Cutting force measurement based on tool embedded Ni-chrome thin-film micro-sensors

WU Wen-ge, CHENG Yun-ping, DU Xiao-jun

(School of Mechanical and Power Engineering, North University of China, Taiyuan 030051, China)

CuttingforcemeasurementbasedontoolembeddedNi-chromethin-filmmicro-sensors

WU Wen-ge, CHENG Yun-ping, DU Xiao-jun

(SchoolofMechanicalandPowerEngineering,NorthUniversityofChina,Taiyuan030051,China)

Abstract：Cutting force measurement has become a crucial activity for enhancing machining process performance.This paper described the design and fabrication of embedded Ni-chrome thin-film micro-sensors in tool holders to measure the cutting force in machining operations.A Ni-chrome thin-film sensor device is embedded within a substrate structure through a dynamic brazing process, which consists of a Ti6Al4V substrate, a nickel-chromium thin-film sensor and an alumina insulating layer.The Wheatstone bridge which consists of four sensors would produce the output voltage when the thin film caused deformation by the cutting forces.The relationship between input and output voltages was theoretically analyzed.Accordingly, an in-process cutting force measurement system is established.The results show that the thin-film sensor had good linearity and less mutual interference, and it is suitable for all kinds of turning forces under the measurement conditions.

Key words：thin-film micro-sensor; cutting force measurement; theoretical analysis

CLDnumber： TP212; TG806Documentcode： A

The measured cutting force information is essential to monitoring the operational status of the equipment, determining the process regime, and improving the reliability, which contributes to better quality products and higher productivity.Recently, there have been significant advances in the area of micro-sensors technology.Because small-size micro-sensors respond more quickly than ordinary macro-sensors, thermo-mechanical responses can be measured very efficiently by using thin-film micro-sensors due to some advantages of the absence of adhesive material, flexibility to tailoring the properties of the sensor material in thin-film form, good linearity, improved strain sensitivity, and fast response[1-3].There are reports about micro-fabrication and characterization of metal-embedded thin-film thermo-mechanical micro-sensors applyied in hostile manufacturing environments[4].Moreover, the micro thin-film thermocouple sensors are embedded into poly-crystalline cubic boron nitride (PCBN) tool insert to study the tool behavior[5].

In this paper, we present a new approach that embeds thin-film mechanical micro-sensors into metal substrates to measure the cutting forces.The system design is discussed in details.

1 Configuration of measurement system

Generally, an in-process cutting force measurement system contains an embedded thin-film mechanical micro-sensors cutting tool system, signal amplification circuit, signal processing and status recognition functional modules, as shown in Fig.1.

Fig.1 Configuration of cutting force measurement system

Cutting forces' effects on cutting tools will result in a deflection of the strain gauge, and the developed strain makes the resistance of the gauge change.The change in the resistance of each sensor element is detected as change in the output voltage of a Wheatstone bridge circuit.The all output voltages of the bridge circuit are sent to a PC through an amplifier and signal processing and status recognition functional modules.The embedded thin-film mechanical microsensors cutting tool system is shown in Fig.2.The microfabrication and characterization of tool embedded thin-film mechanical microsensors are vital techniques.As depicted in Fig.2, the tool system is typically made up of a holder, inserts, micro-sensors, wires, etc.It will be described in detail in the following.

Fig.2 Diagram of embedded thin-film mechanical micro-sensors cutting tool systems within Cartesian coordinate system

2 Design of thin-film micro-sensor

The thin-film micro-sensor consists of four layers: the substrate, insulating layer, strain gauge layer and covering layer, as shown in Fig.3.

Fig.3 Structure of sensor unit layers

Ti6Al4V titanium alloy substrate as selected due to its excellent performance.Thin-film sensors should be fabricated on an insulating layer.The selection of insulating films is crucial to sensor survival and stability.This layer will isolate the sensor electrically from the underlying metallic substrate and from the final protective embedding layer.Electron beam evaporated Al2O3film was found as an insulating layer due to its excellent thermal stability and good thermal coefficient matching with metal substrates[6].Initially, 0.5 μm thick aluminum oxide membrane layer was deposited by magnetron sputtering.On top of this layer, a thin layer of nichrome (NiCr 80/20 wt.%) was deposited using magnetron sputtering and patterned to form the strain gauge layer.The thin-film strain gauge was designed.The layout of thin-film and size diagram of cell were designed[7].The size and parameters of designed micro-sensors model are shown in Table 1.

