FR3137317A1 - process of assembling parts by homogeneous diffusion welding. - Google Patents

Abstract

Assembly process by homogeneous diffusion welding Process comprising the diffusion welding of a stack of parts of which at least two parts in contact are made of the same alloy, the alloy presenting: - an absence of abnormal grain enlargement continued to a first reference heat treatment carried out under thermal conditions identical to the thermal conditions of diffusion welding, - a fully recrystallized microstructure with an average equivalent grain size of less than 50 µm following a second reference heat treatment which successively comprises a heating of the alloy identical to the heating of the diffusion welding rise phase, and quenching, and - an average equivalent grain size at the end of the first reference heat treatment greater than or equal to 1.5 times size of average equivalent grain at the end of the second reference heat treatment. No figure for the abstract

Description

process of assembling parts by homogeneous diffusion welding. Field of the invention

The present invention relates to a method for producing an assembly, by diffusion welding, of parts made of the same material.

State of the art

Diffusion welding consists of bringing parts into contact and forming an assembly of these parts under the combined effect of compression and heating at a welding-diffusion temperature lower than the melting temperature of the the constituent alloy of the parts, generally greater than 0.7*T _f , T _f being the absolute melting temperature expressed in Kelvin.

“Welding-diffusion” includes in succession:

• a “rise” phase comprising heating and the application of a compressive force on the parts to be assembled,
• a “bearing” phase, comprising maintaining the force at the welding-diffusion temperature for a suitable duration, then
• a “descent” phase comprising cooling and progressive removal of the compressive force, for example by depressurization, in particular up to atmospheric pressure.

Diffusion welding is said to be homogeneous when the parts are made of the same alloy.

The defined pores between the contacting parts are gradually removed during the welding-diffusion cycle.

The properties of the assembly obtained after the descent phase depend in particular on the state of the surfaces of the parts which are intended to be in contact during welding, as well as on the composition and microstructure of the alloy. .

For example, to assemble two plates by diffusion welding, it is known to take these plates from sheets having undergone straightening cold rolling, called "skin pass" in English. Such sheets have a surface condition suitable for diffusion welding. However, during diffusion welding of plates, abnormal grain growth is frequently observed which results in the formation of grains having a size which may be greater than ten times the average equivalent grain size of the alloy. Even if they are few in number, such large grains can drastically reduce the mechanical properties of the welded joint, such as creep resistance and fatigue resistance. This abnormal grain growth can in particular be attributed to the existence, before welding, of local gradients of elastic energy stored between the grains. During straightening cold rolling, certain grains more favorably oriented with respect to the direction of stress deform, thus accumulating numerous crystal defects and storing deformation energy, while others, oriented less favorably , do not deform or only slightly. At the diffusion welding temperature, the grain boundaries separating the deformed grains from the undeformed grains are then likely to move much faster than the grain boundaries separating grains of similar deformation, which results in a strong heterogeneity of growth of grain.

Furthermore, more generally, the abnormal growth of grains in an alloy can also be attributed to the reduction in the speed of movement of a grain boundary by fine second phase particles which tend to block the movement of part of the joints, anchoring them. This phenomenon, known as the Zener-Smith effect, appears when the particles are numerous and generally less than 1 µm in size. Anchored joints move little or not at all, while unanchored joints can move. The abnormal growth of grains in an alloy can also have other causes, linked for example to the existence of a texture or to the dragging of solutes by grain boundaries.

For alloys which exhibit phase transformations such as tool steels or martensitic steels, it is possible to regenerate a fine grain microstructure by appropriate heat treatments. For other alloys, such as austenitic steels, alloys based on nickel, aluminum or copper, regeneration of the microstructure by simple heat treatment is however impossible.

Finally, at the interface between the parts in contact, it is desired that the grain boundaries of the alloy of one of the parts move into the other part, and vice versa , crossing the interface under the effect of heating temperature. Such crossing contributes to the final homogenization of the microstructure of the welded assembly. However, poorly crossed interfaces can be observed, which have reduced mechanical properties, for example reduced creep resistance and/or fatigue resistance. The absence of crossing, or incomplete crossing, can have several origins. The crossing being dependent on the coarsening of the grains, the temperature and duration of the welding-diffusion must therefore be sufficiently high. Then, even if the conditions for grain enlargement are met, it can be observed that the grain enlargement does not or only minimally affect the interface, that is to say that the crossing is incomplete or even absent. Such a phenomenon can be observed when the interface contains numerous obstacles, such as pores and small inclusions originating from solid or gaseous contaminants present on the initial surfaces and/or in the welding atmosphere, or from particles forming spontaneously during welding from elements present in the material. These obstacles are responsible for a sort of Zener-Smith effect localized at the interface.

