JP6086895B2 - Mold cooling system - Google Patents

Description

  The present invention relates to a mold cooling apparatus for supplying air to a cooling water channel.

  Conventionally, a cooling device such as a die-casting mold that supplies cooling water together with pressurized air supplied by a pressurized air supply source (pressurizing means) to the inside of the mold (cooling water channel) is known (for example, Patent Document 1). In general, the higher the oxygen concentration in the cooling water, the easier it is to rust in the piping of the cooling water, so deoxidation is performed by a deoxygenating device on the cooling water supplied to the cooling water channel (for example, , See Patent Document 2).

JP 2005-046846 A Japanese Patent Laid-Open No. 10-109092

  However, in a conventional cooling device such as a die casting mold, the cooling water supplied to the cooling water passage has an oxygen concentration that is higher by the amount of air supplied by the pressurizing means. There is a problem that the deoxygenation effect is reduced when the oxygen device is returned to the oxygen device.

  The present invention has been made paying attention to the above problem, and an object of the present invention is to provide a mold cooling apparatus capable of suppressing a reduction in the deoxygenation effect of the deoxygenation means provided in the cooling water circulation tank. .

In order to achieve the above object, a mold cooling apparatus of the present invention includes a mold, a cooling water circulation tank, a pressurizing unit, an intermediate tank, and a first cooling water returning unit.
The mold has a first cooling water channel.
The cooling water circulation tank has a deoxygenation means for deoxygenating cooling water for cooling the mold, and stores the cooling water.
The pressurizing means communicates with the cooling water circulation tank, pressure-feeds the pressurized cooling water to the first cooling water channel, and supplies air to the first cooling water channel.
The intermediate tank stores the cooling water discharged from the first cooling water channel and is open to the atmosphere.
The first cooling water return means returns the cooling water stored in the intermediate tank to the cooling water circulation tank.

Therefore, the cooling water pressurized by the pressurizing means is pumped to the first cooling water channel, the air is supplied to the first cooling water channel, and the cooling water discharged from the first cooling water channel is opened to the atmosphere. The cooling water stored in the intermediate tank by the first cooling water return means is returned to the cooling water circulation tank having the oxygen removal means.
That is, the oxygen concentration of the cooling water supplied to the first cooling water channel is increased by the amount of air supplied by the pressurizing means. For this reason, the cooling water is stored in an intermediate tank that is temporarily opened to the atmosphere before being returned to the cooling water circulation tank. As a result, air escapes from the cooling water, so that the oxygen concentration that is increasing is lowered.
As a result, it is possible to suppress a reduction in the deoxygenation effect of the deoxygenation means included in the cooling water circulation tank.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall system diagram of a mold cooling apparatus according to a first embodiment applied to a mold of an aluminum die cast product. It is a whole system diagram of the metallic mold cooling device of Example 1 applied to the metallic mold of an aluminum die casting product, and is an explanatory view explaining the flow of the cooling water at the time of metallic mold cooling. It is a time chart which shows the example of intermittent operation of the 1st cooling water return pump motor according to the amount of water of an intermediate tank.

  Hereinafter, the best mode for realizing a mold cooling apparatus of the present invention will be described based on Example 1 shown in the drawings.

First, the configuration will be described.
FIG. 1 shows an overall system diagram of a mold cooling apparatus according to a first embodiment applied to a mold of an aluminum die cast product. Hereinafter, the configuration of the mold cooling device will be described with reference to FIG.

The mold cooling device 1 according to the first embodiment is applied to a mold of an aluminum die cast product such as a transmission case of a vehicle. The cooling device 1 for the mold 2 includes a mold 2, a cooling water circulation tank 3, a pressurizing device 4 (pressurizing means), an intermediate tank 5, a pure water supply device 6, and a cooling water circulation drive controller 7. It is equipped with.
Further, the cooling device 1 for the mold 2 includes a first cooling water path 11, a second cooling water path 12, a circulation tank outlet-side cooling water path 13, and a first input as a cooling water W channel for cooling the mold 2. A side cooling water passage 14 (pressurizing means), a second inlet cooling water passage 15 (cooling water supply means), an outlet side cooling water passage 16, a first cooling water return water passage 17 (first cooling water return means), A second cooling water return channel 18 (second cooling water return means) and a pure water supply channel 19 are provided.

