JP5722416B2 - Hot isostatic press - Google Patents

Description

  The present invention relates to an apparatus for processing an article by hot isostatic pressing and an article processing by hot isostatic pressing.

  Hot isostatic pressing (HIP) is a technique that can find an increasingly wide range of applications. Hot isostatic pressing is used, for example, to eliminate porosity during casting, for example, to sufficiently increase the service life and strength, particularly fatigue strength, of turbine blades. Another area of application is the production of products that are required to have a sufficiently compact and pore-free surface by compressing the powder.

  In the hot isostatic pressing method, an article to be processed by pressing is placed in a compartment of an isolated pressure vessel charge. A cycle, or processing cycle, includes loading an article, processing the article, and removing the article, and the total duration of the cycle is referred to herein as the cycle time. The process can be divided into several parts or states in turn, such as a pressed state, a heated state and a cooled state.

  After loading, the container is sealed and the pressure medium is introduced into the pressure container and the charge container's compartment. The pressure medium pressure and temperature are then increased, so that the article is exposed to the increased pressure and temperature for a selected time. The increase in temperature of the pressure medium, and hence the article, is provided by a heating element, or furnace, located in the furnace chamber of the pressure vessel. The pressure, temperature and processing time will of course depend on many factors, such as the material properties of the article being processed, the field of application and the quality required of the article being processed. The pressure and temperature in the hot isostatic pressing can typically be in the range of 200 to 5000 bar and 300 to 3000 ° C., respectively.

  When the article has been pressed, the article often needs to be cooled before being removed from the pressure vessel, i.e., removed. For many types of metallurgical processes, the cooling rate will affect the metallurgical properties. For example, thermal stress (or temperature stress) and grain growth should be minimized in order to obtain high quality materials. It is therefore desirable to cool the material uniformly and to control the cooling rate if possible. Many press methods of the known art suffer from slow cooling of the article and therefore efforts are made to shorten the cooling time of the article.

  In patent document 1, the hot isostatic pressing method comprised so that articles | goods may be cooled rapidly after a press process and a heat processing are completed is provided. The pressing method has a pressure vessel having an outer wall, an end closure, and a hot zone surrounded by a thermal barrier. The outer wall of the pressure vessel is cooled from the outside. The hot zone is arranged to accommodate articles to be processed. There is a relatively cool space, or zone, between the thermal barrier and the pressure vessel with the end closure. As in conventional hot isostatic pressing, the pressure medium is heated during the pressing of the article, and such article is placed in a hot zone as mentioned above.

  Furthermore, in US Pat. No. 6,057,049, during cooling of an article, a cooled pressure medium is introduced into the hot zone, and thus heat energy is conveyed from the article to the pressure medium. Thus, the temperature of the pressure medium will increase while passing through the hot zone, and the temperature of the article will decrease. Upon exiting the hot zone, the relatively hot pressure medium will reach the walls of the pressure vessel. In conventional hot isostatic pressing, the amount of hot pressure medium reaching the pressure vessel wall must be carefully monitored so that it does not overheat the pressure vessel wall, i.e. all internal surfaces of the press that come into contact with the hot pressure medium. Must be controlled. This must be done at a relatively slow pace of cooling, i.e. not faster than the pressure vessel can withstand for a predetermined time.

  However, the pressing method in Patent Document 1 described above further includes a heat exchanger located on the hot zone so that the time for cooling the article can be shortened. This will cause the pressure medium to be cooled by the heat exchanger before contacting the pressure vessel wall. As a result, the heat exchanger can increase the cooling capacity without the risk of overheating the wall of the pressure vessel. Further, as in conventional hot isostatic pressing, the pressure medium is cooled as it passes through the gap between the pressure vessel wall and the thermal barrier during the cooling of the article. When the cooled pressure medium reaches the bottom of the pressure vessel, it re-enters the hot zone (where the article to be cooled is located) via a passage through the thermal barrier.

