EP4314683A1 - Dispositif de commande et procédé pour commander une installation et un processus de traitement thermique de pièces métalliques - Google Patents

Dispositif de commande et procédé pour commander une installation et un processus de traitement thermique de pièces métalliques

Info

Publication number
EP4314683A1
EP4314683A1 EP22722142.1A EP22722142A EP4314683A1 EP 4314683 A1 EP4314683 A1 EP 4314683A1 EP 22722142 A EP22722142 A EP 22722142A EP 4314683 A1 EP4314683 A1 EP 4314683A1
Authority
EP
European Patent Office
Prior art keywords
workpiece
workpieces
section
heating
control device
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
EP22722142.1A
Other languages
German (de)
English (en)
Inventor
Steffen Frank
Heike Liebe
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Aerospace Transmission Technologies GmbH
Original Assignee
Aerospace Transmission Technologies GmbH
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Aerospace Transmission Technologies GmbH filed Critical Aerospace Transmission Technologies GmbH
Publication of EP4314683A1 publication Critical patent/EP4314683A1/fr
Pending legal-status Critical Current

Links

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27BFURNACES, KILNS, OVENS OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
    • F27B9/00Furnaces through which the charge is moved mechanically, e.g. of tunnel type; Similar furnaces in which the charge moves by gravity
    • F27B9/02Furnaces through which the charge is moved mechanically, e.g. of tunnel type; Similar furnaces in which the charge moves by gravity of multiple-track type; of multiple-chamber type; Combinations of furnaces
    • F27B9/028Multi-chamber type furnaces
    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21DMODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
    • C21D1/00General methods or devices for heat treatment, e.g. annealing, hardening, quenching or tempering
    • C21D1/62Quenching devices
    • C21D1/673Quenching devices for die quenching
    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21DMODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
    • C21D1/00General methods or devices for heat treatment, e.g. annealing, hardening, quenching or tempering
    • C21D1/74Methods of treatment in inert gas, controlled atmosphere, vacuum or pulverulent material
    • C21D1/773Methods of treatment in inert gas, controlled atmosphere, vacuum or pulverulent material under reduced pressure or vacuum
    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21DMODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
    • C21D11/00Process control or regulation for heat treatments
    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21DMODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
    • C21D9/00Heat treatment, e.g. annealing, hardening, quenching or tempering, adapted for particular articles; Furnaces therefor
    • C21D9/0006Details, accessories not peculiar to any of the following furnaces
    • C21D9/0018Details, accessories not peculiar to any of the following furnaces for charging, discharging or manipulation of charge
    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21DMODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
    • C21D9/00Heat treatment, e.g. annealing, hardening, quenching or tempering, adapted for particular articles; Furnaces therefor
    • C21D9/0056Furnaces through which the charge is moved in a horizontal straight path
    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21DMODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
    • C21D9/00Heat treatment, e.g. annealing, hardening, quenching or tempering, adapted for particular articles; Furnaces therefor
    • C21D9/0062Heat-treating apparatus with a cooling or quenching zone
    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21DMODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
    • C21D9/00Heat treatment, e.g. annealing, hardening, quenching or tempering, adapted for particular articles; Furnaces therefor
    • C21D9/0068Heat treatment, e.g. annealing, hardening, quenching or tempering, adapted for particular articles; Furnaces therefor for particular articles not mentioned below
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27BFURNACES, KILNS, OVENS OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
    • F27B9/00Furnaces through which the charge is moved mechanically, e.g. of tunnel type; Similar furnaces in which the charge moves by gravity
    • F27B9/04Furnaces through which the charge is moved mechanically, e.g. of tunnel type; Similar furnaces in which the charge moves by gravity adapted for treating the charge in vacuum or special atmosphere
    • F27B9/042Vacuum furnaces
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D19/00Arrangements of controlling devices
    • F27D2019/0028Regulation
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D19/00Arrangements of controlling devices
    • F27D2019/0028Regulation
    • F27D2019/0059Regulation involving the control of the conveyor movement, e.g. speed or sequences
    • F27D2019/0062Regulation involving the control of the conveyor movement, e.g. speed or sequences control of the workpiece stay in different zones