There is therefore a need for a process for producing an assembly by diffusion welding making it possible to overcome the aforementioned drawbacks.

The invention relates to a process comprising the diffusion welding of a stack of parts of which at least two parts in contact are made of the same alloy, the alloy having:

• an absence of abnormal grain enlargement following a first reference heat treatment carried out under thermal conditions identical to the thermal conditions of diffusion welding,
• a fully recrystallized microstructure with an average equivalent grain size of less than 50 µm following a second reference heat treatment which successively comprises heating of the alloy identical to the heating of the rise phase of welding-diffusion, and quenching, And
• an average equivalent grain size at the end of the first reference heat treatment greater than or equal to 1.5 times average equivalent grain size at the end of the second reference heat treatment.

Advantageously, the implementation of the method according to the invention results in an assembly having a homogeneous microstructure, in particular with a substantially monomodal distribution of grain size, and in which the interfaces have been substantially crossed by the grain boundaries during the welding. The assembly thus has good mechanical properties, including good creep resistance and good fatigue resistance. These mechanical properties result in particular from a non-excessive grain enlargement during diffusion welding.

The alloy has an irreversible grain enlargement from diffusion welding, that is to say it has a matrix which does not undergo phase transformation, during the descent phase or during a subsequent heat treatment to diffusion welding, such that a microstructure with finer grains than at the end of the bearing phase can be obtained.

Preferably, the alloy is chosen from austenitic or ferritic stainless steels, austenitic alloys based on nickel, austenitic alloys based on iron and nickel, and copper alloys, for example a structural hardening alloy.

The alloy may be an austenitic chrome-nickel stainless steel or an austenitic chrome-nickel-molybdenum stainless steel. Preferably, the alloy is an austenitic stainless steel not stabilized with titanium or niobium, preferably comprising by mass less than 0.01% of titanium and less than 0.02% of niobium. In particular, the alloy can be chosen from the grades of stainless steel designated in standard NF EN 10088-1:2014 under the numbers 1.43xy and 1.44xy, where x and y designate numerical characters.

The average equivalent grain size of the alloy can be determined, depending on the composition of the alloy, in accordance with the standards in force such as the standards NF EN ISO 643:2020, NF EN ISO 2624, NF A04-503 and the standard ASTM-E112-13(2021).

The alloy according to the invention ensures that in the assembly obtained by diffusion welding, the average equivalent grain size does not exceed a value that is too high with regard to the expected mechanical properties of the assembly while allowing partial or complete interfaces by grain boundaries.

The two parts can each have the shape of a plate and the interface of the assembly is defined by the large contacting faces of the plates. In particular, the thickness of at least one of the plates may be greater than or equal to 15 times the average equivalent grain size of the alloy at the end of the second reference heat treatment.

In particular, the thickness of each plate can be between 0.2 mm and 5 mm . Advantageously, the process according to the invention makes it possible to manufacture an assembly having a sufficient number of grains in its thickness and which thus has good mechanical properties. Each plate can have a ratio of its length to its thickness greater than 100, or even greater than 1000.

In a preferred mode of implementation, the assembly of the plates obtained by the process according to the invention is intended to form in whole or in part a plate exchanger heat exchanger or a reactor-exchanger.

Furthermore, the alloy is characterized by an absence of abnormal grain growth which can easily be observed, in particular after implementation of the first reference heat treatment. In particular, the process may include a preliminary step of carrying out the first reference heat treatment on a sample made of the alloy and different from the parts to be assembled.

The “thermal conditions” implemented to carry out the first reference heat treatment include at least the welding-diffusion temperature and the duration of the stage at the welding-diffusion temperature. They can also include the temperature rise speed to the welding-diffusion temperature and/or the cooling speed from the welding-diffusion temperature to a temperature significantly lower, for example 100°C, than that -this.

The first reference heat treatment is preferably carried out under atmospheric pressure. Preferably, during the first reference heat treatment, no external force is applied to the alloy. By “external force” we mean any force other than gravitational force. The first reference heat treatment and diffusion welding can be carried out in the same oven.

