Patent Grant
9433989
The present invention relates to a hot press forming method and a hot press forming die of a metal sheet.
In recent years, as means for shaping steel sheet for auto parts using high strength steel sheet, hot press forming has increasingly been employed. Hot press forming shapes the steel sheet at a high temperature to thereby form it at a stage of a low deformation resistance and then rapidly cools it to quench harden it. With hot press forming, it is possible to press-form parts which are high in strength and are high in shape precision without causing deformation or other shaping problems after shaping.
Specifically, with the hot press forming method, first, steel sheet which has been heated in advance by a heating furnace to a predetermined temperature is supplied to a press die. After this, in a state placed on the bottom die (die) or in a state lifted from the bottom die by lifters or other fixtures built in the bottom die, a top die (punch) is descended to the bottom die limit. Next, the steel sheet is cooled for a certain time (usually 10 seconds to 15 seconds) to cool the steel sheet to a desired temperature. Further, after the cooling finishes, the shaped steel sheet is taken out from the die, then a new steel sheet which has been heated to a predetermined temperature is supplied to the press die. The steel sheet is quenched, tempered, and otherwise heat treated in the cooling process. Therefore, in hot press forming, freely controlling the cooling rate from the viewpoint of the heat treatment characteristics of the steel sheet, obtaining a uniform cooling rate at the steel sheet as a whole from the viewpoint of stability of quality, and shortening the time required for the cooling process after shaping the steel sheet from the viewpoint of productivity, are important.
As means for shortening the cooling time of the shaped steel sheet, it has been proposed to not make the die directly rob heat from the steel sheet, but to feed another medium, for example, water, to the surface of the steel sheet (for example, PLT 1). In particular, in the hot press forming apparatus which is described in PLT 1, the inside surface of the die is provided with a plurality of independent projections of certain heights and channels for water which are communicated with plurality of locations at the inside surface of the die are provided inside the die. Due to this, it is possible to run coolant through the channels inside of the die in the clearances, which are formed by the projections, between the inside surface of the die and the steel sheet. For this reason, it is possible to cool the metal sheet in a short time and raise the productivity of the hot press forming operation. Further, this quenching by rapid cooling enables the steel sheet to be raised in hardness and the strength of the shaped part to be greatly improved.
Further, as means for shortening the time which is required for the cooling process after shaping the steel sheet, it has been proposed to arrange a storage container storing a coolant as close to the steel sheet as possible (for example, PLT 2). In particular, the die which is described in PLT 2 is provided with a storage container which stores a coolant, a plurality of feed holes which feed coolant which is stored in the storage container to the steel sheet, and a coolant feed control device which is provided between the storage container and the feed holes. By having a storage container of coolant arranged inside the die in this way, it is possible to shorten the distance between the storage location of the coolant and feed locations of the coolant. Due to this, it becomes possible to immediately feed coolant to the steel sheet after the control device is sent a coolant feed instruction, and therefore the time from press forming the steel sheet to the end of the cooling process can be shortened.
PLT 1: Japanese Patent Publication No. 2005-169394 A
PLT 2: Japanese Patent Publication No. 2007-136535 A
In this regard, in general the heat conduction rate of a liquid is higher than the heat conduction rate of a gas, and therefore when using a liquid state coolant as a coolant for cooling the metal sheet after being pressed, the metal sheet can be cooled quickly compared with the case of using a gas state coolant. From this viewpoint, in both the above PLTs 1 and 2, as the coolant, a liquid, in particular water, is used.
In this regard, when using a liquid state coolant for cooling the metal sheet, even after stopping the feed of the liquid state coolant, the liquid state coolant remains on the surface of the metal sheet. This liquid state coolant does not remain on the entire surface of the metal sheet uniformly, but locally deposits on the surface of the metal sheet. In this case, regions where the liquid state coolant remains are rapidly cooled, while regions where liquid state coolant does not remain are not cooled that much. For this reason, the metal sheet is unevenly cooled and as a result the metal sheet becomes uneven in strength. Further, when using a liquid state coolant comprised of water or another highly corrosive liquid (liquid which easily causes a metal etc. to corrode), if the liquid state coolant remains on the surface of the metal sheet, corrosion of the metal sheet will be invited.