  The heat exchanger becomes hot to function as a booster during the cooling of the pressure medium and the article, and before the heat exchanger can be operated to process a new set of articles Must be cooled. Thus, a disadvantage of this type of pressing method is that the time between subsequent cycles depends on the cooling time of the heat exchanger. To overcome this problem, one approach is to utilize two heat exchangers. With two heat exchangers, one heat exchanger can be cooled outside the hot isostatic pressing device and the other heat exchanger can be used in the course of the hot isostatic pressing process. used. However, this results in the disadvantage of having to change the heat exchanger before each press operation. Furthermore, the use of two heat exchangers naturally increases the cost of the pressing device.

US Pat. No. 5,118,289

  It is an object of the present invention to provide an improved hot isostatic pressing method that eliminates or reduces at least one of the problems mentioned above.

  This object is met by a hot isostatic pressing device as defined in the appended independent claim. Further embodiments are defined in the dependent claims.

  In a first aspect of the present invention, a hot isostatic pressing apparatus for processing articles by a hot isostatic pressing method is provided. The hot isostatic pressing apparatus has a pressure vessel including a furnace chamber. The furnace chamber has a heat insulating casing and a furnace for heating the pressure medium during pressing. The furnace chamber is configured to accommodate articles. The pressure vessel further includes a heat exchanger unit positioned below the furnace chamber and configured to exchange heat energy with the pressure medium.

  The present invention is therefore based on the idea of providing a heat exchanger unit and using a pressure medium to cool the heat exchanger unit. This is achieved by placing a heat exchanger unit inside the pressure vessel and below the furnace chamber. Here, the heat exchanger unit can exchange heat energy with the pressure medium. The heat exchanger unit can then be exposed to a relatively cooler part of the pressure medium due to the density difference between the relatively hot part and the cold part, and the pressure medium passes through the pressure container in the pressure container. Head downwards against the bottom of the. Thus, the heat exchanger unit expects the pressure medium to be cooler instead of placing the heat exchanger unit above the furnace chamber where the pressure medium can be expected to be hotter than the lower portion of the vessel. Can be placed under the furnace chamber. Thereby, a cooler pressure medium can be used to lower the temperature of the heat exchanger unit.

  Following the heating of the processing cycle and completion of the pressing portion, during the cooling of the article, heat (or heat energy) is transferred from the pressure medium to the heat exchanger unit. Heat energy must be dissipated from the heat exchanger unit before operating the press to cool the article again in subsequent processing cycles. This is achieved by directing a flow of relatively cool pressure medium through the relatively warm heat exchanger unit. Thus, heat is transferred to and from the heat exchanger unit at different parts of the hot isostatic press cycle, i.e. the processing cycle.

  In this way, the present invention provides the advantage of significantly accelerating the operation of the press apparatus since the exchanger does not need to be moved or replaced between cycles.

  Furthermore, the cost of the pressing device can be reduced by the fact that only one heat exchanger needs to be utilized for one pressing device.

  A further advantage of placing the heat exchanger unit at the bottom of the press is to provide easy access by an opening at the top of the pressure vessel for loading and unloading items into the furnace chamber. A charge compartment is also provided.

  For the wall of the pressure vessel to maintain the high temperature and pressure of the hot isostatic pressing process, the hot isostatic pressing article is preferably provided with means for cooling the pressure vessel. Yes. For example, the means for cooling can be a refrigerant such as water. The coolant can be arranged to flow along the outer wall of the pressure vessel of the piping system, i.e., the cooling channel, to maintain the wall temperature at an appropriate level.

  Furthermore, the heat insulation casing of the furnace chamber has a lower heat insulation portion. Moreover, the heat exchanger unit is located under the said lower heat insulation part of a casing. As a result, the heat exchanger unit is isolated from the articles in the furnace chamber and is thermally insulated (insulated). This effectively isolates the hot zone in the furnace chamber from the cold zone in the lower part of the hot isostatic press.

  A hot isostatic pressing device according to some embodiments of the present invention has first and second guide passages or channels. The first guide passage is formed between the casing of the furnace chamber and the outer wall of the pressure vessel. The casing includes a heat insulating portion and a housing arranged to surround the heat insulating portion. Further, the second guide passage is formed between the heat insulating portion and the housing. The first guide passage is mainly arranged to guide the pressure medium in a downward direction along the wall of the compression vessel, either inside or outside the environment. The second guide passage is mainly arranged to guide the pressure medium in an upward direction along the outer wall of the furnace chamber, that is, the housing of the furnace chamber.