The absence of abnormal grain growth of the alloy can be observed by observing an image of the microstructure of the alloy taken by optical microscopy containing at least 1000 grains. Abnormal growth is observed when the 1% largest grains, in number, occupy more than 20% of the observed surface. The absence of abnormal growth following the first reference heat treatment allows us to anticipate that after welding-diffusion the assembly will present a homogeneous microstructure.

Furthermore, the alloy is characterized by an average equivalent grain size of less than 50 µm after implementation of the second reference heat treatment. In particular, the process may include a preliminary step of carrying out the second reference heat treatment on a sample made of the alloy and different from the parts to be assembled. The “thermal conditions” implemented to carry out the second reference heat treatment include at least: the speed of temperature rise to the welding-diffusion temperature, an absence of bearing and quenching, for example at a speed of cooling of at least 10°C/min.

The second reference heat treatment is preferably carried out under atmospheric pressure. Preferably, during the second reference heat treatment, no external force is applied to the alloy. The second reference heat treatment and the diffusion welding can be carried out in the same oven. The inventors have noted that an average equivalent grain size of less than 50 µm following the second reference heat treatment allows optimal crossing of the interface between the parts to be assembled while preventing the alloy from having, after welding-diffusion, a size of average grain equivalent too high.

At the end of the second reference heat treatment, the alloy preferably has an average equivalent grain size of less than 20 µm.

As mentioned above, the absence of abnormal grain enlargement following the first reference heat treatment can be noted by carrying out the first reference heat treatment on a sample.

Alternatively, it can be observed from the results of a plurality of tests, each test being carried out without application of an external force on a sample made of the alloy, and comprising maintaining the sample at a temperature and for a predetermined duration, the result of each of the tests including the observation of the absence of abnormal magnification.

Thus, by observing the absence of abnormal enlargement over all of the tests, it can be determined that the alloy presents an absence of abnormal grain enlargement following the first reference heat treatment, without carrying out said first heat treatment of reference.

For example, the temperature of at least one test may be lower than the welding-diffusion temperature and the temperature of at least one test may be higher than the welding-diffusion temperature and/or the duration of at least one test may be less than the duration of the welding-diffusion stage and the duration of at least one test may be greater than the duration of the welding-diffusion stage.

For example :
- the test presenting the lowest temperature may present a temperature of at most 50°C lower than the diffusion welding temperature and/or the test presenting the highest temperature may present a temperature of at most 50°C C greater than the diffusion welding temperature, and/or
- the test having the shortest temperature maintenance duration may have a duration of at most 0.5 h less than the duration of the diffusion welding stage and/or the test having the longest duration may have a duration at most 1 hour longer than the duration of the diffusion welding stage.

Furthermore, the average equivalent grain size following the first reference heat treatment and the average equivalent grain size following the second reference heat treatment can be measured by carrying out the first and second reference heat treatments respectively.

Alternatively, they can be determined from a model of evolution of the average equivalent grain size, the parameters of the model being identified by means of experimental data measured during the tests. It is thus possible to avoid carrying out the second reference heat treatment.

For example, the model of evolution of the average equivalent grain size can be governed at least by the equation

in which :
- is the initial average equivalent grain size,
- is the final average equivalent grain size after carrying out a test of a duration at the temperature , And
- And are parameters that depend on temperature .

Furthermore, the average equivalent grain size after implementation of the first reference heat treatment is greater than or equal to 1.5 times, or even greater than 2.5 times, the average equivalent grain size after implementation of the second treatment thermal reference. The inventors have thus noted that normal grain enlargement can take place during the diffusion welding maintenance phase, which therefore ensures the crossing of the interface between the parts to be assembled.

Preferably, after diffusion welding, the assembly has an average equivalent grain size of between 10 µm and 150 µm, preferably between 20 µm and 80 µm.

The duration of maintenance at the welding-diffusion temperature can be between 0.5 h and 6 h.The welding-diffusion temperature may in particular be greater than 0.7*T_f,T_fbeing the absolute melting temperature of the alloy. The “absolute temperature” is the temperature having as reference the absolute zero of the temperature (0 K).

The diffusion welding technique is preferably chosen from hot isostatic compression and hot uniaxial compression. It involves the compression of the assembly formed by the parts. The pressure applied to the parts during welding can be adapted depending on the composition of the alloy. In particular, it is high enough to ensure the closure of the interface between the parts and avoid the presence of pores in the assembly. Those skilled in the art routinely know how to choose such a pressure.