Definitions

  • the invention relates to a control device and a method for controlling a system and a process for the heat treatment of metal workpieces, in particular transmission components.
  • the invention also relates to a press hardening system controlled by such a control device, in which a hardening furnace and a hardening press are used to carry out a quenching procedure under tension on the workpiece.
  • the heat treatment of metallic workpieces is known from the prior art.
  • the well-known basic principle of heat treatment is that metallic workpieces are heated and then hardened by quenching.
  • the invention is based on the object of creating solutions which, in the context of a heat treatment that can be carried out advantageously in terms of process technology, result in advantages over previous approaches with regard to the heating of the workpieces.
  • This object is achieved according to a first aspect of the present invention by a control device for controlling a process for heat treatment of metal workpieces using a hardening furnace comprising a heating section for heating workpieces and a discharge section for discharging workpieces from the hardening furnace and a hardening press , wherein the output section can be heated and the control device is designed in such a way that it coordinates the transport of workpieces through the heating section in such a way that there is a defined heating-up residence time for the respective workpiece in the heating section, the transfer of heated workpieces from the heating section to the Output section coordinates such that this transfer takes place at the end of the heating residence time and for the output section a heating power supply coordinates such that in the output section there is a workpiece warm maintenance at a defined temperature level
  • the heating dwell time i.e. the dwell time of the workpiece in the heating section, is preferably adjusted in such a way that the temperature of the workpiece is adequately adjusted to a target temperature defined by the furnace temperature of the heating section.
  • the heating section can have zones with different heating power, so that in particular the initial heating of the workpiece takes place with a temperature gradient that does not exceed a defined limit value.
  • the control device is preferably configured in such a way that before the start of a quenching process, at least one workpiece heated within the heating dwell time in the heating section with a defined thermal energy input history is then kept warm for a specified and documented time in the output section without significant temperature change gradients. Keeping the workpiece warm in the output section is also part of the workpiece-specific thermal history with regard to the dwell time and the atmospheric conditions in the output section.
  • the control device according to the invention is furthermore preferably designed in such a way that at least one workpiece is heated in the heating section, while at least one workpiece is kept warm in the output section. As a result, immediately after a workpiece has been removed from the output section, a workpiece can be conveyed from the heating section to the output section in close cycle sequence.
  • the hardening furnace is preferably designed in such a way that its heating section can accommodate a plurality of workpieces.
  • the control device is preferably designed in such a way that the workpieces are moved through the hardening furnace in such a way that more workpieces are heated in the heating section than are kept at a target output temperature in the output section. As a result, the heating in the heating section can be stretched out in a defined manner over time and a high throughput rate through the heating section nevertheless results.
  • the control device is preferably designed in such a way that it controls all of the actions relevant to the workpiece flow through the hardening furnace.
  • the control device can, in particular, activate a lock device provided between the heating section and the output section, in order to release a workpiece throughput path and to close it.
  • the control device can also activate a lock device provided between the heating section and an upstream input section, likewise for releasing a workpiece throughput path and for the controlled closing of the same.
  • Predetermined time concepts can be implemented for this control.
  • the control device can thus control the lock devices in such a way that the lock devices are alternately opened and closed. In this case, the heating section communicates only with the output section or the input section, respectively.
  • the control device is configured in such a way that it controls an output opening device of the output section in order to assume an open position that enables a workpiece to be output from the output section and a closed position in which an interior area of the output section is sealed off from the environment.
  • the control device ensures that the dispensing opening device is only in one state of the dispensing section is opened, in which this is sealed off from the heating section by a closed lock device.
  • the control device is preferably also configured such that it controls an input opening device of the input section to adopt an open position that enables a workpiece to be input into the input section and a closed position in which an interior area of the input section is sealed off from the environment.
  • the control device can advantageously ensure that the input section can only be charged with a workpiece when it is sealed off from the heating section.
  • the hardening furnace is preferably designed as a continuous furnace and the workpieces or batches of workpieces are conveyed therein along a passageway, with the conveyance of the workpieces or batches of workpieces along the passageway being coordinated by the control device.
  • this passageway can be a substantially straight, stretched path, or else a curved path, in particular a circular path.
  • the continuous furnace is preferably designed as a vacuum furnace and the keeping of the workpiece at the target temperature in the discharge section is divided into two phases according to the control device.
  • the first phase can represent keeping warm at a pressure level below ambient pressure and the second phase can represent keeping warm at a pressure equal to ambient pressure in the dispensing section.
  • control device can preferably coordinate the keeping warm in the dispensing section in such a way that the time component of keeping warm at reduced pressure outweighs the time component of keeping warm at equalized pressure. This protects the workpiece from atmospheric influences for a relatively long time while it is being kept warm.
  • control device preferably takes on several control and regulating tasks relating to the operation of the hardening furnace.
  • control device preferably controls/regulates the temperature and/or the pressure in the heating section and/or the input section and/or the output section.
  • the heating section can advantageously be subdivided into successive heating zones.
  • the control device can be configured in such a way that it controls or also regulates the heating output of the respective heating zone.
  • the thermal history of the workpiece is preferably determined by the temperatures in the respective heating zones, as well as by the dwell time in that zone or throughput speed through that zone.
  • the thermal history of a workpiece in the heating section is preferably reproduced identically for a specific workpiece, the dwell time in the output section can vary within a certain maximum holding time window, provided that the holding is divided into a vacuum phase and an ambient pressure phase as stated above, the time extension is preferably realized within the vacuum phase and the ambient pressure phase is kept constant so that the reactive phase of the holding is workpiece-specifically constant.
  • the input section and the output section each form a lock chamber and the control device adjusts the functions of these lock chambers, in particular the communication with the heating section, the opening and closing to the outside, the pressure in the sections of the hardening furnace, the temperatures, the residence times and Transport speeds and / or the composition of the gas atmosphere in the furnace sections.
  • temperature values of the workpiece are preferably recorded in the heating section and/or in the output section.
  • the control device is preferably designed in such a way that it takes into account and preferably also documents the recorded temperature values for the transfer of the workpiece through the continuous furnace and the transfer to the hardening press.
  • the object specified at the outset is also achieved according to the invention by a method for controlling a process for the heat treatment of metallic workpieces, using a hardening furnace which comprises a heating section and a discharge section and a hardening press, wherein: the transport of workpieces by the heating section is adjusted in such a way that there is a defined heating-up dwell time in the heating section for the respective workpiece, the transfer of heated workpieces from the heating section to the output section is adjusted in such a way that this transfer takes place when the heating-up dwell time has elapsed a supply of heating power to the output section is adjusted in such a way is that a workpiece is kept warm in the output section at a defined temperature level.
  • the heating output in the dispensing section can advantageously be increased to an extent when the dispensing section is opened to the environment, which compensates for the heat loss through the opening of the dispensing section. As a result, a drop in the workpiece temperature after opening the output section is prevented in a defined manner.
  • the solution concept according to the invention makes it possible to ensure a high level of reproduction accuracy in terms of the microstructure and the geometry of correspondingly heat-treated workpieces as part of a heat treatment that can be carried out advantageously in terms of process technology.
  • the invention also includes a method for the heat treatment of metallic workpieces, in particular transmission components, in which carburized metallic workpieces are introduced into a means for heating workpieces and are heated therein, the means for heating workpieces being designed as a continuous furnace and workpieces being placed in the Continuous furnace are introduced through a first opening device and removed from the continuous furnace through a second opening device spaced apart from the first opening device, wherein workpieces are introduced into a means for hardening after removal for hardening.
  • the first opening device serves to release or close a furnace entrance area.
  • the second opening device is used to open or close a furnace exit area.
  • the method according to the invention comprises the steps of introducing the workpieces into the hardening furnace via the furnace entrance area and conveying the workpieces through a heating section of the hardening furnace to the furnace exit area.
  • the means for hardening can also be referred to as a hardening press.
  • the means of hardening can also be referred to as a quenching press.
  • the heating means can also be referred to as a curing oven.