For this reason, to suppress uneven strength or corrosion of a metal sheet, it is considered necessary to remove the liquid state coolant which has deposited on the surface of the metal sheet as quickly as possible after pressing.
Therefore, in consideration of the above problem, an object of the present invention is to provide a hot press forming method and a hot press forming die which can remove the liquid state coolant which has deposited on the surface of the metal sheet as fast as possible when stopping the feed of the liquid state coolant.
The inventors studied various hot press forming methods and various hot press forming dies relating to the removal of the liquid state coolant which deposited on the surface of a metal sheet when stopping the feed of the liquid state coolant.
As a result, they discovered that by providing the hot press forming die with a plurality of feed holes able to feed fluid to the metal sheet and by not only feeding liquid state coolant through these feed holes to the surface of the metal sheet, but also blowing a gas on the surface of the metal sheet, it is possible to remove the liquid state coolant which has deposited on the surface of the metal sheet member as fast as possible when stopping the feed of the liquid state coolant.
The present invention was made based on the above findings and has as its gist the following:
According to the present invention, it is possible to quickly remove the liquid state coolant which was deposited on the surface of a metal sheet at the time of stopping the feed of the liquid state coolant and, as a result, it is possible to suppress uneven strength of the shaped metal sheet and corrosion of the metal sheet.
Below, referring to the figures, embodiments of the present invention will be explained in detail. Note that, in the following explanation, similar components are assigned the same reference numerals.
As will be understood from
The hot press forming die 10 has a bottom die 20 which is disposed in a lower side and a top die 21 which is disposed in a upper side. The bottom die 20 is arranged on the base 22. The top die 21 is arranged vertically above the bottom die 20 and facing the bottom die 20 and is configured to be able to be lifted by a lift mechanism 23 in the vertical direction. The lift mechanism 23 performs a lift operation based on a control signal from the control unit 13.
The bottom die 20 is provided with positioning pins 30 for positioning with prepierced holes P which are preliminarily provided in the steel sheet K. The positioning pins 30 are arranged so as to pass through the inside of the bottom die 20 and stick out vertically upward from the top surface of the bottom die 20.
The top ends of the positioning pins 30 are formed into substantially conical shapes. For this reason, by fitting the top ends of the substantially conical shapes in the prepierced holes P of the steel sheet K, as shown in
Further, the positioning pins 30 are slidable with respect to the bottom die 20. Further, they are supported at the top surface of the base 22 through not shown biasing means (for example, springs). For this reason, if the top die 21 descends and the positioning pins 30 are pushed down, the steel sheet K is pushed down together with the positioning pins 30.
Further, at the forming surface 20a of the bottom die 20, as shown in
The header 40, as shown in
Note that, in the example which is shown in
Further, in the present embodiment, the forming surface 20a of the bottom die 20, as shown in
Note that, to enable the coolant etc. which is fed from the feed holes 41a to be smoothly discharged through the exhaust suction holes 50, the exhaust suction holes 50 should be atmospheric pressure or less. That is, for example, if opening the end of the suction pipe 51 at the opposite side to the exhaust suction holes 50 to the atmosphere, the extraneous coolant around the surface of the steel sheet K will be discharged outside of the die. For this reason, the exhaust mechanism 52 need not necessarily be provided.
Note that, in the present embodiment, water is used as the coolant which is fed from the coolant feed source 11, but aside from water, anti-rust oil which has a rust prevention function or another liquid state coolant may also be used. Further, a mist of water or anti-rust oil etc. or other mist-like coolant can be used. Further, in the present embodiment, as the gas which is fed from the gas feed source 12, compressed air is used, but the invention is not limited to this. For example, so long as a gas which is fed at a pressure of atmospheric pressure or more, nitrogen gas or another gas other than air may be used. In particular, when using nitrogen as the gas which is fed from the gas feed source 12, the surroundings of the steel sheet K may be a nonoxidizing atmosphere, and therefore rusting of the steel sheet K can be further suppressed.