  When the pressure medium is brought into contact with the wall of the pressure vessel, the heat energy is exchanged between the pressure medium and the wall and is cooled by the refrigerant from the outside of the pressure vessel as described above. Can. In this way, the pressing device is effectively arranged to circulate the pressure medium in the pressure vessel, thus forming an outer passive convection loop. The purpose of the outer convection loop is to allow cooling of the pressure medium during cooling of the article, and cooling of the heat exchanger unit during heating of the article.

  Effectively, this embodiment allows the heat exchanger unit to be cooled during the pressing and heating of the article, i.e., heat heats the heat exchanger unit during the cooling of the article. , From the pressure medium and during the pressing and heating of the article from the heat exchanger unit to the pressure medium. In this way, after the article has cooled, the cycle time can be shortened because the press can be operated immediately to press and heat a new set of articles.

  According to a further embodiment of the invention, the hot isostatic pressing device further comprises a flow generator located below the furnace chamber near the heat exchanger unit. This flow generator enhances the circulation of the pressure medium in the pressure vessel, ie the outer convection loop. The flow generator may be in the form of a fan, pump, ejector, etc., for example.

  The furnace chamber may further have a further guide passage. This guide passage is formed between the heat insulation casing of the furnace chamber and the compartment of the charge.

  Furthermore, a further flow generator can be positioned in the furnace chamber so that the pressure medium is circulated inside to form a uniform temperature distribution. This flow generator exerts a force on the pressure medium upwards through the load compartment and downwards through the further guide passage. As a result, an inner active convection loop is formed. Said further flow generators such as fans, pumps, ejectors etc. can be used to control the inner active convection loop.

  In the outer convection loop, the pressure medium is cooled on the outer wall of the pressure vessel, i.e. on the inner surface of the pressure medium, where the pressure medium flows towards the bottom of the pressing device. At the bottom of the pressing device, a portion of the pressure medium is returned to the furnace chamber where it is heated with the article (ie, charge) during rapid cooling. The pressure medium then proceeds upward by the flow generator towards the top of the furnace chamber, as described above with respect to the inner convection loop.

  Furthermore, the pressure vessel can have a guiding structure for guiding and guiding the flow of the pressure medium that has passed or passed through the heat exchanger unit. It is intended that the exchange of thermal energy between the pressure medium and the heat exchanger unit is essentially avoided when the flow is directed through the heat exchanger unit. On the other hand, exchange of thermal energy between the pressure medium and the heat exchanger unit is possible when the flow is guided or guided by the heat exchanger unit. Thus, the guiding arrangement provides the ability to control when the cooling effect of the heat exchanger unit can be applied, i.e. the booster effect of the heat exchanger unit is selected in the cooling part of the processing cycle. Can be selected to apply at different times. However, for example, in the form of a valve, it is possible to control the cooling effect of the heat exchanger unit by means of an adjustable limit, for example, in the first guide passage.

  In addition, the guide structure can have a first valve structure disposed around the heat exchanger unit, whereby the pressure from the first guide passage through or through the heat exchanger unit. It makes it possible to improve the control of the medium flow. In this context, the term “perimeter” is intended to cover the position of the first valve arrangement in the radial direction in the heat exchanger unit, regardless of the position along the long axis, ie cylindrical, pressure vessel. Has been. Furthermore, the first valve arrangement may partially or completely cover the periphery of the pressure vessel, i.e. it does not depend on the angular position along the periphery of the heat exchanger unit.

  Furthermore, the guiding structure can have a second valve structure and the heat exchanger unit can be arranged around the second valve structure. Thereby, an improved control of the flow of the pressure medium from or through the heat exchanger unit from the first guide passage can be effected. Similarly, according to the above, the term “perimeter” as used in this context refers to the heat exchanger unit in the radial direction of the second valve arrangement, irrespective of its position along the long axis of the pressure vessel. Is intended to cover the position. Furthermore, similar to the first valve structure, the heat exchanger unit can partially or completely cover the periphery of the second valve structure, ie the position of the heat exchanger unit is It does not depend on a predetermined angular position along the circumference of the two valve structures.

  Furthermore, it is possible to combine the first and second valve arrangements to obtain a further improved control of the pressure medium flow. This is illustrated in detail by the example of the detailed description below.