Table1Sizeandparametersofdesignedmicro-sensorsmodel

ParameterLength(mm)Width(mm)Thickness(mm)Ti6Al4V substrate18180.8Ti6Al4V elastic diaphragm18181Nickel-chromium thin film--400 nmAlumina insulating layer18180.005

The entire fabrication of micro-sensor was performed in class 100 and 1 000 clean rooms.Fig.4 shows the thin-film sensors on Ti6Al4V substrate before embedded.The substrate size is 50 mm circular base tab separated with wire-electrode cutting process into the required size as 18 mm×18 mm.

Fig.4 Thin-film sensors on Ti6Al4V substrate (before embedded)

One micro-sensor cell is made up of four gauge elements and every gauge element has two electrodes.As Fig.3 shows, one sensor element is mounted onto the upper surface of cutting tool holder in proper position.The other sensor element is mounted under the surface of holder.In the same way, the left and right surface of holder have one sensor, respectively.Finally, the thin-film micro-sensors were bonded with holder through ultrasonic welding and brazing process.

Four strain gauges are connected in a half-Wheatstone or full-Wheatstone bridge circuit arrangement.As the force is applied on the strain gauge, the membrane deflects inducing strain across the bridge arms, which in turn results in a change in the resistance on the bridge arm.When there is any small change in the resistances of the bridge arms, the output voltage will not be nonzero.The Wheatstone bridge circuit in the device was electrically connected, as shown in Fig.5.

Fig.5 Schematic of Wheatstone bridge circuit

Four strain gauges with resistances ofR1,R2,R3andR4, respectively, are defined asRwith equivalent resistance when Wheatstone bridge circuit is in balance.Identical initial voltage was loaded on the four sensor units, when the input voltageUinwas loaded, the relationship betweenUinandUoutcan be defined as

(1)

As depicted in Fig.2, when the tangential force (Zdirection force) was loaded on the external turning tool tip, the resistance would change, and the Eq.(1) can be rewritten as

(2)

When the axial force (Xdirection force) and the radial force (Ydirection force) were loaded on the external turning tool tip, respectively, the relationship between input and output voltages is

(3)

(4)

The output voltage caused by the forcesFZandFYcan be measured through No.1 sensor (on the upper surface of holder) and No.2 sensor (under the surface of holder), and the output voltage caused by the forceFXandFYcan be measured through No.3 sensor (left surface of holder) and No.4 sensor (right surface of holder).Each component force can be calculated according to the output voltage measured by four sensors.

3 Conclusion

This paper describes the fabrication, embedding, and characterization of the metal embedded thin-film micro-sensors for turning force measurements.Thin-film mechanical micro-sensors have been successfully fabricated and embedded into tool structures by ultrasonic welding and brazing.Thin-film mechanical micro-sensors have high sensiuivity and linearity.We should note the differential output of the micro-sensors, which refers to the amount of bending, torsion and tension passing through the tool tip at the cutting point.The real tri-axial force values need further experimental investigation by the configuration of the cutting force measurement systems.

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刀具嵌入鎳鉻合金薄膜微傳感器切削力測(cè)量的研究

武文革， 成云平， 杜曉軍

(中北大學(xué) 機(jī)械與動(dòng)力工程學(xué)院， 山西 太原 030051)

摘 要:切削力的測(cè)量旨在改進(jìn)和提高切削加工性能。 本文設(shè)計(jì)和制備了一種鎳鉻合金薄膜微傳感器， 將其焊接嵌入刀具的刀桿上以測(cè)量加工中的切削力。 該傳感器由Ti6Al4V鈦合金基體、 鎳鉻合金薄膜層及氧化鋁絕緣層組成。 切削力引起的薄膜變形使四個(gè)電阻柵組成的惠斯通電橋產(chǎn)生輸出電壓， 對(duì)其輸入和輸出電壓之間的關(guān)系進(jìn)行了理論分析。 構(gòu)建了切削力測(cè)量系統(tǒng)。 研究結(jié)果表明， 該薄膜傳感器具有良好的線性度和更小的相互干擾， 適合于各種條件下車削力的測(cè)量。

關(guān)鍵詞:薄膜傳感器； 切削力測(cè)量； 理論分析

引用格式：WU Wen-ge, CHENG Yun-ping, DU Xiao-jun.Cutting force measurement based on tool embedded Ni-chrome thin-film micro-sensors.Journal of Measurement Science and Instrumentation, 2014, 5(4): 16-19.[doi: 10.3969/j.issn.1674-8042.2014.04.004]

Article ID：1674-8042(2014)04-0016-04

10.3969/j.issn.1674-8042.2014.04.004

Receiveddate： 2014-07-25

Research Project Supported by Shanxi Scholarship Council of China (No.2013-086)

Corresponding author：WU Wen-ge (3wwwg@163.com)