Next, the method of using the thus configured hot press forming apparatus 1 to form steel sheet K by hot press will be explained next.
First, when starting the press forming of the steel sheet K, the valves 47 and 48 are closed. Due to this, the pipes 41 of the bottom die 20 are not fed with either coolant or gas. In such a state, a steel sheet K which has been heated to a predetermined temperature (for example, 700° C. to 1000° C.) is placed by a conveyor apparatus (not shown) between the bottom die 20 and the top die 21. Specifically, the steel sheet K is placed on the positioning pins 30 of the bottom die 20 so that the prepierced holes P fit into the positioning pins 30.
Next, the top die 21 is moved in the vertical direction so as to approach the bottom die 20 to press the steel sheet K which is clamped between the top die 21 and bottom die 20. When the top die 21 descends to the bottom die limit and the press operation is completed, the valve 47 which is provided at the coolant feed pipe 45 is opened. When the valve 47 is opened, coolant is fed from the coolant feed source 11 through the coolant feed pipe 45, header 40, pipes 41, and feed holes 41a to the surface of the steel sheet K. Due to this, the steel sheet K starts to be rapidly cooled.
Further, if the top die 21 is held at the bottom die limit for a certain time and the steel sheet K is cooled to a temperature of for example 200° C. or less, next, the valve 47 which is provided at the coolant feed pipe 45 is closed and the valve 48 which is provided at the gas feed pipe 46 is opened. If the valve 48 is opened, the gas is blown from the gas feed source 12 through the gas feed pipe 46, header 40, pipes 41, and feed holes 41a to the surface of the steel sheet K. At this time, if the pressure of the gas which is fed from the feed holes 41a is too high, the pressurizing energy becomes high, while conversely if too low, gas is no longer evenly ejected from the feed holes 41a, and therefore the pressure is set to 0.1 to 1.0 MPa, preferably 0.3 to 0.7 MPa, more preferably 0.4 to 0.5 MPa. The flow rate is determined by the pressure of the gas and the nozzle shape and is set to 20 to 2000 ml/sec, preferably 300 to 1000 ml/sec, more preferably 400 to 700 ml/sec.
Further, the temperature of the gas which is fed from the feed holes 41a is set to 200° C. or less, preferably ordinary temperature. That is, the steel sheet K is cooled by the coolant down to 200° C. or less, whereby it is quenched. For this reason, if blowing 200° C. or more gas, the steel sheet K becomes at a temperature of 200° C. or more, the steel sheet K is annealed, and the hardness falls.
Further, in the present embodiment, along with the closing of the valve 47 or the opening of the valve 48, the top die 21 is risen to top die limit. If the top die 21 rises in this way, the positioning pins 30 which had been pushed downward by the top die 21 rise and the steel sheet K is separated from the forming surface 20a of the bottom die 20. Due to this, a clearance is formed between the bottom surface of the steel sheet K and the forming surface 20a of the bottom die 20.
Further, if blowing gas to the surface of the steel sheet K and thereby finishing removing the coolant on the surface of the steel sheet K, the shaped steel sheet K is taken off by the conveyor apparatus (not shown) from the positioning pins 30 and is unloaded from the hot press forming apparatus 1. Further, a heated new steel sheet K is placed by a conveyor apparatus (not shown) on the positioning pins 30 of the hot press forming apparatus 1 and this series of steps in the hot press forming operation is repeated.
Next, the advantageous effects of the hot press forming die and hot press forming method according to the above embodiment will be explained.
According to the above embodiment, in the state with a steel sheet K placed on the same hot press forming die 10, the surface of the steel sheet K was fed with coolant from the coolant feed source 11 and blown with gas from the gas feed source 12. For this reason, it is possible to blow gas to the surface of the steel sheet K immediately after stopping feeding of the coolant to the surface of the steel sheet K. For this reason, it is possible to quickly remove the coolant which has deposited on the surface of the steel sheet K.