The mold 2 is a mold 2 included in a die casting machine. The mold 2 is composed of a fixed mold part and a movable mold part of a die casting machine. The movable mold part is provided so as to be able to reciprocate in a direction perpendicular to the mating surface of the fixed mold part.
The mold 2 has a first cooling water channel 11 and a second cooling water channel 12. Pressurized cooling water (cooling water) and air pressurized by the pressurizing device 4 are supplied to the first cooling water channel 11 through the first inlet-side cooling water channel 14. The first cooling water channel 11 has a smaller diameter than the first inlet-side cooling water channel 14. Normal cooling water (cooling water) is supplied from the cooling water circulation tank 3 to the second cooling water channel 12 via the second inlet-side cooling water channel 15. Here, “normal cooling water” refers to the cooling water W stored in the cooling water circulation tank 3 and not pressurized, and the normal cooling water is distinguished from the pressurized cooling water. Use to do.

  The cooling water circulation tank 3 stores the cooling water W. As shown in FIG. 1, the cooling water circulation tank 3 includes a deoxygenation device 31 (deoxygenation means) and a circulation tank outlet side cooling water passage 13. The deoxygenation device 31 deoxygenates the cooling water W stored in the cooling water circulation tank. One end of the circulation tank outlet side cooling water channel 13 is connected to the cooling water circulation tank 3, and the other end is connected to the first inlet side cooling water channel 14 and the second inlet side cooling water channel 15. The circulation tank outlet-side cooling water passage 13 is provided with a circulation tank outlet-side pump 13p. The circulation tank outlet pump 13p drives (operates) the cooling water W in the cooling water circulation tank to the first inlet cooling water passage 14 and the second inlet cooling water passage 15 via the circulation tank outlet cooling water passage 13. Supply.

  The pressurizing device 4 includes a first inlet-side cooling water channel 14 and a pressurizing device main body 41. One end of the first inlet side cooling water channel 14 is connected to the first cooling water channel 11, and the other end is connected to the circulation tank outlet side cooling water channel 13. A pressurizing device main body 41 is provided in the first inlet-side cooling water channel 14. The pressurizing device main body 41 includes a pressurizing pump 411 that pressurizes and pumps the cooling water W, and an air blow device 412 that blows and feeds air to the cooling water W1. Air blower 412 takes in outside air. This pressurizing pump 411 pumps the cooling water W supplied from the circulation tank outlet side cooling water channel 13 from the first inlet side cooling water channel 14 to the first cooling water channel 11 with pressurized cooling water having a pressure higher than that of the normal cooling water. At the same time, air blowing (air blowing) is performed by the air blowing device 412 to repeat water flow (pressure feeding) and drying. When the cooling water W is caused to flow from the first inlet cooling water channel 14 to the first cooling water channel 11 by the operation of the pressurizing pump 411 and the air blowing device 412 of the pressurizing device main body 41, the first inlet cooling water channel 14 The cooling water W easily flows into the first cooling water channel 11 having a small diameter.

  One end of the second inlet side cooling water channel 15 is connected to the second cooling water channel 12, and the other end is connected to the circulation tank outlet side cooling water channel 13.

  The outlet-side cooling water channel 16 has one end communicating with the first cooling water channel 11 and the other end disposed above the intermediate tank 5 and opened in the intermediate tank.

  The intermediate tank 5 stores the pressurized cooling water discharged from the first cooling water channel 11 through the outlet side cooling water channel 16. This intermediate tank 5 is open to the atmosphere. For this reason, the pressurized cooling water discharged from the first cooling water channel 11 becomes the cooling water W that is not pressurized in the intermediate tank 5. The intermediate tank 5 is provided with a level sensor 51. The level sensor 51 detects the amount of cooling water W stored in the intermediate tank 5 (the amount of water in the intermediate tank 5), and outputs the detected amount of water to the cooling water circulation drive controller 7. This level sensor 51 may be one that detects that the amount of water in the intermediate tank 5 has reached a specific level of an upper limit or a lower limit, or that detects a change in the level of the amount of water in the intermediate tank 5. good.