  • the transfer of the workpieces into the hardening press by the handling system and the implementation of the quenching process by the hardening press form a process step group that is processed in a program-technically defined time frame.
  • This processing in a time frame defined by the program can enable a particularly high reproduction accuracy, ie also a constant quality of the workpieces.
  • a particularly high level of reproduction accuracy can also be made possible by operating the handling system in such a way that a programmatically secured temporal temperature profile of the workpiece results for the transfer of the workpiece from the output device into the hardening press.
  • a high degree of reproduction accuracy can also be possible if the handling system is operated in such a way that the workpiece is brought into contact with gas in a programmed manner for the transfer of the workpiece from the output device into the hardening press.
  • a handling system which is arranged in an intermediate area between the output device and the hardening press.
  • the transfer process is activated with a ready signal from the hardening press.
  • the workpieces can be moved in a controlled manner, which can have an advantageous effect on high reproduction accuracy.
  • a transfer or transfer process can also be understood as transport or transport process and can be designated accordingly.
  • the transfer process can only be initiated when the hardening press is in a ready state. It can be avoided that workpieces to means to Hardships to be spent, although this is not operational. In this respect, it is possible to prevent individual workpieces from cooling down, in particular while they are being transported and waiting for the agent to be ready for hardening. A transfer process can therefore only enable a consistent quality of all workpieces when the hardening press is in a state of readiness.
  • a signal confirming the completion of the transfer process starts the press hardening process. This means that hardening can be started under controlled conditions and the treated workpieces can be of consistent quality.
  • the workpiece may be picked up in the exit area of the hardening furnace as soon as the workpiece has reached a defined thermal state.
  • a defined thermal state can be attainable for all workpieces that are treated and thus make a significant contribution to the high reproduction accuracy of the method.
  • the workpiece is exposed to a quenching medium in a way that is defined in terms of programming and coordinated by adjusting means.
  • a quenching medium in a way that is defined in terms of programming and coordinated by adjusting means.
  • Such controlled quenching conditions can be another essential component for a high reproducibility of the process.
  • the workpieces are brought into the hardening furnace via a handling system and the heating of the workpieces as they pass through the hardening furnace is recorded by measurement .
  • the method according to the invention is preferably carried out in such a way that at least one workpiece is heated in the heating section while at least one workpiece is kept warm in the exit area. As a result, the number of workpieces that are treated can be increased.
  • the method can also be processed in such a way that a workpiece is also preheated in the input area. This allows the residence time in the heating section to be reduced. Further, according to the method of the present invention, preferably, a negative pressure or a vacuum is set and maintained in the heating section while a workpiece is fed out from the furnace exit section. For this purpose, the workpiece is guided through a lock device provided between the heating section and the furnace exit area, and the pressure in the exit area is alternately lowered and then brought back into line with the ambient pressure.
  • the workpiece preheating in the input area can be limited to a temperature at which there is still no significant reaction of the workpiece surface with the gas atmosphere in the input area.
  • the method according to the invention is also preferably carried out in such a way that a pressure below the ambient pressure, in particular a vacuum, prevails in the heating section even during the introduction of a workpiece into the furnace entrance area.
  • the workpiece is guided through a lock device located between the furnace entrance area and the heating section.
  • the pressure in the furnace entrance area is also alternately lowered and adjusted to the ambient pressure. Direct communication between the heating section and the environment is avoided as part of the workpiece heating operation of the hardening system by coordinating the opening and closing of the locks and the opening devices.
  • the pressure control in the sections of the continuous furnace that can be sealed off selectively from one another, as well as the temperature control in these sections, is regulated or at least controlled in accordance with a coordinated process control.
  • the device provided for carrying out this method comprises at least one means for heating workpieces and also at least one means for hardening workpieces, wherein:
  • the at least one means for heating workpieces is designed as a continuous furnace, through which the workpieces can be conveyed in a direction of flow, the continuous furnace has an input section, a heating section and an output section, the workpieces can be introduced into the input section via a first opening device, the workpieces can be discharged from the output section via a second opening device, the output section comprises an output chamber and the output chamber can be closed in a controlled manner with respect to the heating section and the means for hardening the workpiece.
  • the furnace acts as a transport system through which the components are heated as part of their transport to the entry area of the quenching agent.
  • this results in a local offset of a cold zone in front of the furnace, which is used for the introduction of the workpiece, from a hot zone facing the means for hardening. This results in an elongation of an overall system formed including the device according to the invention.
  • the device according to the invention thus makes it possible to coordinate the sequential steps of heating and hardening with one another, as a result of which a consistent quality of the correspondingly heat-treated workpieces and thus high reproduction accuracy can be achieved.
  • the continuous furnace is preferably designed in such a way that it comprises at least one entry chamber, which forms the entry section.
  • the input chamber and the output chamber are coupled to each other by a workpiece transport path passing through the heating section.
  • the workpieces are preferably conveyed through the continuous furnace in connection with workpiece carriers.
  • the workpieces can be brought into the input chamber through the first opening device, preferably in conjunction with an associated workpiece carrier.
  • the workpieces are preferably conveyed on the workpiece transport path by a transport mechanism.
  • This transport mechanism can be designed in such a way that it conveys the workpieces in connection with the workpiece carriers.
  • the workpieces can be removed from the output chamber through the second opening device.
  • the workpiece carriers are preferably conveyed back to the input section.
  • the heating section is preferably dimensioned in such a way that a number of workpieces can be arranged in successive stations in this heating section.
  • the workpieces can be conveyed through the heating section by successively advancing the workpiece carriers.
  • the input chamber and the output chamber are preferably designed in such a way that they each have only one workpiece or a workpiece carrier with one or more on it accommodate arranged workpieces.
  • the workpiece carriers can in particular be made of a ceramic or heat-resistant metallic material.
  • the material carriers are handled automatically after they leave the output chamber. As part of this handling, they are cleaned in the form of blowing off, brushing and/or washing. It is possible to convey the workpiece carriers back to the input area of the continuous furnace in a temperature-controlled state and to bring the workpieces or the workpiece into the continuous furnace in connection with a workpiece carrier that has been preheated in a defined manner.
  • At least one further chamber is preferably provided.
  • This further chamber preferably forms the heating section.
  • the communication of the further chamber with the input chamber and/or with the output chamber can be established and interrupted in a switchable manner.
  • doors, flaps or slide structures are preferably provided, which switchably separate the heating section from the input chamber upstream in the workpiece transport direction and the output chamber downstream in the workpiece transport direction.
  • the continuous furnace is preferably designed as a vacuum continuous furnace, with a vacuum being able to be applied at least in the input chamber and/or in the output chamber and/or in the at least one further chamber, with the vacuum being preferably chamber-specifically controllable.
  • At least one means is provided for interrupting communication, in particular for closing at least one section between the input chamber and output chamber and/or between the input chamber and the at least one additional chamber and/or between the at least one additional chamber and the output chamber.
  • This means for interrupting the communication can be designed in particular as a flap, door, slider or bulkhead that can be brought selectively into a release position and into a closed position. The position of this means can be changed in an advantageous manner by electronically controlled actuating means.
  • At least one means for setting at least one temperature of the continuous furnace is preferably provided, by means of which the temperatures can be individually set chamber-specifically, preferably in the input chamber and in the output chamber.
  • the dispensing chamber can advantageously be provided with a heating device. This heating device is preferably operated via a control or regulating device.
  • the output chamber can advantageously be operated in a controlled or regulated manner in such a way that it enables the workpiece located therein to be kept warm in a vacuum, preferably temperature-controlled.
  • the dispensing chamber can be operated in such a way that it is kept warm at ambient pressure or reduced vacuum.
  • the workpiece transfer from the output chamber to the hardening press can be handled in such a way that it takes place either in an atmospheric environment or in a vacuum.
  • the output chamber forms a lock system through which workpieces can be removed from the heating section without the vacuum in the heating section having to be broken for this purpose.
  • the output chamber also functions as a warming section in which the workpieces can continue to be kept at a specified temperature level. The thermal history of the workpieces in the heating section is not affected by the discharge of the workpieces from the discharge section.
  • the pressure in the dispensing chamber can also preferably be adjusted in accordance with a control device.
  • the dispensing chamber is separable from the heating section by a closure device. This closing device and the opening device are actuated at different times. In regular operation, the closing device is closed; it is preferably only temporarily opened to move a workpiece from the heating section into the output chamber.