Note that, the time which is taken for removing the coolant which is deposited on the surface of the steel sheet K depends on the temperature and sheet thickness of the shaped steel sheet K (that is, the heat capacity of the steel sheet K). For example, if making the pressure of the gas which is fed from the feed holes 41a 0.4 MPa, making the flow rate 60 to 70 ml/sec, and making the temperature ordinary temperature, if the temperature of a sheet thickness 1.4 mm steel sheet K right after pressing is about 150° C., it is possible to remove the coolant which deposited on the steel sheet K in about 3 seconds from the start of blowing of the gas. Further, in the case of sheet thickness 1.2 mm steel sheet K, it is possible to remove the coolant which deposited on the steel sheet K in about 7 seconds from the start of blowing of the gas.
In this way, it is possible to quickly remove the coolant which deposited on the surface of the steel sheet K, and therefore it is possible to suppress uneven cooling of the steel sheet K due to coolant remaining on the surface of the steel sheet K in an uneven manner. Accordingly, it is possible to keep the strength of the steel sheet K from becoming uneven. Further, even when using water as a coolant, it is possible to keep rust from forming due to the coolant which remains on the surface of the steel sheet K.
Further, after being pressed by the hot press forming die 10, the surface of the steel sheet K is sprayed with gas whereby the scale which formed on the surface of the steel sheet K due to the pressing etc. can be removed. In particular, if the coolant is removed from the surface of the steel sheet K and the surface of the steel sheet K is dried, the scale easily peels off, and therefore in the present embodiment, the scale can be removed more efficiently.
Further, in the above embodiment, the clearance H is formed when blowing gas on the surface of the steel sheet K. By such a clearance H being formed, the gas which is fed from the gas feed source 12 through the feed holes 41a is easily exhausted and the flow rate of the gas which passes over the surface of the steel sheet K can be raised. Due to this, the coolant which deposited on the surface of the steel sheet K can be efficiently removed. Note that, if the clearance H is too small, it becomes difficult to draw in the surrounding gas while conversely if too large, the blown gas will disperse and the effect of blowing it will fall, and therefore the clearance is 1 mm to 100 mm or so, preferably 5 to 20 mm, more preferably 8 to 15 mm.
Next, referring to
The outside die 61 is provided with a plurality of outside pipes 64 which run from the forming surface 61a which contacts the steel sheet K to the sliding surface 63 between the outside die 61 and inside die 71, through the inside of the outside die 61. The ends of the outside pipes 64 at the forming surface 61a sides, in the same way as the feed holes 41a of the first embodiment, act as feed holes 64a which feed fluid to the surface of the steel sheet K. Therefore, the outside pipes 64 can be said to be arranged between the feed holes 64a and the sliding surface 63. The forming surface 61a, like the forming surface 20a of the first embodiment, is formed with a plurality of projections.
Further, the outside die 61 is supported through elastic members 65 on the base 22. As the elastic members 65, for example, springs of predetermined stroke lengths are used. For this reason, if the top die 21 descends and pushes the outside die 61, the outside die 61 is guided by the sliding surface 63 while being pushed downward. The guide mechanism for sliding the outside die 61 and the inside die 71 may be provided separately from the sliding surface 63.
Inside of the inside die 71, a plurality of first inside pipes 72, a plurality of second inside pipes 73, a first header 74 which connects the plurality of first inside pipes 72 and coolant feed source 11, and a second header 75 which connects the plurality of second inside pipes 73 and gas feed source 12 are provided. The first inside pipes 72 are provided in the same number as the outside pipes 64 of the outside die 61 and run from the sliding surface 63 to the first header 74 through the inside of the inside die 71. The second inside pipes 73 are also provided in the same number as the outside pipes 64 of the outside die 61 and run from the sliding surface 63 to the second header 75 through the inside of the inside die 71.
The first header 74, as shown in
The ends of the second inside pipes 73 at the sliding surface 63 sides are arranged so as to be aligned with the ends of the outside pipes 64 at the sliding surface 63 sides in the state where the outside die 61 is not pushed by the top die 21. Conversely, the ends of the first inside pipes 72 at the sliding surface 63 sides are arranged so as not to be aligned with the ends of the outside pipes 64 at the sliding surface 63 sides in the state where the outside die 61 is not pushed by the top die 21. Therefore, in the state where the outside die 61 is not pushed by the top die 21, only the second inside pipes 73, that is, only the gas feed source 12, is connected to the outside pipes 64.