  The first cooling water return channel 17 has one end connected to the cooling water circulation tank 3 and the other end connected to the intermediate tank 5. One end of the first cooling water return water channel 17 is disposed above the cooling water circulation tank 3 and is opened in the cooling water circulation tank. The other end of the first cooling water return channel 17 is immersed in the cooling water W stored in the intermediate tank 5 and is opened in the intermediate tank. The first cooling water return water passage 17 is provided with a first cooling water return pump 17p (first cooling water return means). The first cooling water return pump 17p returns the cooling water W stored in the intermediate tank 5 to the cooling water circulation tank 3 by driving (operation).

  One end of the second cooling water return channel 18 is connected to the second cooling channel 12 and the other end is connected to the cooling water circulation tank 3. The other end of the second cooling water return channel 18 is disposed above the cooling water circulation tank 3 and is opened in the cooling water circulation tank. The second cooling water return water channel 18 is provided with a second cooling water return pump 18p (second cooling water return means). The second cooling water return pump 18p returns normal cooling water from the second cooling water passage 12 to the cooling water circulation tank 3 by driving (operation).

  The pure water supply device 6 supplies pure water to the cooling water circulation tank 3 through the pure water supply water channel 19. The amount of pure water to be supplied is adjusted by a valve or the like included in the pure water supply device 6. The amount of pure water supplied from the pure water supply device 6 is set from the amount of water that evaporates in the first cooling water channel 11 and the second cooling water channel 12 obtained in advance through experiments or the like. The pure water supply device 6 is not limited to pure water and may supply tap water or the like. The pure water supply channel 19 has one end connected to the pure water supply device 6 and the other end connected to the cooling water circulation tank 3. The other end of the pure water supply channel 19 is disposed above the cooling water circulation tank 3 and is opened in the cooling water circulation tank.

  The cooling water circulation drive controller 7 inputs water amount information of the cooling water W stored in the intermediate tank 5 from the level sensor 51, temperature information of the mold 2, and the like. The cooling water circulation drive controller 7 is supplied from the pure water supply device 6 to the cooling water circulation tank 3 based on the input information, pressurization control for operating the pressurizing device body 41 (the pressurizing pump 411 and the air blowing device 412). Pure water supply control for controlling the amount of pure water to be supplied, circulation tank outlet side pump motor control for switching driving (ON) / stop (OFF) of the circulation tank outlet side pump motor 13m of the circulation tank outlet side pump 13p, first cooling The first cooling water return pump 17p is intermittently operated by switching the driving (ON) / stopping (OFF) of the first cooling water return pump motor 17m (first cooling water return means) of the water return pump 17p. Pump motor intermittent operation control, drive (ON) / stop of second cooling water return pump motor 18m (second cooling water return means) of second cooling water return pump 18p Back second coolant to switch the OFF) performing a pump motor control. That is, the cooling water circulation drive controller 7 sends control signals for each control to the pressurizing device body 41, the pure water supply device 6, the circulation tank outlet pump motor 13m, the first cooling in accordance with the cooling of the mold 2. It outputs to the water return pump motor 17m and the 2nd cooling water return pump motor 18m. In this embodiment, an example in which control is performed using one cooling water circulation drive controller 7 will be described. For example, a plurality of controllers are provided in each device such as the pressure device main body 41 and the pure water supply device 6 described above. A configuration may be adopted in which signals are exchanged and controlled by a plurality of these controllers.

  The pure water supply control is performed by controlling the opening degree of a valve or the like included in the pure water supply device 6 according to the amount of pure water supplied from the pure water supply device 6.

In the first cooling water return pump motor intermittent operation control, the first cooling water return pump motor 17m is driven (ON) / stopped according to the amount of the cooling water W detected by the level sensor 51 (the amount of water in the intermediate tank 5). This is done by controlling (OFF). Thereby, the 1st cooling water return pump 17p operates intermittently. That is, when the water amount information of the cooling water W input from the level sensor 51 to the cooling water circulation drive controller 7 reaches the “operation start level” at which the operation of the first cooling water return pump 17p starts, the cooling water circulation drive controller 7 The drive (ON) signal is output to the first cooling water return pump motor 17m, the first cooling water return pump motor 17m is driven (ON), and the operation of the first cooling water return pump 17p is started. When the water amount information of the cooling water W input from the level sensor 51 to the cooling water circulation drive controller 7 reaches the “operation stop level” at which the operation of the first cooling water return pump 17p is stopped, the cooling water circulation drive controller 7 Then, a stop (OFF) signal is output to the first cooling water return pump motor 17m, the first cooling water return pump motor 17m is stopped (OFF), and the operation of the first cooling water return pump 17p is stopped.
Here, the “operation start level (the amount of predetermined cooling water W)” is the amount of water that prevents the cooling water W from overflowing from the intermediate tank 5 due to the amount of pressurized cooling water discharged from the first cooling water channel 11. It is. The “operation stop level” is the amount of water that is before the amount of water in the intermediate tank 5 runs out and is larger than the amount that the first cooling water return pump 17p sucks up by one pump operation.