  Various aspects of the present invention, including particular features and advantages, will be readily understood from the following detailed description and the accompanying drawings. In the following figures, the same reference numerals refer to the same components and features of the embodiments of the present invention throughout. Furthermore, reference signs indicating symmetrically positioned members, components or features are displayed only once in the drawings.

FIG. 1 is a side view of a pressing device according to an embodiment of the present invention during a super-quenching state. FIG. 2 is a side view of a pressing device according to another embodiment of the present invention during a super-quenching state. FIG. 3 is a side view of a pressing device according to a further embodiment of the invention during a quenching condition. FIG. 4 is a side view of a pressing device according to another embodiment of the present invention during a super-quenching state. FIG. 5 is a side view of a pressing device according to a further embodiment of the present invention during at least one of a heated state and a pressed state. FIG. 6 is a side view of the pressing device according to FIG. 5 during a quenching condition with a cold, inactive heat exchanger unit. FIG. 7 is a side view of the pressing device according to FIG. 5 during a quenching condition with a hot, inactive heat exchanger unit. FIG. 8 is a side view of the pressing device according to FIG. 5 during a super-quenching state.

  The following is a description illustrating an embodiment according to the present invention. This description is intended for purposes of illustration only and is not meant to be limiting. It should be noted that the drawings are schematic and the press apparatus of the embodiments described herein may have many features and components not shown in the drawings for the sake of simplicity.

  Embodiments of the pressing device according to the present invention can be used to treat articles made of many different materials by hot isostatic pressing.

  Referring to FIG. 1, a pressing device according to an embodiment of the present invention is shown. A pressing device intended to be used for pressing articles comprises means (not shown) for supplying and discharging pressure medium, such as at least one port, inlet and outlet. It has a pressure vessel 1. The pressure vessel 1 has a furnace (or heater) 36, ie a furnace chamber 18 with heating elements, for heating the pressure medium during the pressing part of the processing cycle. The furnace 36 may be located, for example, at the lower portion of the furnace chamber 18 as shown in FIG. 1 or at the side of the furnace chamber 18 as shown in FIG. it can. The person skilled in the art will further understand that it is also possible to combine a heating element at the side and a heating element at the bottom so as to provide a furnace located at the side and bottom of the furnace chamber. Any application of the furnace with respect to the arrangement of the heating elements of the known technology can of course be applied to the embodiment shown here.

  It is noted that the term “furnace” refers to a means for heating, and the term “furnace chamber” refers to a load and the volume in which the furnace is located.

  The furnace chamber 18 further comprises a charge compartment 19 for containing and holding the article 5 to be processed. The furnace chamber 18 is further positioned with a fan 30 for circulating the pressure medium in the furnace chamber 18 to enhance the inner convection loop so that the pressure medium flows upward through the compartment for loading. And a downward flow along the peripheral portion 12 of the furnace chamber. The furnace chamber 18 is surrounded by the heat insulating casing 3. The bottom of the casing 3 has a lower heat insulating portion 6 provided with a passage 37 for supplying the pressure medium to the furnace chamber 18.

  Furthermore, the pressure vessel 1 has a heat exchanger unit 33 located at the bottom of the pressure vessel 1 below the furnace chamber 18 and the lower heat insulating part 6. The heat exchanger unit 33 is arranged for at least one of exchanging heat energy with the pressure medium, dissipating, and absorbing.

  The pressure vessel 1 further has a fan 31 positioned below the furnace chamber 18 to guide the pressure medium to the furnace chamber.

  Furthermore, the outer wall of the pressure vessel 1 can be provided with a plurality of channels or tubes (not shown), into which coolant for cooling can be provided. In this way, the container wall can be cooled to protect the container from unwanted heat. The refrigerant is preferably water, but may be other refrigerants. The flow of the refrigerant is shown in FIG. 1 by arrows on the outside of the pressure vessel.

  Although not shown, the pressure vessel 1 can be opened and thus the article in the pressure vessel 1 can be removed. This can be accomplished in many different ways, all of which are obvious to those skilled in the art.

  The operation of an exemplary press apparatus according to an embodiment of the present invention is described below. In the following description, a processing cycle can have several states, such as a loading state, a pressing state and / or a heating state, a cooling state, a quenching state, a super quenching state, and a removal state.