  • the opening device is also primarily closed and is only opened temporarily for the removal of a workpiece from the removal chamber. During regular operation of the hardening device, the opening device is only opened when the closing device is closed and the interior of the dispensing chamber is thus sealed off from the interior of the heating section.
  • the closing device pointing to the heating section and the opening device pointing outward are closed.
  • the closing device pointing towards the heating section releases a workpiece passageway between the heating section and the output chamber.
  • the closing device blocks this workpiece passageway.
  • the closure device atmospherically seals the heating section and the dispensing chamber from one another. It is possible to set a negative pressure in the dispensing chamber for as long as possible and to equalize the pressure only shortly before the opening device is opened. This makes it possible to avoid the action of any non-inert gases on the workpiece and, in particular, avoid scaling.
  • the at least one means for hardening the workpieces is preferably designed in such a way that the workpieces introduced into it can be quenched by means of a fluid, preferably oil.
  • the at least one means for hardening the workpieces can also be designed in such a way that the workpieces introduced into it can be quenched by means of a gaseous medium.
  • the means for hardening is designed as a device in which the fluid provided for quenching the workpiece is actively brought to the workpiece.
  • a channel system is created in the device in interaction with the workpiece and a structure enclosing it and/or dipping into it, and the quenching medium actively flows through this channel system.
  • the flow is controlled in such a way that there is a defined heat dissipation from the zones of the workpiece that are flushed.
  • the workpiece is preferably clamped and/or supported in the quenching device. Insofar as the workpiece is clamped, the workpiece is loaded in a state in which it assumes a desired geometry with the introduction of compressive forces.
  • the application of the quenching medium can be controlled in such a way that a defined energy discharge from the workpiece takes place, in which case the workpiece assumes a defined thermal expansion state.
  • the workpiece can be relieved or, in particular, mandrel structures can be moved out of the workpiece.
  • the quenching process can be continued in the quenching device, which can also be referred to as a means for hardening, or the workpiece can already be removed in this state from the hardening device, which can also be referred to as a means for hardening or quenching device and fed to another device, in which a further heat discharge from the workpiece takes place, which is defined in terms of its temporal characteristics.
  • the workpiece can be quenched in a clamped state at intervals. These intervals can be tailored to provide sequential reheating of selected and already quenched zones of the workpiece.
  • the quenching medium can then be applied again to these reheated zones.
  • Different quenching media can be actively applied to the workpiece in chronological sequence or coordinated for different workpiece zones. It is thus possible, as part of a first quenching step, to apply a reactive quenching medium to the workpiece, which causes oxide removal or a layer-forming reaction with the workpiece. In a subsequent step, a quenching or reaction medium that differs in terms of its composition can then be applied to the workpiece.
  • the quenching device is designed in such a way that individual workpieces or groups of workpieces are subjected to a quenching treatment.
  • the workpieces or the workpiece are held in a defined position in the quenching device. This position can be determined by receiving structures and/or by inserting the workpiece into the quenching device.
  • any matrices, fixtures, mandrels, housing bells or valve devices into the quenching device.
  • the automated equipping of the quenching device with these auxiliary devices and the automated transfer of the workpiece into the quenching device enables the heat treatment of an individual workpiece to be carried out while ensuring the required microstructure.
  • the system ie the device according to the invention, comprising means for hardening and means for heating workpieces, is therefore suitable for the treatment of different workpieces in different batches, including batch 1 in a chronological sequence.
  • the device according to the invention can thus also enable a particularly high degree of flexibility with regard to the number of workpieces to be treated and workpiece geometries.
  • the quenching device is designed in particular as a hardening press.
  • the stamps provided for building up the pressing stress are preferably moved in the vertical direction.
  • the workpiece is preferably at or above the level at which it passed through the heating section of the continuous furnace during the quenching process tapped from the dispensing chamber. The quenching medium is thus brought to the fixed workpiece and not the workpiece to the quenching medium.
  • the device according to the invention preferably also comprises at least one handling device, by means of which workpieces can be transferred from the continuous furnace, preferably from the output chamber or from a storage device downstream of the output chamber, into the at least one means for hardening workpieces.
  • the device according to the invention forms part of an assembly which functions as a hardening cell.
  • the hardening cell is preferably constructed in such a way that it covers those process steps that are necessary for hardening the components. These hardening process steps are austenitizing, quenching (preferably in oil), washing, deep freezing and tempering.
  • austenitizing in vacuum and quenching in oil is accomplished within the hardening cell with the integration of an airlock acting as a holding chamber, which can be understood and referred to as a discharge chamber, a handling system and a hardening press.
  • Austenitizing is done by heating and holding in a vacuum. In this way, it is achieved in an advantageous manner that the process takes place with reduced release of particles and the workpiece surface is exposed to a reduced extent to reaction events.
  • the workpieces are heated by passing them through a furnace designed as a continuous furnace, which is located between two lock devices. The workpieces are thus transported from an entry lock area through the furnace along a flow direction to an exit lock area. The opening of the sluice devices towards the inside of the furnace takes place only after a sufficient reduction in pressure in the respective sluice chamber.
  • the concept according to the invention makes it possible to subject individual parts or very small batches to a hardening treatment efficiently in a short time sequence. Due to the process management according to the invention, the transfer times incurred for moving the workpiece from the austenitizing furnace to the start of quenching can be maintained in a reproducible manner with high accuracy and can also be kept very short.
  • the delivery chamber forming the discharge area at the end of the furnace, in which the pressure is equalized to the ambient pressure can be designed as a heatable chamber in which the heating can be continued can be used to maintain the workpiece temperature reached in the continuous furnace or to set it in a defined manner.
  • the dispensing chamber is designed as a heatable dispensing chamber that can be operated both at atmospheric pressure and in a vacuum.
  • the quenching process begins when the door of the output chamber, which acts as a pressure equalization chamber, is opened.
  • the workpiece transfer between the continuous austenitizing furnace and the hardening press is automated according to a particular aspect of the present invention.
  • a program-technically defined and reproducible workpiece transfer between the continuous furnace and the press with regard to the workpiece transfer path and the temporal dynamics of the workpiece transfer can be ensured.
  • the flaps, doors and bulkheads and/or locks at the beginning, at the end and inside the continuous furnace are opened in conjunction with a control device.
  • the workpieces are heated in such a way that a defined temporal heating in the furnace and in the exit area, i.e. the discharge or output chamber, results in a high temperature stability. This can have a particularly advantageous effect on the consistent quality of heat-treated workpieces.
  • the quenching device is preferably designed as an oil quenching device, in particular in the form of a mandrel hardening press for quenching with oil. This advantageously ensures a controlled distortion behavior. As an alternative to this, or also in combination with this measure, quenching in gas can also take place.
  • the system according to the invention can be designed in such a way that it enables a combination of vacuum austenitizing with a gas quenching process in the hardening press.
  • Gas quenching can be fixed or unsupported. In particular, it is possible to carry out targeted gas quenching in the hardening press using numerically controlled nozzles.
  • the workpiece is preferably clamped in the hardening press by inserting the workpiece into the press and driving a mandrel, preferably from below, into an oversized hole in the workpiece.
  • the workpiece or component can be covered from above. For example, it may be possible for a hood to be lowered over the component from above. Subsequently, oil is again preferably pressed through this arrangement from below.
  • the press can advantageously control several, in particular two, different oil inflows.
  • the hardening press offers channels that allow different fluid throughputs and these channels for supplying the quenching medium can be opened or closed individually in a time-controlled manner.
  • the mandrel is also designed in such a way that it includes oil channels.
  • the workpieces can be removed from the hardening press after sufficient cooling and subjected to a preferably multi-stage washing treatment.
  • a washing medium is passed through the channels for supplying the quenching medium by channel switching.
  • This washing medium can be subjected to a separation treatment, by which washed-off quenching medium is separated.
  • This pre-cleaning which is carried out within the hardening press, can also be carried out in connection with a gaseous medium.
  • the washed workpieces are preferably automatically transported to a preferably combined freezer/oven.
  • the transformation of martensite is driven further by deep-freezing and the structure is strengthened. Subsequent tempering then removes residual internal stresses. After this thermal post-treatment, the workpiece treatment in this system is complete and the component can be output.
  • the hardening system according to the invention is preferably designed in the manner of a sealed, enclosed cell with a preferably elongated rectangular cross section.
  • the continuous furnace used according to the invention can extend in the longitudinal direction of this cell.
  • the hardening press can be located in a longitudinal end area of this cell.
  • the workpiece store can be located in the area of the longitudinal end area of the cell opposite the hardening press.
  • a very compact cell can be provided in a particularly advantageous manner.