  As described above, the cooling water circulation drive controller 7 performs intermittent operation control of driving (ON) / stopping (OFF) of the first cooling water return pump motor 17m in accordance with the amount of water in the intermediate tank 5, and the first cooling water return pump. 17p is intermittently operated.

Next, the operation will be described.
The effects of the mold cooling apparatus of the first embodiment are as follows: “mold cooling action”, “intermittent operation control action”, “characteristic action of mold cooling apparatus”, “other characteristics of mold cooling apparatus” This will be described separately in “Operation”.

[Mold cooling action]
FIG. 2 is an overall system diagram of the mold cooling apparatus according to the first embodiment applied to a mold of an aluminum die cast product, and shows a flow of cooling water during mold cooling. Hereinafter, the mold cooling operation will be described with reference to FIG. In addition, the arrow in each water channel of FIG. 2 has shown the flow of the cooling water W, pressurized cooling water, and normal cooling water.

  First, in order to cool the mold 2, the cooling water W in the cooling water circulation tank that has been deoxygenated by the deoxygenation device 31 is driven by the operation (operation) of the circulation tank outlet pump 13 p. It is supplied to the first inlet side cooling water channel 14 and the second inlet side cooling water channel 15 through the cooling water channel 13. In addition, pure water is supplied from the pure water supply device 6 to the cooling water circulation tank 3 through the pure water supply water channel 19. The cooling water W supplied from the cooling water circulation tank 3 and the pure water supplied from the pure water supply device 6 are cold water.

  Next, the cooling water W supplied to the first inlet side cooling water channel 14 is pressurized by the pressurizing pump 411. The pressurized pressurized cooling water is pumped from the first inlet-side cooling water channel 14 to the first cooling water channel 11 by the pressurizing pump 411 and the air blowing device 412, and air is blown by the air blowing device 412. Is supplied from the first inlet-side cooling water channel 14 to the first cooling water channel 11. Moreover, the pressurized cooling water remaining in the 1st entrance side cooling water channel 14 is dried by performing air blow. Note that the pressurized cooling water supplied from the first inlet-side cooling water channel 14 is cold water.

  Further, the normal cooling water supplied to the second inlet-side cooling water passage 15 is second cooled from the second inlet-side cooling water passage 15 by driving (operation) of the circulation tank outlet-side pump 13p and the second cooling water return pump 18p. Supplied to the water channel 12. The normal cooling water supplied from the second inlet side cooling water channel 15 is cold water.

  Next, the mold 2 is cooled by the pressurized cooling water supplied to the first cooling water channel 11 and the normal cooling water supplied to the second cooling water channel 12. Then, when the molten metal (aluminum) filled in the mold is cooled by the cooled mold 2 and the molten metal (aluminum) is solidified, an aluminum die-cast product is taken out from the mold 2. For this reason, the pressurized cooling water supplied to the first cooling water channel 11 and the normal cooling water supplied to the second cooling water channel 12 take the heat of the molten metal transmitted from the mold 2 so that each cooling water is removed from the cold water. It is made hot water.

  Next, the pressurized cooling water supplied to the first cooling water channel 11 is discharged to the outlet side cooling water channel 16. This is because pressurized cooling water is discharged from the first cooling water channel 11 to the outlet cooling water channel 16 by the pressurized cooling water that is successively pumped from the first inlet cooling water channel 14 to the first cooling water channel 11. It is. The pressurized cooling water discharged from the first cooling water channel 11 is hot water.