On the other hand, the ends of the first inside pipes 72 at the sliding surface 63 sides are arranged so as to be aligned with the ends of the outside pipes 64 at the sliding surface 63 sides in the state where the outside die 61 is pushed down to the bottom die limit by the top die 21. Conversely, the ends of the second inside pipes 73 at the sliding surface 63 sides are arranged so as not to be aligned with the ends of the outside pipes 64 at the sliding surface 63 sides in the state where the outside die 61 is pushed down to the bottom die limit by the top die 21. Therefore, in the state where the outside die 61 is pushed down to the bottom die limit by the top die 21, only the first inside pipes 72, that is, only the coolant feed source 11, is connected to the outside pipes 64.
In other words, in the present embodiment, the outside die 61 and the inside die 71 slide relative to each other linked with the operation of the top die 21. Due to this, it is possible to switch between a state where the outside pipes 64 are connected to the first inside pipes 72 and a state where they are connected to the second inside pipes 73. Note that, when with just the metal surfaces sliding together, it is difficult to seal in the coolant against the pressure of the coolant, the ends of the inside pipes 72 and 73 at the sliding surface 63 sides or the ends of the outside pipes 64 at the sliding surface 63 sides may be provided with rubber rings or other seal members.
Next, the method of using the thus configured hot press forming apparatus to hot press form steel sheet K will be explained.
First, when starting the press forming of the steel sheet K, the valve 48 which is provided at the gas feed pipe 46 is closed and the valve 47 which is provided at the coolant feed pipe 45 is opened. At this time, the outside die 61 is not pushed by the top die 21, and therefore is lifted by the elastic members 65. Therefore, the outside pipes 64 are connected, with the second inside pipes 73. For this reason, even if the valve 47 is opened, the coolant feed source 11 feeds coolant to the first inside pipes 72 at a predetermined pressure and does not feed coolant to the outside pipes 64. In other words, the coolant which is fed to the first inside pipes 72 is stopped by the sliding surface 63 of the outside die 61 and is filled at a predetermined pressure to the ends of the first inside pipes 72. On the other hand, the valve 48 is closed, and therefore even if the second inside pipes 73 and the outside pipes 64 are connected, the outside pipes 64 are not fed with gas.
Next, a high temperature steel sheet K is placed by a conveyor apparatus (not shown) on the positioning pins 30 of the bottom die 60. Next, the top die 21 is moved in the vertical direction so as to approach the bottom die 60 to, for example, as shown in
At this time, the outside die 61 is pushed down to the bottom die limit, whereby the outside pipes 64 of the outside die 61 are disconnected from the second inside pipes 73 of the inside die 71 and are connected to the first inside pipes 72. Due to this, the coolant which had been filled to the end of the first inside pipes 72 is immediately fed from the outside pipes 64 to the steel sheet K. The steel sheet K starts to be rapidly cooled right after the steel sheet K is pressed.
Further, if the outside die 61 is pushed down to the bottom die limit and thereby the outside pipes 64 and the second inside pipes 73 are disconnected, the valve 48 which is provided at the gas feed pipe 46 is opened. For this reason, the second inside pipes 73 are fed with gas of a predetermined pressure. In other words, the coolant which was fed to the second inside pipes 73 is stopped by the sliding surface 63 of the outside die 61 and is filled at a predetermined pressure to the ends of the second inside pipes 73.
Further, if the top die 21 is held at bottom die limit for a certain time and the steel sheet K is cooled down to a temperature of for example 200° C. or less, next, the top die 21 is risen to top dead center. If the top die 21 rises to top die limit, the outside die 61 which was pushed down to the bottom die limit is pushed vertically upward by the elastic members 65 which support the outside die 61. As a result, the outside pipes 64 are disconnected from the first inside pipes 72 and are connected to the second inside pipes 73. For this reason, the feed of coolant from the outside pipes 64 to the steel sheet K is immediately stopped. In addition, the gas which filled up to the ends of the second inside pipes 73 is immediately fed from the outside pipes 64 to the steel sheet K, and therefore gas starts to be blown to the steel sheet K immediately after stopping the feed of the coolant. At this time, the pressure etc. of the gas which is fed from the feed holes 64a are set in the same way as in the first embodiment.