  First, the pressure vessel 1 can be opened and accessed to the furnace chamber 18 and the compartment 19 for the loading of this furnace chamber. This can be done in many different ways known in the art, and no further explanation is necessary for an understanding of the principles of the invention.

  The article to be pressed is then placed in the compartment 19 for the charge and the pressure vessel 1 is closed.

  When the article is placed in the compartment 19 for loading of the pressure vessel 1, the pressure medium is supplied to the pressure vessel 1 by, for example, a compressor, a pressurized storage tank (pressure supply unit), a cryogenic pump, or the like. The The supply of pressure medium into the pressure vessel 1 continues until the desired pressure is obtained inside the pressure vessel 1.

  During or after the supply of the pressure medium into the pressure vessel 1, the furnace (heating member) 36 of the furnace chamber 18 is driven to increase the temperature inside the compartment for loading. If necessary, the supply of pressure medium is continued and the pressure is increased until the desired pressure for the pressing process and the desired temperature below the desired pressing temperature are obtained. The final pressure is then increased by increasing the temperature in the furnace chamber 18, thus achieving the desired press pressure. Instead, the desired temperature and pressure are achieved simultaneously, or the desired pressure is achieved after the desired temperature is achieved. Those skilled in the art will appreciate that any suitable method known in the art can be utilized to achieve the desired press pressure and temperature. For example, it is possible to equalize the pressure in the pressure vessel and the high pressure supply, further pressurize the pressure vessel with a compressor, and simultaneously heat the pressure medium further. The inner convection loop can be driven by a fan 30 contained in the furnace chamber 18 to achieve a uniform temperature distribution.

  According to embodiments described herein, the desired pressure is above about 200 bar and the desired temperature is above about 400 ° C.

  After the temperature and pressure are maintained, i.e. after a time selected in the actual pressing state, the temperature of the pressure medium decreases, i.e. the cooling state is started. With regard to the embodiment of the press apparatus, the cooling state can have, for example, at least one of at least one quenching state and a super-quickening state, as described below.

  The pressure medium used during the pressing state can be discharged from the pressure vessel 1 when the temperature drops sufficiently. For some pressure media, it may be advantageous to discharge the pressure media to a tank or the like for recycling.

  After depressurization, the pressure vessel 1 is opened and thus the pressed article 5 can be removed from the compartment 19 for the charge.

  FIG. 2 shows a hot isostatic pressing apparatus according to another embodiment of the present invention. In this embodiment, the first guide passage 10 is formed between the inside of the wall of the pressure vessel and the casing 3. The first guide passage 10 is used for guiding the pressure medium from the top to the bottom of the pressure vessel 1.

  Further, the heat insulating casing 3 includes a heat insulating portion 7 and a housing 2 disposed so as to surround the heat insulating portion 7. The housing 2 thermally seals the inside of the pressure vessel 1 in order to reduce heat loss.

  Further, the second guide passage 11 is formed between the housing of the furnace chamber 18 and the heat insulating portion 7 of the furnace chamber 18. The second guide passage 11 is used to guide the pressure medium toward the top of the pressure vessel. In the second guide passage 11, the pressure medium is supplied to the second guide passage in the same manner as the opening 13 at the top of the pressure vessel for allowing the pressure medium to flow into the first guide passage 10. An inlet 14 is provided for supply.

  The insulating part 7 is provided with an opening (or gap) 15 in order to supply the pressure medium to the second guide passage via the inlet 14. These inlets 14 are preferably located below the upper edge of the lower insulating part 6. As a result, the outer convection loop is formed by the first and second guide passages 10, 11 below the lower heat insulating part 6, similar to the lower part of the pressure vessel 1.

  Pressing the article 5 with the pressing device according to FIG. 2 takes place substantially as described above. However, when the article is pressed by this pressing device, the heat exchanger unit 33 is cooled by the pressure medium flowing from the first guide passage 10. The pressure medium is cooled by contact with the outer wall of the pressure vessel 1. Subsequently, the outer wall is cooled by a coolant such as water from the outside of the pressure vessel. The pressure medium absorbs heat from the heat exchanger unit 33 and subsequently dissipates the heat and passes through the opening 15 to the second guide passage 11. Then, the valve 32 is closed (not shown). In this embodiment, the heat exchanger unit can be effectively cooled during the pressing and heating of the article to prepare the heat exchanger unit 33 for other ultra-quenching conditions.