  Next, the pressurized cooling water discharged to the outlet side cooling water channel 16 is discharged to the intermediate tank 5. The pressurized cooling water discharged to the intermediate tank 5 is stored in the intermediate tank 5 opened to the atmosphere until the amount of water in the intermediate tank 5 reaches the “operation start level”. Note that the pressurized cooling water discharged to the outlet side cooling water channel 16 is hot water.

  Subsequently, when the amount of water in the intermediate tank 5 reaches the “operation start level”, the operation of the first cooling water return pump 17 p is started, and the cooling water W stored in the intermediate tank 5 is the first cooling water return channel 17. Then, the intermediate tank 5 returns to the cooling water circulation tank 3. And the deoxidation of the cooling water W is performed by the deoxidation device 31 in the cooling water circulation tank. When the amount of water in the intermediate tank 5 reaches the “operation stop level”, the operation of the first cooling water return pump 17p is stopped. The cooling water W returned from the intermediate tank 5 to the cooling water circulation tank 3 is hot water.

  Further, the normal cooling water supplied to the second cooling water channel 12 is supplied from the second cooling water channel 12 to the cooling water circulation tank via the second cooling water return water channel 18 by driving (operation) of the second cooling water return pump 18p. Return to 3. Then, the deoxidation device 31 deoxidizes the normal cooling water in the cooling water circulation tank. The normal cooling water discharged from the second cooling water channel 12 is hot water.

  Thus, at the time of mold cooling, the cooling water W stored in the cooling water circulation tank 3 flows through the cooling water channels 11 to 18 by the pressurizing device body 4a and the pumps 13p, 17p, and 18p. Thereby, the metal mold | die 2 is cooled.

[Intermittent operation control action]
FIG. 3 is a time chart showing an example of intermittent operation of the first cooling water return pump motor according to the amount of water in the intermediate tank. Hereinafter, based on FIG. 3, the first cooling water return pump motor intermittent operation control action will be described.

  At time t0, since the amount of water in the intermediate tank has reached the “operation stop level” at which the operation of the first cooling water return pump 17p is stopped, the cooling water circulation drive controller 7 switches the first cooling water return pump motor 17m. The operation is stopped (ON), and the operation of the first cooling water return pump 17p is stopped. Thereby, the cooling water W stored in the intermediate tank 5 is not returned from the intermediate tank 5 to the cooling water circulation tank 3.

  Between the time t0 and the time t1, that is, the amount of water in the intermediate tank 5 starts the operation of the first cooling water return pump 17p from the “operation stop level” at which the operation of the first cooling water return pump 17p is stopped. Until the “operation start level” is reached, the coolant circulation drive controller 7 does not drive (ON) the first coolant return pump motor 17m. Thereby, the cooling water W stored in the intermediate tank 5 is not returned from the intermediate tank 5 to the cooling water circulation tank 3 during this period. For this reason, the amount of water in the intermediate tank 5 is increased by the pressurized cooling water discharged from the first cooling water channel 11.

  At time t1, the amount of water in the intermediate tank 5 reaches the “operation start level”. At this time, the cooling water circulation drive controller 7 drives (ON) the first cooling water return pump motor 17m to start the operation of the first cooling water return pump 17p. Thereby, the cooling water W stored in the intermediate tank 5 is returned from the intermediate tank 5 to the cooling water circulation tank 3 between the time t1 and the time t2. For this reason, the amount of water in the intermediate tank 5 decreases.

  At time t2, the amount of water in the intermediate tank 5 reaches the “operation stop level”. At this time, the cooling water circulation drive controller 7 stops (OFF) the first cooling water return pump motor 17m and stops the operation of the first cooling water return pump 17p. For this reason, the amount of water in the intermediate tank 5 is increased by the pressurized cooling water discharged from the first cooling water channel 11 from time t2.

  As described above, the cooling water circulation drive controller 7 performs intermittent operation control of driving (ON) / stopping (OFF) of the first cooling water return pump motor 17m in accordance with the amount of water in the intermediate tank 5, and the first cooling water return pump. 17p is intermittently operated. For this reason, the pressurized cooling water discharged from the first cooling water channel 11 is stored in an intermediate tank that is temporarily opened to the atmosphere. Thereby, air escapes from the cooling water W stored in the intermediate tank 5.