  • One embodiment can provide for a workpiece carrier circuit to take place inside the cell through the furnace and outside of the furnace back along it.
  • the means for heating and the means for hardening in one cell in such a way that a longitudinal extent of the output region of the means for heating, which is preferably designed as a continuous furnace, is arranged approximately parallel to a longitudinal extent of an insertion device of the means for heating.
  • a very compact unit consisting of means for hardening and means for heating workpieces can thus be provided as part of a device for heat-treating workpieces.
  • a system can also be taken from the present disclosure, which comprises at least two, preferably several devices for the heat treatment of workpieces, in particular at least two, preferably several means for heating and means for hardening workpieces.
  • the heat treatment of the workpiece can be carried out as a so-called batch process.
  • This batch process enables heat treatment as part of a single workpiece treatment as well as subsequent treatment of different single workpieces.
  • different quenching procedures specifically defined for the respective workpiece can be processed in direct succession.
  • the hardening system is constructed in such a way that the workpieces are transported generically, above all through the austenitizing furnace, largely independently of the component size and geometry.
  • the workpieces are preferably guided through the continuous furnace via trays or can be guided through accordingly.
  • several and even relatively small workpieces can be grouped and fed through the hardening plant, which is designed as a cell, for the processing of external orders.
  • the automated conveyance of the workpieces through the continuous furnace in conjunction with workpiece transport pallets or trays can be handled in such a way that the pallets or trays are transported back within the system from the exit area of the continuous furnace to the entrance area of the same.
  • the hardening system according to the invention preferably comprises a circulatory conveyor system for returning the pallets, trays or workpiece carriers.
  • a wide variety of workpiece carriers can be stored in a carrier store.
  • the workpiece handling within the system designed as a processing cell is preferably automated in all stations, monitored and documented by handling systems.
  • components in the heating chamber are heated with a preferably defined thermal history, while components in the output chamber are kept warm.
  • the system according to the invention thus enables a press hardening process to be carried out in which at least one workpiece is heated in the heating section at a defined time, while at least one workpiece is kept warm in the exit area or is brought to the hardening press.
  • the input chamber, the heating section and the output section comprise heating elements which can be controlled or regulated with regard to the heating power introduced into the oven as a result. Furthermore, means are provided in the input section, the heating section and the output section for detecting the temperatures in these sections.
  • the heating section can form several zones in which different temperatures or heat outputs can be set.
  • the respective chambers are preferably coupled to a vacuum pump with the involvement of electrically controllable valves.
  • the input chamber and the output chamber can be coupled in terms of valves and lines in such a way that the negative pressure present in the corresponding chamber is used for gas extraction from a chamber with ambient pressure.
  • the output chamber Before the output chamber is opened, it can be coupled to the input chamber via a line and a valve device, so that the negative pressure still prevailing in the output chamber is used to partially reduce the pressure in the input chamber that has just been loaded with a workpiece and is now closed. After this energetically beneficial Once the pressure has been reduced, the dispensing chamber can then be further aerated and opened at ambient pressure.
  • the process chamber is preferably equipped with three control zones. This ensures a particularly even working area. Also in this part of the furnace housing there are additional passages for reaching the measuring points for the TUS test. In this way, in particular, periodic checks of the workpieces can be carried out with little effort.
  • the heated output or discharge chamber is equipped with a separate control zone. This process chamber is flanged to the chamber of the heating section.
  • the output chamber is also provided with passages to reach the measuring points.
  • the chamber parts preferably all chamber parts, in particular the possibly unheated transfer chamber, are preferably equipped with vacuum and pressure measuring heads and enable the pressures to be monitored and recorded, with assignment to the respective workpiece.
  • the system's sensors enable automated, workpiece-specific process documentation.
  • the hardening plant according to the invention combines a furnace designed as a continuous vacuum furnace with a discharge chamber with a stationary hardening press for austenitizing the components.
  • the discharge chamber can be heated so that the components maintain a defined temperature level when the atmosphere changes.
  • an alternative device which comprises at least one means TK for heating workpieces WP.
  • the device also includes at least one means PQ for hardening workpieces, the at least one means TK for heating workpieces WP being designed as a continuous furnace through which the workpieces WP move in a continuous direction DTK.
  • the continuous furnace has an entry section TKI, a heating section TKH and an exit section TKO, the workpieces being able to be introduced into the entry section TKI via a first opening device 1, the workpieces being able to be removed from the exit section TKO via a second opening device 2 and both the entry section TKI and the output section TKO can be temporarily sealed off from the heating section TKH.
  • the above statements can be appropriately adapted for this further device according to the invention.
  • Temporarily sealing off the exit section from the heating section can allow workpieces that have been heated in a defined manner in the heating section to be exposed to controlled conditions, in particular controlled thermal conditions, in the exit section.
  • Figure 1 is a schematic representation to illustrate the structure of a controlled by a control device according to the invention device for
  • FIG. 2 shows a further schematic illustration to illustrate the structure of a hardening system according to the invention constructed as a hardening cell
  • FIG. 3 shows a flowchart to illustrate the process according to the invention, which is processed according to a control device
  • FIG. 4 shows a schematic representation to explain the embedding of the furnace designed as a continuous furnace between an inlet lock chamber and an outlet lock chamber, and between two workpiece transfer systems.
  • carburized metallic workpieces WP are introduced into a means TK for heating workpieces and heated therein, the means TK for heating workpieces being designed as a continuous furnace and wherein workpieces WP are introduced into the continuous furnace through a first opening device 1 and are removed from the continuous furnace through a second opening device 2 spaced apart from the first opening device 1, wherein workpieces WP are introduced into a means PQ for hardening after being removed for hardening.
  • FIG. 1 illustrates the structure of a device for the heat treatment of metallic workpieces, in particular transmission components, according to the concept mentioned.
  • This device is controlled by a control device CPU according to the invention, so that a heat treatment method according to the invention is also processed via this device.
  • the control device CPU is used to control a process for the heat treatment of metal workpieces using a hardening furnace TK, which includes a heating section TKH for heating workpieces WP and an output section TKO for outputting workpieces from the hardening furnace TK, and a hardening press PQ, the output section TKO can be heated and the control device CPU is designed in such a way that it coordinates the transport of workpieces WP through the heating section TKH in such a way that there is a defined heating-up residence time in the heating section TKH for the respective workpiece WP.
  • control device CPU coordinates the transfer of heated workpieces WP from the heating section TKH to the output section TKO in such a way that this transfer takes place when the heating dwell time has elapsed.
  • the control device CPU coordinates a heating power supply for the output section TKO in such a way that the workpiece is kept warm at a defined temperature level in the output section TKO.
  • At least one workpiece WP is kept warm in the output section TKO by compensating for dissipation or fluctuation effects. This warming is carried out with the aim of keeping the workpiece temperature within a narrow temperature range and avoiding fluctuations in the workpiece temperature.
  • Control device CPU causes a process control according to which at least one workpiece is kept warm in the output section during the time in which at least one workpiece is heated in the heating section.
  • the control device CPU causes the workpiece transport through the hardening furnace to be coordinated in such a way that more workpieces WP are heated in the heating section TKH than are kept at a target output temperature in the output section TKO.
  • a lock device 4 provided between the heating section TKH and the output section TKO is controlled by the control device CPU in order to release a workpiece throughput path and to close it.
  • the control device CPU also controls a lock device 3an provided between the heating section TKH and an upstream input section TKI, likewise for releasing a workpiece throughput path and for the controlled closing of the same.
  • the lock devices 3, 4 can be activated by the control device CPU in such a way that the lock devices 3, 4 are alternately opened and closed.
  • the control device CPU can also initiate an operating mode in which it controls the lock devices 3, 4 in such a way that the lock devices 3, 4 are opened and closed in opposite phases.
  • the control device CPU also controls a discharge opening device 2 of the
  • Output section TKO to take an open position that allows a workpiece output from the output section TKO and a closed position in which an interior of the output section TKO is sealed off from the environment.
  • the control device also controls an input opening device 1 of the
  • Input section TKI to take an open position that allows a workpiece input into the input section TKI and a closed position in which an interior of the input section TKI is sealed off from the environment.
  • the hardening furnace TK is designed as a throughput furnace and the workpieces or workpiece batches are conveyed therein along a throughput path DTK, with the conveyance of the workpieces WP or workpiece batches along the throughput path DTK being coordinated by the control device CPU.
  • the stay of the workpieces WP in the heating section TKH is coordinated in such a way that the workpiece is heated with a predetermined thermal history. This is preferably the same or similar for workpieces of the same type.