Furthermore, the process preferably comprises, prior to assembling the parts, cleaning at least one surface of each part and bringing the cleaned surfaces into contact. Cleaning can be carried out with a detergent, for example chosen from alkaline detergents with soda and acid detergents, and/or a solvent, for example chosen from oxygenated solvents, in particular acetone and/or alcohols, and halogenated solvents. The cleaned parts can then be rinsed and/or dried.

Preferably, the method further comprises the degassing of the at least one cleaned surface, and where appropriate rinsed and/or dried. Preferably, degassing is carried out by evacuating the parts in contact. Degassing can be carried out in situ , in the enclosure of the welding oven when the diffusion welding is carried out by hot uniaxial compression or by connecting fluid, to a vacuum pump, to a sealed container containing parts, when diffusion welding is carried out by hot isostatic compression.

The assembly obtained by the process according to the invention may have a structure of equiaxed and in particular recrystallized grains.

Furthermore, the process may involve bringing one of the parts into contact with a third part made of another alloy which is linked to the assembly.

Finally, the invention relates to the use of an assembly obtained by the process according to the invention in a plate heat exchanger or in a reactor-exchanger.

The invention is illustrated below by means of the following non-limiting examples and the figures in which:

is a photograph acquired by optical microscopy of a polished surface of a sample of the steel of Example 1 after rolling and recrystallization annealing,

is a photograph acquired by optical microscopy of a polished surface of a cross section of an assembly obtained by an example of implementation of the method according to the invention,

is a photograph acquired by optical microscopy of a polished surface of a cross section of an assembly obtained by the method outside the invention of Example 2.

Example 1

We have an austenitic stainless steel X2CrNiMo17-12-2 whose composition in mass percentages is given in table 1.

Fe VS NOT Mn If S P Cr Neither 100% complement 0.021 0.072 1.71 0.19 <0.001 0.021 17.4 12.2 MB Al Ti No. V Your B O 2.4 0.013 <0.001 0.003 0.046 <0.003 0.0002 0.0025

The steel was hot rolled to a thickness of 10mm and then reduced by 60% by cold rolling to form a 4mm thick plate. Then, it was maintained at 950 °C for 10 minutes in order to be completely recrystallized. At the end of this treatment, the average equivalent grain size is 6.2 µm and no abnormal grain enlargement is observed ( ).

The steel was then the subject of a study of its behavior in terms of grain coarsening in the experimental range of temperatures between 975°C and 1100°C and for temperature retention times of 16 hours at most. . No abnormal grain enlargement was observed during testing under any of the conditions tested. It was therefore deduced that steel is not subject to the phenomenon of abnormal enlargement in the experimental field considered, and that a homogeneous microstructure can be obtained after a heat treatment comprising heating to 1090°C followed by a step of 2 h, these conditions being part of the experimental domain.

This study also made it possible to model the evolution of the average equivalent grain size of the steel, by approximating this size according to the equation in which And are the initial and final average equivalent grain sizes measured respectively before and after a duration exposure at the temperature , And And are parameters that depend on , determined from the study measurements. This isothermal model can be used to estimate the magnification during heating, by approximating the heating curve by a succession of small isothermal steps.

Using this model, it was determined that following heating up to 1090°C corresponding to heating of the rise phase of a welding-diffusion cycle, without maintaining at 1090°C and followed by quenching ( that is to say corresponding to the second reference treatment), the average equivalent grain size reaches 28.4 μm and is therefore less than 50 μm. It was further determined by means of the model that following a first reference heat treatment carried out under the thermal conditions of diffusion welding and comprising a plateau lasting 2 hours at 1090°C, the average equivalent grain size is 46.2µm, or 1.75 times more than after the second reference heat treatment.

Subsequently, plates made of cold-rolled steel at 60% reduction then recrystallized at 950°C (as described above) were cleaned, degassed then assembled by diffusion welding by hot isostatic compression at a welding temperature of 1090 °C and under a pressure of 105 MPa for a period of 2 hours. After cooling, as observed on the , following diffusion welding, the steel within the assembly has a microstructure of equiaxed grains whose average equivalent size is 44.7 µm. The grain size distribution is substantially monomodal and the assemblage is free of abnormally sized grains. Furthermore, as observed in the , the interface between the two plates, whose position before assembly is indicated by the arrows, is no longer visible and has been crossed by the grain boundaries of each of the plates during welding. Such an assembly has excellent mechanical properties.