[Characteristic action of mold cooling system]
For example, a cooling device such as a die casting mold that supplies cooling water together with pressurized air supplied from a pressurized air supply source (pressurizing means) to the inside of the mold (cooling water channel) is used as a comparative example. In general, as the oxygen concentration of the cooling water is higher, rust is more likely to occur in the piping of the cooling water, and therefore, deoxidation is performed on the cooling water supplied to the cooling water channel by a deoxygenation device.

  However, according to the cooling device such as the die casting mold of the comparative example, the cooling water supplied to the cooling water channel has an oxygen concentration that is higher by the amount of air supplied by the pressurizing means. There is a problem that when the oxygen device is returned to the oxygen device, the deoxidation effect is reduced.

On the other hand, the pressurized cooling water pressurized by the pressurizing device body 41 is pumped to the first cooling water channel 11, and the air is supplied to the first cooling water channel 11 and discharged from the first cooling water channel 11. The pressurized cooling water is stored in the intermediate tank 5 opened to the atmosphere, and the cooling water W stored in the intermediate tank 5 through the first cooling water return water channel 17 by the first cooling water return pump 17p is supplied to the deoxygenator 31. The structure returned to the cooling water circulation tank 3 having was adopted (FIGS. 1 and 2).
That is, the pressurized cooling water supplied to the first cooling water channel 11 has an oxygen concentration that is higher by the amount of air supplied by the pressurizing device body 41. For this reason, the pressurized cooling water is stored in the intermediate tank 5 that is temporarily opened to the atmosphere before being returned to the cooling water circulation tank 3. As a result, air escapes from the cooling water W, so that the oxygen concentration that has increased is lowered.
As a result, it is possible to suppress the deoxygenation effect of the deoxygenation device 31 included in the cooling water circulation tank 3 from being reduced.

[Other characteristic actions of mold cooling device]
In the first embodiment, normal cooling water is supplied from the cooling water circulation tank 3 to the second cooling water path 12 via the second inlet cooling water path 15 by driving the circulation tank outlet pump 13p, and the second cooling water return pump. A configuration was adopted in which the normal cooling water discharged from the second cooling water passage 12 through the second cooling water return water passage 18 by driving 18p is returned to the cooling water circulation tank 3 (FIGS. 1 and 2).
That is, the normal cooling water supplied to the second cooling water channel 12 is not pressurized by the pressurizing device body 41. For this reason, the normal cooling water supplied to the second cooling water channel 12 does not have a high oxygen concentration unlike the pressurized cooling water supplied to the first cooling water channel 11.
Therefore, the normal cooling water can be supplied to the second cooling water channel 12 without affecting the deoxygenation effect of the deoxygenation device 31 included in the cooling water circulation tank 3.
In addition, the normal cooling water supplied to the second cooling water channel 12 can assist the cooling effect of the mold 2 by the pressurized cooling water supplied to the first cooling water channel 11.

In the first embodiment, when a predetermined amount of cooling water W (operation start level) is stored in the intermediate tank 5, the intermediate tank 5 is driven by the first cooling water return pump 17p by driving the first cooling water return pump 17p. The configuration in which the cooling water W stored in 5 is returned to the cooling water circulation tank 3 is employed (FIGS. 1 to 3).
That is, the cooling water W is stored in the intermediate tank 5 until a predetermined amount of the cooling water W is stored in the intermediate tank 5.
Therefore, air can be surely vented from the cooling water W stored in the intermediate tank 5 opened to the atmosphere.

In the first embodiment, the first cooling water return pump 17p is intermittently operated according to the amount of the cooling water W detected by the level sensor 51, and the cooling water W stored in the intermediate tank 5 is returned to the cooling water circulation tank 3. (Figs. 1 to 3).
That is, when the amount of the cooling water W detected by the level sensor 51 reaches the operation start level, the operation of the first cooling water return pump 17p is started, and the level sensor 51 operates during the operation of the first cooling water return pump 17p. When the detected amount of the cooling water W reaches the operation stop level, the operation of the first cooling water return pump 17p is stopped.
For this reason, the cooling water W is stored in the intermediate tank 5 until the amount of the cooling water W reaches the operation start level from the operation stop level. When the amount of the cooling water W reaches the operation stop level from the start of the operation of the first cooling water return pump 17p, the first cooling water return pump 17p is stopped by stopping the operation of the first cooling water return pump 17p. Inhalation of air together with the cooling water W is prevented.
Thereby, when the cooling water W stored in the intermediate tank 5 is returned to the cooling water circulation tank 3, the oxygen concentration of the cooling water W is not increased.
Accordingly, it is possible to further suppress the deoxygenation effect of the deoxygenation device 31 included in the cooling water circulation tank 3.