  • the continuous furnace is also designed as a vacuum furnace, and keeping the workpiece WP warm at the target temperature in the output section is preferably divided into two phases according to the control device, with the first phase being warm-keeping at a pressure level below ambient pressure and the second phase being a Keeping warm at a pressure equal to ambient pressure in the represents the output section.
  • the control device coordinates the keeping warm in the dispensing section in such a way that the proportion of time that is kept warm at reduced pressure outweighs the proportion of time that is kept warm at equal pressure.
  • the heating i.e. the process with a temperature gradient and active power input, takes place in the heating section, always in a vacuum.
  • the output chamber maintains the workpiece temperature with a power input that only compensates for the dissipation.
  • the thermal history of the workpiece in the heating section is designed to be consistent, specific to the workpiece.
  • the output chamber results in temporal flexibility with a constant workpiece temperature.
  • an embodiment of a device according to the invention for carrying out the method according to the invention comprises at least one means TK for heating workpieces WP.
  • the device also comprises at least one means PQ for hardening workpieces, the at least one means TK for heating workpieces WP being designed as a continuous furnace through which the workpieces WP travel in a continuous direction DTK, the continuous furnace having an input section TKI, a heating section TKH and an outlet section TKO, the workpieces being able to be introduced into the inlet section TKI via a first opening device 1, the workpieces being able to be removed from the outlet section TKO via a second opening device 2 and both the inlet section TKI and the outlet section TKO opposite the heating section TKH can be temporarily isolated.
  • This structure makes it possible to heat the components WP as part of their transfer to the quenching device PQ, with the transfer of the workpieces WP to the quenching device PQ being carried out by the introduction of the workpieces WP into the heating section TKH and the transfer of the workpieces WP within the furnace decoupled in time in the output section TKO and can be coordinated with the opening of the second opening device 2 .
  • the continuous furnace TK is designed here in such a way that it comprises at least one input chamber C1, which forms the input section TKI, and at least one output chamber C2, which forms the output section TKO, these two chambers C1, C2 being connected to one another through a heating section TKH extending workpiece transport path W are coupled.
  • the workpieces WP can be brought into the input chamber C1 through the first opening device 1 .
  • the Workpieces WP can be removed from the output chamber C2 through the second opening device 2 .
  • At least one further chamber C3 is provided, this further chamber C3 here forming the heating section TKH, through which the input chamber C1 communicates with the output chamber C2.
  • the continuous furnace TK is designed as a vacuum continuous furnace, with a negative pressure being able to be applied at least in the input chamber C1 and/or in the output chamber C2 and/or in the at least one further chamber C3.
  • This negative pressure can be regulated chamber-specifically and is set to ambient pressure before the openings 1, 2 are opened.
  • a means 3 is provided for interrupting communication, in particular for closing at least one section between the first chamber C1 and the heating section TKH. Furthermore, a means 4 is provided between the second chamber C2 and the heating section TKH.
  • These means 3, 4 for interrupting communication with the chamber C3 can be designed in particular as a flap, door, slider or bulkhead that can be brought into a release position and into a closed position. The position change of this means 3, 4 can be accomplished in an advantageous manner by electronically controlled actuators and / or actuators.
  • the device shown has at least one means 5 for setting at least one temperature of the continuous furnace TK, in particular a control unit CPU, by means of which the temperatures T1, T2, T3 are chamber-specific and individually, preferably in the output chamber C2 and in the at least third chamber C3 are individually adjustable.
  • the at least one means PQ for hardening the workpieces WP is designed here in such a way that the workpieces WP introduced into it can be quenched by means of a fluid, preferably oil or gas.
  • the device according to the invention comprises a handling device TS by means of the workpieces WP from the continuous furnace TK, ie from the output chamber C2 or from a storage device downstream of the output chamber C2, into which at least one means PQ for hardening the workpieces WP can be transferred.
  • the handling device TS can be formed by a robot arm or a portal system.
  • the control device CPU is used to control a heat treatment process of preferably metallic workpieces. As part of this heat treatment process, carburized workpieces are preferably introduced through a first opening device 1 into chambers C1, C2, C3 of a means TK for heating workpieces to a predetermined temperature and heated there.
  • the workpieces WP are discharged from a discharge chamber C2 through a second opening device 2, which is different from the first opening device 1, and transported to a means for hardening workpieces and quenched thereby.
  • the controller also controls the pressures in chambers C1, C2, C3. The process sequence controlled by the control device CPU is explained further in connection with FIG.
  • the continuous furnace TK provides several heating zones Z1, Z2, Z3, AK.
  • the continuous furnace TK provides several heating zones Z1, ZTK, AK.
  • the heating zone of the heating section ZTK is subdivided into further zones Z2, Z3.
  • the temperature in these zones can be controlled according to the control unit CPU.
  • the heating section TKH is constructed in such a way that it defines a number of heating zones Z2, Z3 in which different temperatures and heating outputs can be set to a sufficient extent.
  • Both the input area TKI, the heating section TKH and the output area TKO are designed in such a way that these measuring points TUS provide for recording, monitoring and documenting the workpiece heating.
  • the pressures in these chambers can be lowered to below ambient pressure via a vacuum pump VP.
  • the chambers C1, C2, C3 are coupled to one another via a line system and electrically controllable valves provided therein.
  • the chambers C1, C2, C3 can temporarily communicate with one another via the line system, so that in the context of partial ventilation of one chamber C1, C2, partial ventilation of the other chamber C2, C1 can be effected in phase opposition.
  • the representation according to FIG. 2 shows a press-hardening system constructed including the device according to FIG. 1 and designed as a cell.
  • This press hardening system includes a hardening furnace TK, an output lock TKO for the output of workpieces WP from the hardening furnace TK and a hardening press PQ for clamping a workpiece WP and for accomplishing a quenching process of the workpiece WP in the clamped state.
  • a handling system TS is provided in an intermediate area between the discharge chamber TKO, which functions as an output lock, and the hardening press PQ.
  • This handling system TS is operated in such a way that a programmatically secured temporal temperature profile of the workpiece WP results for the movement of the workpiece WP from the output lock into the hardening press PQ.
  • the hardening furnace TK is designed as a vacuum furnace for heating a workpiece WP in a low-oxygen environment. Furthermore, the TK hardening furnace is designed as a continuous furnace. The workpiece handling between the hardening furnace TK and the hardening press PQ is accomplished here in such a way that the workpiece WP, after exiting the opening device 2 of the output lock TKO, is guided through the hardening furnace TK into the hardening press PQ transversely to the flow direction DTK.
  • the TK hardening furnace and the PQ hardening press are linked across the corner by the TS transfer system with regard to workpiece travel.
  • the transfer process of the workpieces from the WP from the output sluice TKO of the hardening furnace TK to the hardening press PQ and the quenching process in the hardening press PQ take place at the same time in terms of process flow.
  • the transfer of the workpiece from the output chamber TKO into the hardening press PQ is handled as a thermally relevant sub-step of the quenching process.
  • a workpiece transfer system WPH1, WPH2 is provided, which extends along the hardening furnace TK between an output area of the hardening press PQ and an entry opening 1 of the entry lock TK1 of the hardening furnace TK.
  • the workpiece transfer system WPH1, WPH2 includes several linked conveyor modules.
  • a post-cooling station 6, a washing station 7 and/or a test station 8 can be loaded with workpieces via a first module of the workpiece transfer system WPH1.
  • a second module of the workpiece transfer system can be used to return the respective workpiece to the input area of the cell CW. From there, the hardened and washed workpieces can be taken to the cooling cells 10...13.
  • the press hardening system is designed in such a way that workpieces WP located in the area of the test station 8 can be removed from the press hardening system.
  • the press-hardening system can be designed in such a way that the workpieces are press-hardened using a die device.
  • This die device is used to hold the workpiece and to provide wall sections that support the workpiece.
  • the quenching medium can be guided onto the workpiece in interaction with the die device, controlled by valve devices. If the workpiece is supported using a core or dome, it is possible to carry out the quenching process in such a way that the workpiece is not completely cooled. After this partial cooling, the supporting structures such as mandrels, cores or matrices can be removed from the workpiece, which is then still thermally expanded. Then there is further cooling. This can also take place outside of the hardening press, for example in a bath.
  • a handling system TS is provided in the device according to FIG. 1 and in the press hardening system according to FIG. This handling system TS is arranged in an intermediate area between the output chamber TKO and the hardening press PQ. This handling system TS is operated in such a way that, for the transfer of the workpiece WP from the output chamber TKO into the hardening press PQ, there is a program-technically secured time sequence of movements for the transfer of the workpiece WP.
  • the handling system is configured in connection with a corresponding control device in such a way that the delivery process and the quenching process are linked in terms of time.
  • the transfer process can be activated with a ready signal from the hardening press PQ or can only be initiated in a ready state PQ of the hardening press. Furthermore, a signal confirming the completion of the transfer process of the workpiece WP into the press PQ can start the press hardening process.
  • the TS handling system is located in a CW hardening cell, which houses the TK hardening furnace and the PQ hardening press.
  • the hardening cell CW is designed as a rectangular cuboid structure, the oven extends in the longitudinal direction of this cuboid structure.