Further, when coolant finishes being removed from the surface of the steel sheet K by blowing gas to the surface of the steel sheet K, the shaped steel sheet K is removed by the conveyor apparatus (not shown) from the positioning pins 30 and is unloaded from the hot press forming apparatus. After this, a heated new steel sheet K is placed by the conveyor apparatus (not shown) on the positioning pins 30 of the hot press forming apparatus and this series of steps of the hot press forming operation are repeated.
Next, the advantageous effects of the hot press forming die and hot press forming method according to the above embodiment will be explained.
According to the present embodiment, the outside pipes 64 and the first inside pipes 72 and second inside pipes 73 are switched to be connected and disconnected by making the outside die 61 and the inside die 71 move relative to each other. Therefore, in the present embodiment, a fluid switching means for switching the fluid which is fed to the plurality of feed holes 64a between a coolant and gas can be said to be provided inside of the bottom die. For this reason, the outside pipes 64 and the first inside pipes 72 and second inside pipes 73 are switched to be connected and disconnected at positions close to the feed holes 64a which feed fluid (coolant and gas) to the steel sheet K. In other words, control may be performed to feed and stop the fluid at positions close to the forming surface 61a of the outside die 61, that is, positions close to the steel sheet K to which the fluid is to be fed.
For this reason, in the state where the second inside pipes 73 are closed by the sliding surface 63 of the outside die 61, the gas is fed in advance to the second inside pipes 73 to fill the gas up to the ends of the second inside pipes 73. After this, the outside die 61 can be pushed up to connect the outside pipes 64 and the second inside pipes 73. Due to this, the gas which had been filled in the second inside pipes 73 can be quickly blown from the outside pipes 64 to the steel sheet K. Therefore, compared with the first embodiment, it is possible to more quickly blow gas to the surface of the steel sheet K after stopping the feed of coolant to the surface of the steel sheet K.
Similarly, in the state where the first inside pipes 72 are closed by the sliding surface 63 of the outside die 61, the coolant is fed in advance to the first inside pipes 72 to fill the coolant up to the ends of the first inside pipes 72. After this, the outside die 61 can be pushed down to the bottom die limit to connect the outside pipes 64 and the first inside pipes 72. Due to this, coolant which is filled in the first inside pipes 72 can be quickly blown from the outside pipes 64 to the steel sheet K.
Further, for example, at the bottom die 60 which is shown in
Note that, the outside pipes 64 of the outside die 61 are preferably the same in pipeline lengths. By making the outside pipes 64 the same in pipeline lengths, the times from connection of the outside pipes 64 and the inside pipes 72 and 73 to the start of feed of coolant or gas to the steel sheet K become the same. In this case, it is possible to make the timings of start of cooling and the timings of start of blowing of gas uniform over the surface of the steel sheet K. As a result, the hardness of the steel sheet K after hot press forming can be uniform over the surface.
Note that, the bottom die 60 of the second embodiment can be changed in various ways. Below, modifications of the bottom die 60 are shown.
In the above embodiments, the outside die 61 which is supported by the elastic members 65 is pushed down by the top die 21 whereby the outside die 61 is slid against the inside die 71. However, if the outside die 61 and the inside die 71 can be slid relative to each other, the inside die 71 can be slid and, further, both the outside die 61 and the inside die 71 can be slid. When making the inside die 71 side, for example as shown in
Further, when using the drive mechanism 80, the state where the ends of the outside pipes 64 at the sliding surface 63 sides are connected with the first inside pipes 72, the state where the ends of the outside pipes 64 at the sliding surface 63 sides are connected with the second inside pipes 73, and, in addition, the state where the ends of the outside pipes 64 at the sliding surface 63 sides are not connected to either the first inside pipes 72 and second inside pipes 73 (that is, the state where the ends of the outside pipes 64 at the sliding surface 63 sides face the inside wall surface of the inside die 71) can be switched between. In this case, the valves 47 and 48 no longer need be provided.
