computer, the numerical control system 45 controls the three-axis movement of the machine tool through an original point compensation method, completes the compensation of the three-axis five-degree-of-freedom error of the machine tool and reduces the three-axis five-degree-of-freedom error of the machine tool.

The present invention is not limited to the above-described embodiments. The above description of the embodiments is intended to describe and illustrate the technical solutions of the present invention, and the above embodiments are merely illustrative and not restrictive. Without departing from the spirit of the invention and the scope of the appended claims, the person skilled in the art can make many changes in form and detail within the teaching of the invention.

Claims (2)

1. A machine tool three-axis five-degree-of-freedom measuring head data synchronous acquisition system is characterized by comprising a power supply and control cabinet, an upper computer and a numerical control system, wherein the laser emission end and the laser receiving end are connected with the power supply and control cabinet through shielded twisted-pair lines;

the circuit part of the laser receiving end comprises three branches, wherein the first branch consists of a 1# four-quadrant detector, a 1# trans-impedance amplifier, a 1# low-pass filter, a 1# A/D converter, a 1# single chip microcomputer and a 4# single chip microcomputer which are sequentially connected; the second branch circuit consists of a 2# four-quadrant detector, a 2# trans-impedance amplifier, a 2# low-pass filter, a 2# A/D converter, a 2# single chip microcomputer and a 4# single chip microcomputer which are connected in sequence; the third branch circuit consists of a 1# position sensitive detector, a 3# trans-impedance amplifier, a 3# low-pass filter, a 3# A/D converter, a 3# single chip microcomputer and a 4# single chip microcomputer which are sequentially connected;

the circuit part of the laser emission end comprises two branches, wherein the first branch consists of a 2# position sensitive detector, a 4# trans-impedance amplifier, a 4# low-pass filter, a 4# A/D converter, a 5# single chip microcomputer and a 7# single chip microcomputer which are sequentially connected; the second branch circuit consists of a 3# position sensitive detector, a 5# trans-impedance amplifier, a 5# low-pass filter, a 5# A/D converter, a 6# single chip microcomputer and a 7# single chip microcomputer which are connected in sequence.

2. The system for synchronously acquiring the three-axis five-degree-of-freedom measuring head data of the machine tool according to claim 1, wherein an 8# single chip microcomputer is arranged in the power supply and control cabinet.

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