  When the cooling of the article is performed in the press apparatus shown in the example, the heat exchanger unit 33 absorbs heat from the pressure medium and is subsequently heated by the article 5 as shown in FIG. This results in a cooling of 5. With respect to the embodiment shown in FIG. 2, the cooling state includes only one state, which is referred to herein as a super-quenching or super-quenching state. The ultra-quenching condition demonstrates that the heat exchanger unit 33 is used to cool the pressure medium before entering the furnace chamber 18 through the passage 37 (valve 32 is now open). . Therefore, thereafter, the heat exchanger unit 33 absorbs heat energy from the article 5 by the pressure medium.

  Referring to FIG. 3, a further embodiment of a pressing device according to the present invention is shown. Here, the pressure vessel 1 is a fixed guide arrangement, such as at least one wall or buffer, for guiding the pressure medium in the first guide passage 10 to the lower part of the heat exchanger unit 33. It further has a body 45. This allows the heat exchanger unit 33 to dissipate heat differently during heating, compared to the heat exchanger in the press device of FIG.

  The pressing state, heating state, and cooling state of the embodiment illustrated in FIG. 3 are performed in the same manner as the embodiment shown in FIG. For efficient utilization of the heat exchanger unit 33 in this embodiment, at least one further inlet (not shown) to the channel 37 that can be located above the valve 32 near the lower insulating part 6 ) Can be provided. In this way, the flow of the pressure medium can be controlled to pass through the exchanger unit during the supercooling condition.

  In a further embodiment of the pressing device according to the invention, the pressure vessel 1 has an outer movable guide structure 35, as shown in FIG. By means of this outer guiding structure, the flow of the pressure medium through the heat exchanger unit 33 can be controlled to be directed upward or downward. Furthermore, the flow of the pressure medium passes through the heat exchanger unit 33 or does not flow through the heat exchanger unit 33, thus not exchanging heat energy with this heat exchanger unit. Can be controlled. The outer guiding arrangement can take an upper position, a lower position, or a predetermined position between the upper position and the lower position.

  In the exemplary embodiment of the press device according to FIG. 4, the cooling state comprises three states. These three states are referred to herein as a quench state including a cold heat exchanger unit 33, a quench state including a hot heat exchanger unit 33, and a super quench state.

  During the super-cooling of the article in the pressing device according to FIG. 4, the outer guiding structure 35 is located in its lower position. Thereby, the flow of the pressure medium has a downward direction through the heat exchanger unit 33. If the fan 31 generates sufficient flow through the passage 37, there will be a downward flow of pressure medium from the openings 15, while the flow of pressure medium at these openings 15 will be more through the passage 37. Has an upward direction for proper flow. As a result, when the fan 31 is relatively fast, the outer convection loop will be filled and the flow will cease to be fast.

  If it is desired not to use the heat exchanger unit 33 for ultra-quenching for a selected predetermined time, it is possible to operate the press device in a quench condition that includes a hot or cold heat exchanger unit 33. is there. Here, the terms “hot” and “cold” are given with respect to the temperature of the pressure medium surrounding the heat exchanger unit. In this way, if the heat exchanger unit 33 is cooler than the pressure medium, the booster effect of the heat exchanger unit 33 can be applied, for example, at different stages of the processing cycle.

  If the heat exchanger unit 33 is hot, i.e. the temperature of the heat exchanger unit 33 is higher than the temperature of the surrounding pressure medium, the outer guiding structure 35 is located in its upper position. This allows the cold pressure medium to pass under the heat exchanger unit 33 to the passage 37. When the fan 31 is operated at a relatively low speed, a part of the pressure medium flows through the second heat exchanger unit 33 into the opening 15 and further into the second guide passage 11. However, it is preferred to operate the fan so that the majority of the pressure medium flows under the heat exchanger unit 33 and through the open valve 32 to the passage 37.