Further, in the above embodiments, the dies 61 and 71 were slid in the up-down direction to connect the outside pipes 64 and the inside pipes 72 and 73. However, the arrangements of the pipes 64, 72, and 73 and the directions of relative sliding of the dies 61 and 71 are not limited to those of the present embodiments and can be freely set. For example, when making the dies 61 and 71 slide in the horizontal direction, as shown in
Alternatively, as shown in
Note that, in the above embodiments, the bottom die 60 was configured by an outside die 61 and an inside die 71, but the top die 21 may be configured by an outside die and inside die. Alternatively, both the bottom die 60 and the top die 21 may be configured by outside dies and inside dies. Further, the die comprised of the outside die and inside die may be used for either the projecting die and recessed die which are used for press forming or may be used for both of the projecting die and recessed die.
Further, in the above embodiments, the inside die 71 was provided with only a single header for each kind of fluid, but it is also possible to provide a plurality of headers for each kind of fluid. In this case, for example, taking a coolant as an example, when stopping the feed of coolant to one part of the headers, it is possible to stop the feed of coolant from the first inside pipes 72 and outside pipes 64 which are connected to the first headers 74 to which feed has been stopped, and continue the feed of coolant from the remaining first inside pipes 72 and outside pipes 64. That is, it is possible to selectively stop the feed of coolant. Due to this, it is possible to control the portions of the steel sheet K which are fed with coolant and change the hardness in the plane of the steel sheet K.
Further, in the above embodiments, the hot press forming operation of the steel sheet K as explained, but the invention can also be used for hot press forming a metal sheet other than steel sheet.
Note that, the present invention was explained in detail based on specific embodiments, but a person skilled in the art can make various changes, corrections, etc. without departing from the claims and concept of the present invention.
The present invention is useful when hot press forming steel sheet.
1 hot press forming apparatus
10 hot press forming die
11 coolant feed source
12 gas feed source
13 control unit
20 bottom die
20
a forming surface
21 top die
22 base
23 lift mechanism
30 positioning pin
40 header
41 pipe
42 projection
60 bottom die
61 outside die
63 sliding surface
64 outside pipe
71 inside die
72 first inside pipe
73 second inside pipe
74 first header
75 second header
K steel sheet
P prepierced hole
| Number | Date | Country | Kind |
|---|---|---|---|
| 2011-115176 | May 2011 | JP | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/JP2012/063075 | 5/22/2012 | WO | 00 | 11/8/2013 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2012/161192 | 11/29/2012 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 8556619 | Matsen | Oct 2013 | B2 |
| 20070017272 | Kurisu et al. | Jan 2007 | A1 |
| 20090013749 | Ishimori et al. | Jan 2009 | A1 |
| 20090126447 | Kondo et al. | May 2009 | A1 |
| 20110162424 | Seidel | Jul 2011 | A1 |
| 20140083155 | Matsen | Mar 2014 | A1 |
| 20140295205 | Ota | Oct 2014 | A1 |
| 20140352388 | Balint | Dec 2014 | A1 |
| Number | Date | Country |
|---|---|---|
| 101394950 | Mar 2009 | CN |
| 0710884 | May 1996 | EP |
| 2004-249320 | Sep 2004 | JP |
| 2005-169394 | Jun 2005 | JP |
| 2006-192480 | Jul 2006 | JP |
| 2007-075835 | Mar 2007 | JP |
| 2007-136535 | Jun 2007 | JP |
| 2008-036709 | Feb 2008 | JP |
| 2009-125808 | Jun 2009 | JP |
| 2009-297741 | Dec 2009 | JP |
| Entry |
|---|
| Extended European Search Report, dated Nov. 26, 2014, for European Application No. 12790192.4. |
| International Search Report issued in PCT/JP2012/063075, mailed on Aug. 14, 2012. |
| Number | Date | Country | |
|---|---|---|---|
| 20140069162 A1 | Mar 2014 | US |