  • the hardening press is located in a longitudinal end area.
  • the workpiece transfer process handled by the TS handling system is monitored and documented in terms of its timing. For this purpose, in particular the thermal time profile of the workpiece can be measured and recorded.
  • the 2 also shows the structure of a hardening cell, with the hardening furnace TK, the hardening press PQ, a workpiece washing device 7 and the workpiece handling system TS for moving the workpieces from the hardening furnace TK into the hardening press PQ.
  • the hardening cell CW includes a workpiece return system WPH for moving the workpieces WP from the hardening press PQ to an input and output area 9, 9a.
  • the TK hardening furnace is designed as a continuous furnace.
  • the WPH workpiece return system runs parallel to the TK hardening furnace.
  • the workpiece washing device 7 is in one Arranged in the intermediate area between the workpiece output area 9a and the hardening press PQ and can be loaded via the workpiece return conveyor system WPH.
  • the hardening furnace TK has an entry lock TKI and an exit lock TKO.
  • a loading system LS is provided in a zone upstream of the entry lock TKI.
  • the workpiece return system WPH1, WPH2 can be used to transfer workpieces between the PQ press and the LS loading system.
  • a workpiece store WPB1, WPB2 is provided in an area of the hardening cell CW adjacent to the entry area or the entry lock TKI of the hardening furnace TK.
  • a first cooling cell 10 is provided in an area of the hardening cell CW adjacent to the input area TKI of the hardening furnace TK.
  • Additional cooling cells 11, 12, 13 are provided in an area of the hardening cell CW adjacent to the input area TKI of the hardening furnace TK.
  • the workpiece store WPB1, WPB2 and/or the cooling cells 10, 11, 12, 13 can be reached via the loading system LS, so that workpieces WP can be removed from these modules by the loading system and introduced into these modules.
  • the cooling cells 10 . . . 13 can also be equipped with heating devices, so that a tempering process can also be carried out via these cells.
  • the hardening cell CW is enclosed by a cell wall CW2.
  • the workpiece return system WPH is connected to an output lock 8 .
  • a workpiece discharge from the hardening cell CW can be accomplished via this output lock 8 in order to carry out a workpiece inspection.
  • Checked workpieces WP can also be returned to the system via the output lock, for example to be used in the cooling cell modules 10...13.
  • the operation of the hardening cell is controlled by a control device CPU (see Fig. 1), which is subdivided here by way of example into two modules CE, CP1 coupled with signals, with the module CE being used primarily for workpiece handling in the entrance area of the hardening furnace TK and the module CP1 controls the workpiece flow in the TK hardening furnace, the TS transfer system and the PQ hardening press. All control tasks relevant to the handling of the workpiece WP from entry into the hardening furnace TK to the end of the hardening process, including the temperature control of the hardening furnace TK, are thus coordinated by the control module CP1.
  • the control module CP1 thus takes over the "hot handling" and the control module CE the "cold handling".
  • the processes in "hot handling” are documented specifically for each workpiece. For “cold handling” there is only documentation with regard to the trouble-free handling process.
  • the cold handling control processed via the CE module also includes workpiece handling Exit from the hardening press PQ. Any data on thermal workpiece post-treatment, in particular cooling and re-tempering, can be fed back to module CP1.
  • the illustration according to FIG. 3 shows a control device CPU and a flow chart of a process processed by this control device.
  • the control device CPU controls the sequence of the method according to the invention for carrying out a press hardening process, in which workpieces are heated in a hardening furnace as part of a tempering step and quenched in a hardening press as part of a quenching step.
  • the control device CPU is coupled here, for example, via a bus system with the switching elements of the controlled components of the hardening system.
  • control used here also includes regulation; the control device can represent a control device in this respect, and adjust manipulated variables taking into account returned signals, in particular with regard to pressure, temperature, workpiece position and dynamically.
  • a workpiece WP is picked up by the handling device from the workpiece storage area WPB1 in step S1 and brought to an area upstream of the first opening device 1 .
  • step S2 in a system state in which the barrier wall 3 is closed, the pressure in the chamber C1 is adjusted to the ambient pressure.
  • step S3 the opening device 1 is opened.
  • step S4 the workpiece WP is introduced into the input chamber C1.
  • step S5 the opening device 1 is closed.
  • step S6 the pressure in the chamber C1 is reduced to the internal pressure in the third chamber C3.
  • step S7 the barrier wall 3 is opened.
  • step S8 the workpiece is conveyed into the third chamber C3 in the throughput direction of the furnace TK.
  • step S9 the barrier wall 3 is closed.
  • steps S10 to S15 the workpiece is conveyed through zones or stations of the furnace TK that follow in the throughput direction DTK and is heated in a defined manner in these zones.
  • a defined negative pressure prevails in chamber C3, which is set and maintained via a control routine that is not described further here.
  • the pressure in the output chamber C2 is lowered to the internal pressure of the chamber C3 in step S16.
  • the barrier wall 4 is opened and the workpiece WP is brought into the output chamber C2 forming the discharge section TKO.
  • the barrier wall 4 is closed in step S18.
  • step S19 the pressure in the chamber C2 is increased to the atmospheric pressure level.
  • the pressure increase can be accomplished by equalizing the pressure by introducing an inert gas into chamber C2.
  • the temperature in the discharge chamber C2 is adjusted to a workpiece holding temperature.
  • step S21 it is queried whether the transfer system TS and the hardening press PQ are in a ready state suitable for processing the quenching process.
  • step S22 the quenching process is activated.
  • the opening device 2 is opened in step Q1.
  • the transfer system TS picks up the workpiece WP from the chamber C2 and transfers it to the hardening press PQ on a defined path with a defined speed profile.
  • the hardening press PQ clamps the workpiece used.
  • step Q4 the clamped workpiece is subjected to a quenching medium.
  • Steps Q1 to Q4 form a process step group that is processed in a time frame defined by the program.
  • the release of the workpiece WP in the chamber C2 and the process of transferring the workpiece WP into the hardening press PQ form part of the quenching process, which is carried out in a parameterized manner specific to the workpiece.
  • the handling system TS is operated in such a way that for the transfer of the workpiece WP from the output device TKO into the hardening press PQ, a program-technically secured temporal temperature profile of the workpiece WP as well as a program-technically secured temporal gas contacting of the workpiece WP results.
  • the transfer process beginning with the opening of the opening device 2 can only be carried out in conjunction with a ready signal from the hardening press. In this respect, there is no waiting time or lengthening of the process time outside of the defined process.
  • step S23 the hardening press PQ is opened in step S23 and the workpiece is removed from the hardening press PQ in step S24.
  • step S25 the workpiece is inserted into a workpiece carrier and fed to a washing station in step S26.
  • the opening device 2 is opened and the workpiece is picked up in the output area TKO of the hardening furnace when the workpiece has reached a defined thermal state and the transfer system and the hardening press are in a ready state.
  • the process step group Q1 . . . Q4 takes its course when the opening device 2 is opened.
  • step Q4 the workpiece is exposed to a quenching medium in a way that is defined by the program and coordinated by means of adjusting means.
  • the heating of the workpieces as part of the passage through the hardening furnace AND is measured and recorded and documented for each workpiece.
  • the illustration according to FIG. 4 shows a press hardening system with a hardening furnace TK, which is designed as a continuous furnace and has a furnace inlet TKI and a furnace outlet TKO.
  • the press hardening system also includes a hardening press PQ for clamping a workpiece and for effecting a quenching process of the workpiece in the clamped state.
  • a handling system TS is provided in an intermediate area between the furnace outlet TKO and the hardening press PQ.
  • a workpiece loading system LS is provided in an area adjacent to the furnace entrance TKI.
  • the handling system TS and the workpiece loading system LS are connected to one another via a workpiece carrier conveyor path DTR, which runs past the continuous furnace TK.
  • the workpiece carriers are returned to the entrance area of the continuous furnace TK via the workpiece carrier conveyor path.
  • the workpiece carriers move through zones both in the input area of the continuous furnace TK and in the output area of the continuous furnace TK, in which a workpiece handling by transfer systems, which are formed in particular by a robot arm or a portal robot, takes place.
  • the workpiece carrier conveyor path runs parallel to the continuous furnace.
  • the workpiece conveyor path WPH described in connection with Figure 2 also runs parallel to this workpiece carrier conveyor path from the exit from the hardening press PQ back to the cooling cells 10...13. This makes it possible to use the TS handling system to pick up the workpiece carriers that have been brought out of the furnace outlet and bring them to the entrance of the hardening furnace TK.
  • the following steps can be provided: picking up the workpieces WP in a furnace exit area located in the vicinity of the second opening device 2 by means of a handling system TS, inserting the workpieces WP into the hardening press PQ, handling the quenching process and removal of the workpieces WP from the hardening press PQ, with the transfer of the workpieces WP into the hardening press PQ by the handling system TS and the implementation of the quenching process by the hardening press PQ forming a process step group Q1...Q4, which takes place in a time frame defined by the program is processed.
  • a further configuration of a device for carrying out this method comprises at least one means TK for heating workpieces and also at least one means PQ for hardening workpieces, with the at least one means TK for heating workpieces being designed as a continuous furnace, through which the workpieces WP in can be conveyed through a throughput direction, the continuous furnace has an input section, a heating section and an output section, the workpieces WP can be introduced into the input section via a first opening device 1, the workpieces WP can be removed from the output section via a second opening device 2, the output section has an output chamber C2 and the output chamber C2 can be closed in a controlled manner in relation to the heating section TKH and the means PQ for hardening the workpiece.