  If the heat exchanger unit 33 is cold, i.e. if the temperature of the heat exchanger unit 33 is lower than the temperature of the surrounding pressure medium, the outer guide structure 35 is located in its lower position, thereby The relatively hot pressure medium can flow over the heat exchanger unit 33 and into the passage 37 via the open valve 32. Further, part of the pressure medium enters the opening 15 and passes through the second guide passage 11.

  When the article is heated, the outer guide structure is located in its upper position. Thereby, the flow of the pressure medium has an upward direction through the heat exchanger unit 33. The valve 32 is closed. The pressure medium cooled by the outer wall of the pressure vessel 1 cools the heat exchanger unit 33, passes through the opening 15, and passes through the second guide passage 11. In this way, the heat exchanger unit 33 is prepared for another cooling state.

  According to FIG. 5, a further embodiment of a pressing device according to the invention is shown. Here, the pressure vessel 1 further includes an inner movable guide structure 34 for controlling the flow of the pressure medium. Accordingly, the pressure vessel 1 has inner and outer movable guide structures 34, 35. The inner and outer guide structures 34, 35 improve the control of the pressure medium flow through or through the heat exchanger unit 33 as compared to embodiments having only the outer guide structure 35.

  Referring to FIG. 5, the pressing and heating of the article 5 is shown. The flow of the pressure medium flows through the heat exchanger unit 33 to the first guide passage 11 through the opening 15. The valve 32 is closed. In this way, the heat exchanger unit 33 is cooled during heating and pressing of the article 5 so that after the cooling state of the article 5 (as described below) is complete, It is possible to get started.

  With respect to the pressing device according to FIG. Again, the terms “hot” and “cold” are interpreted with respect to the temperature of the pressure medium surrounding the heat exchanger unit 33.

  With reference to FIGS. 6 to 8, the cooling state of the pressing device according to FIG. 5 will be described in more detail.

  In a quench condition involving a cold heat exchanger unit 33, as shown in FIG. 6, the flow of pressure medium passes over the heat exchanger unit 33 and then enters the passage 37 via the open valve 32, It enters the furnace chamber 18 through the lower insulating part 6. As can be seen from FIG. 6, the outer and inner guiding structures 34, 35 are located in their lower position. In this way, if desired, the booster effect of the heat exchanger unit 33 can be divided and used in different cases.

  According to FIG. 7, a quenching condition involving a hot heat exchanger unit 33 is shown. Here, the inner and outer guide structures 34, 35 are located in their upper positions. In this way, the flow of pressure medium proceeds below the heat exchanger unit 33 and is guided through the open valve 32 to the passage 37. This is appropriate when the temperature of the pressure medium is lower than the temperature of the heat exchanger unit 33. In this state, only the cooling effect from the pressure vessel wall is used to cool the pressure medium and then cool the article 5. Therefore, there is no booster effect. With respect to the embodiment shown in FIG. 7, during a quench condition involving a hot heat exchanger, when the speed of the fan 31 is relatively slow, there is a flow through the heat exchanger unit 33 in the upward direction as indicated by arrow 101. is there.

  In the super-quenching state, as shown in FIG. 8, the inner valve structure 34 is located at its upper position, and the outer valve structure 35 is located at its lower position. Thus, the flow of the pressure medium is guided downward through the heat exchanger unit 33. The valve 32 is open to allow the pressure medium to enter the passage 37 and be pumped by the fan 31 to the furnace chamber 18.

  Furthermore, the hot isostatic pressing device according to the embodiment described above has a controllable restriction at the inlet 14 for further improvement of the booster effect achieved by the heat exchanger unit. Can do. This limiting part can be a valve or the like. Preferably, this restriction is adjusted to allow a small flow of pressure medium through these inlets 14 during the superquenching condition.

  In a further embodiment of the hot isostatic pressing device, the opening 15 can have a controllable limit for further improvement of the booster effect achieved by the heat exchanger unit. Again, this restriction can be a valve or the like. For example, it can be effective to completely close these openings 15 by means of a restriction without using a heat exchanger unit during quenching.

  Further, in an embodiment of the hot isostatic pressing apparatus, the orifice 16 can have a controllable restriction for further improvement of the booster effect.

  In a further embodiment, at least one of the inner and outer guide structures is provided on a stationary wall portion having upper and lower valves so as to control the flow of pressure medium as described in detail above. Can be replaced. For example, closing the upper valve and opening the lower valve corresponds to setting the guide structure in the upper position.