Example 2 comparison

We have an austenitic stainless steel X2CrNiMo17-12-2 whose composition in mass percentages is given in table 2.

Fe VS NOT Mn If S P Cr 100% complement 0.02 0.044 0.93 0.50 0.001 0.025 17.3 Neither MB Al Ti No. V B O 12.9 2.76 0.013 0.009 0.010 0.084 0.0013 0.0025

This steel was supplied in the form of 4 mm thick sheets after successively undergoing the following operations: hot rolling, cold rolling, recrystallization treatment at 1080°C followed by quenching, pickling, application of a light cold rolling pass called “skin pass”. This last operation implements a total deformation of 1 to 3% and therefore results in the presence of local gradients of stored elastic energy. The average equivalent grain size is 30 µm.

Two plates made of the alloy thus slightly deformed are assembled under welding conditions identical to those of Example 1.

After cooling, as observed on the , following diffusion welding, the steel presents a grain microstructure whose size distribution is substantially bimodal. Abnormal grain growth is noted. It results in the presence of very large grains of several hundred microns which harm the mechanical properties of the assembly.

Claims (15)

Process comprising the diffusion welding of a stack of parts of which at least two parts in contact are made of the same alloy, the alloy having:
- an absence of abnormal grain enlargement following a first reference heat treatment carried out under thermal conditions identical to the thermal conditions of diffusion welding,
- a fully recrystallized microstructure with an average equivalent grain size of less than 50 µm following a second reference heat treatment which successively comprises heating of the alloy identical to the heating of the rise phase of welding-diffusion, and quenching , And
- an average equivalent grain size at the end of the first reference heat treatment greater than or equal to 1.5 times average equivalent grain size at the end of the second reference heat treatment. Method according to claim 1, the alloy being chosen from austenitic or ferritic stainless steels, austenitic alloys based on nickel, austenitic alloys based on iron and nickel, and copper alloys, for example a hardening alloy structural. Method according to claim 2, the alloy being an austenitic stainless steel not stabilized with titanium or niobium, preferably comprising by mass less than 0.01% of titanium and less than 0.02% of niobium. Method according to any one of the preceding claims, the alloy having an average equivalent grain size of less than 20 µm at the end of the second reference heat treatment. Method according to any one of the preceding claims, the alloy having an average equivalent grain size at the end of the first reference heat treatment greater than or equal to 2.5 times the average equivalent grain size at the end of the second treatment thermal reference. Method according to any one of the preceding claims, the absence of abnormal grain enlargement following the first reference heat treatment being noted by carrying out the first reference heat treatment. Method according to any one of claims 1 to 6, the absence of abnormal grain enlargement following the first reference heat treatment being noted from the results of a plurality of tests, each test being carried out without application of a external force on a sample made of the alloy, and comprising maintaining the sample at a predetermined temperature and for a predetermined duration, the result of each of the tests including the observation of the absence of abnormal magnification. Method according to any one of the preceding claims, the average equivalent grain size following the first reference heat treatment and the average equivalent grain size following the second reference heat treatment being measured by carrying out the first and second reference heat treatments respectively. . Method according to claim 7, the average equivalent grain size following the first reference heat treatment and the average equivalent grain size following the second heat treatment being determined from a model of evolution of the average equivalent grain size, the model parameters being identified using experimental data measured during testing. Method according to claim 9, the model of evolution of the average equivalent grain size being governed at least by the equation:
in which :
- is the initial average equivalent grain size,
- is the final average equivalent grain size after carrying out a test of a duration at the temperature , And
- And are parameters that depend on temperature . Method according to any one of the preceding claims, the diffusion welding technique being chosen from hot isostatic compression and hot uniaxial compression. Method according to any one of the preceding claims, comprising, prior to assembling the parts, cleaning at least one surface of each part and bringing the cleaned surfaces into contact, and preferably degassing the at least one surface. cleaned, and where necessary rinsed and/or dried. Method according to any one of the preceding claims, the two parts each having the shape of a plate and the interface of the assembly being defined by the large contacting faces of the plates. Method according to the preceding claim, the thickness of at least one of the plates being greater than or equal to 15 times the average equivalent grain size of the alloy at the end of the second reference heat treatment. Use of an assembly obtained by the process according to any one of the preceding claims in a plate heat exchanger or in a reactor-exchanger.