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  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Physics & Mathematics (AREA)
  • Thermal Sciences (AREA)
  • Crystallography & Structural Chemistry (AREA)
  • Materials Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • General Engineering & Computer Science (AREA)
  • Heat Treatments In General, Especially Conveying And Cooling (AREA)
  • Control Of Heat Treatment Processes (AREA)

Abstract

L'invention concerne un dispositif de commande et un procédé pour commander un processus de traitement thermique de pièces métalliques, au moyen d'un four de trempe qui comprend une section de chauffage destinée à chauffer des pièces et une section de sortie de laquelle les pièces sortent du four de trempe, et au moyen d'une presse de trempe, la section de sortie pouvant être chauffée. Selon la configuration du dispositif de commande et du procédé mis en œuvre au moyen de celui-ci, le transport de pièces à travers la section de chauffage est réglé de manière à obtenir un temps de séjour de chauffage et un historique thermique définis dans la section de chauffage pour la pièce respective. En outre, le transfert de pièces chauffées de la section de chauffage à la section de sortie est réglé de telle sorte que ce transfert s'effectue à la fin du temps de séjour de chauffage. Pour la section de sortie, une alimentation en puissance calorifique est réglée de telle sorte qu'un maintien à température de la pièce se produise dans la section de sortie à un niveau de température défini.
EP22722142.1A 2021-04-16 2022-04-08 Dispositif de commande et procédé pour commander une installation et un processus de traitement thermique de pièces métalliques Pending EP4314683A1 (fr)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
DE102021109683 2021-04-16
PCT/EP2022/059357 WO2022218832A1 (fr) 2021-04-16 2022-04-08 Dispositif de commande et procédé pour commander une installation et un processus de traitement thermique de pièces métalliques

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EP4314683A1 true EP4314683A1 (fr) 2024-02-07

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EP (1) EP4314683A1 (fr)
DE (1) DE102022108513A1 (fr)
WO (1) WO2022218832A1 (fr)

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP4261292A1 (fr) 2022-04-14 2023-10-18 Aerospace Transmission Technologies Dispositif et procédé de fabrication de pièces traitées thermiquement, en particulier de roues dentées à denture hélicoidale et dispositif de commande correspondant
EP4261291A1 (fr) 2022-04-14 2023-10-18 Aerospace Transmission Technologies Procédé de fabrication de pièces traitées thermiquement, en particulier de roues dentées à denture hélicoidale et presse de trempe correspondante

Family Cites Families (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE4126597A1 (de) * 1991-08-10 1993-02-11 Heraeus Quarzglas Verfahren und vorrichtung zur waermebehandlung von werkstuecken mit elektrischen und elektronischen bauteilen
DE59208341D1 (de) * 1992-01-15 1997-05-15 Aichelin Gmbh Vorrichtung zur wärmebehandlung metallischer werkstücke
DE29505496U1 (de) * 1995-03-31 1995-06-01 Ipsen Industries International GmbH, 47533 Kleve Vorrichtung zur Wärmebehandlung metallischer Werkstücke unter Vakuum
DE102005057742B3 (de) * 2005-12-02 2007-06-14 Voestalpine Automotive Holding Gmbh Verfahren und Vorrichtung zum Aufheizen von Stahlbauteilen
DE102008055980A1 (de) * 2008-04-17 2009-10-29 Schwartz, Eva Verfahren und Durchlaufofen zum Erwärmen von Werkstücken
DE102012019653A1 (de) * 2012-10-08 2014-04-10 Ipsen International Gmbh Gasdichter schutzgasbegaster Industrieofen, insbesondere Kammerofen, Durchstoßofen, Drehherdofen oder Ringherdofen
WO2019213774A1 (fr) * 2018-05-11 2019-11-14 Magna International Inc. Préchauffage par conduction de feuille pour formage à chaud

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DE102022108513A1 (de) 2022-10-20
WO2022218832A1 (fr) 2022-10-20

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