  Further embodiments of the present invention will become apparent to those skilled in the art after reading the above description. For example, further embodiments can be provided by a combination of a fixed outer valve and a movable inner valve, or a combination of a fixed inner valve and a movable outer valve. Furthermore, those skilled in the art will understand that it is possible to build a pressing device having only a movable inner valve.

  Although the description and drawings herein disclose embodiments and examples including selection of components, materials, temperature regions, pressure ranges, etc., the invention is not limited to these specific examples. Many changes and modifications may be made without departing from the scope of the invention as defined by the appended claims.

DESCRIPTION OF SYMBOLS 1 ... Pressure vessel, 3 ... Thermal insulation casing, 5 ... Article, 6 ... Lower heat insulation part, 7 ... Thermal insulation part, 10 ... 1st guide passage, 11 ... 2nd guide passage, 18 ... Furnace chamber, 31 ... Flow Generator 33 ... Heat exchange unit 34, 35 ... Guide structure 36 ... Furnace

Claims (10)

A furnace chamber (18) having an insulating casing (3) and a furnace (36) for heating the pressure medium during pressing and configured to receive and hold the article (5);
A hot vessel for processing articles by hot isostatic pressing comprising a pressure vessel (1) having a heat exchanger unit (33) configured to exchange heat energy with the pressure medium. A hydraulic press device,
The heat exchanger unit (33) is arranged under the furnace chamber (18) and in the pressure vessel (1) so as to be completely surrounded by the pressure vessel (1) during operation of the press device. And
The heat exchanger unit (33) is configured such that the pressure medium is used to cool and heat the heat exchanger unit (33);
In cooling of the article, when the heat exchanger unit (33) temperature is lower than the pressure medium, heat is transferred to the heat exchanger unit (33) from the pressure medium, during the heating of the article Thus, when the temperature of the pressure medium is lower than that of the heat exchanger unit (33), heat can be transferred from the heat exchanger unit (33) to the pressure medium.   The hot isostatic pressing apparatus of claim 1, wherein the furnace chamber (18) has a closed top. The thermal insulation casing (3) has a lower thermal insulation part (6),
The hot isostatic pressing device according to claim 1 or 2, wherein the heat exchanger unit (33) is located under the lower heat insulating portion (6).   A first guide passage (10) is formed between the outer wall of the pressure vessel (1) and the casing (3), and the first guide passage (10) extends along the inside of the outer wall. 4. The heat according to claim 1, wherein the heat medium is configured to guide the pressure medium in a downward direction, and thus heat energy is exchangeable between the pressure medium and the outer wall. Interhydrostatic press.   The hot isostatic pressing apparatus of claim 4 further comprising means for cooling configured to provide a flow of refrigerant along the outer wall of the pressure vessel (1).   The pressure vessel (1) further includes a flow generator (31) for pumping a pressure medium into the furnace chamber (18), and the flow generator (31) is a fan, an ejector, or a pump. The hot isostatic pressing apparatus according to any one of claims 1 to 5.   The pressure vessel has passed through the heat exchange unit (33) or the heat exchange with the pressure medium to avoid exchange of thermal energy between the pressure medium and the heat exchanger unit (33). A movable guide arrangement (34, configured to guide the flow of the pressure medium through the heat exchanger unit (33) in order to exchange heat energy with the exchanger unit (33). 35) The hot isostatic pressing apparatus according to any one of claims 1 to 6, further comprising:   The hot isostatic pressing apparatus according to claim 7, wherein the guide structure (34, 35) has a first valve structure (35) disposed around the heat exchanger unit (33). The guide arrangement (34, 35) has a second valve arrangement (34),
The hot isostatic pressing apparatus according to claim 7 or 8, wherein the heat exchanger unit (33) is arranged around the second valve component (34). The casing (3)
An insulating part (7);
A housing (2) disposed around the heat insulating portion (7), and thus a second guide passage (11) is interposed between the heat insulating portion (7) and the housing (2). 10. The hot static air according to claim 1, wherein the second guide passage is configured to guide the pressure medium in an upward direction in the second guide passage (11). Hydraulic device.