Next, the effect will be described.
In the mold cooling apparatus according to the first embodiment, the effects listed below can be obtained.

(1) a mold 2 having a first cooling water channel 11;
A cooling water circulation tank 3 having deoxidation means (deoxygenation device 31) for deoxidizing the cooling water W for cooling the mold 2, and storing the cooling water W;
A pressurizing means (pressurizing device 4) that communicates with the cooling water circulation tank 3 and feeds the pressurized cooling water (pressurized cooling water) to the first cooling water channel 11 and supplies air to the first cooling water channel 11; ,
While storing the cooling water (pressurized cooling water) discharged from the first cooling water channel 11, the intermediate tank 5 opened to the atmosphere,
First cooling water return means (first cooling water return water channel 17, first cooling water return pump 17p, first cooling water return pump motor 17m) for returning the cooling water W stored in the intermediate tank 5 to the cooling water circulation tank 3; ,
Is provided.
For this reason, it can suppress that the deoxidation effect of the deoxidation means (deoxygenation apparatus 31) which has in the cooling water circulation tank 3 becomes small.

(2) The mold 2 has a second cooling water channel 12,
A cooling water supply means (second inlet cooling water channel 15) that communicates with the cooling water circulation tank 3 and supplies cooling water (normal cooling water) to the second cooling water channel 12.
Second cooling water return means (second cooling water return water channel 18, second cooling water return pump 18p, second cooling water) for returning the cooling water (normal cooling water) discharged from the second cooling water channel 12 to the cooling water circulation tank 3 Return pump motor 18m).
For this reason, in addition to the effect of (1), the cooling water (normal cooling water) is supplied to the second cooling water channel 12 without affecting the deoxygenation effect of the deoxygenation means (deoxygenation device 31) provided in the cooling water circulation tank 3. Can be supplied to.

(3) The first cooling water return means (first cooling water return water channel 17, first cooling water return pump 17p, first cooling water return pump motor 17m) has a predetermined amount of cooling water W (operation start level). When stored in the intermediate tank 5, the cooling water W stored in the intermediate tank 5 is returned to the cooling water circulation tank 3.
For this reason, in addition to the effect of (1) or (2), air can be surely removed from the cooling water W stored in the intermediate tank 5 opened to the atmosphere.

(4) The first cooling water return means includes a first cooling water return water passage 17 communicating with the cooling water circulation tank 3 and a first cooling water return pump for returning the cooling water W stored in the intermediate tank 5 to the cooling water circulation tank 3. (First cooling water return pump 17p, first cooling water return pump motor 17m),
The intermediate tank 5 is provided with a level sensor 51 for detecting the amount of the cooling water W stored in the intermediate tank 5,
The first cooling water return pump (the first cooling water return pump 17p and the first cooling water return pump motor 17m) is intermittently operated according to the amount of the cooling water W detected by the level sensor 51 and stored in the intermediate tank 5. The cooled cooling water W is returned to the cooling water circulation tank 3.
For this reason, in addition to the effect of (3), it is possible to further suppress the deoxygenation effect of the deoxygenation means (deoxygenation device 31) provided in the cooling water circulation tank 3.

  As mentioned above, although the cooling device of the metal mold | die of this invention was demonstrated based on Example 1, it is not restricted to these Examples about a concrete structure, Invention which concerns on each claim of a claim Design changes and additions are permitted without departing from the gist of the present invention.

  In the first embodiment, an example in which the deoxygenation means included in the cooling water circulation tank 3 is the deoxygenation device 31 is shown. However, the deoxygenating means may be a drug or the like instead of the apparatus. In short, it is only necessary that the cooling water W for cooling the mold 2 can be deoxygenated.

  In the first embodiment, the example in which the cooling water W supplied to the first inlet-side cooling water channel 14 is pressurized by the pressurizing pump 411 is shown. However, the cooling water W may be pressurized by increasing the diameter of the water channel of the first inlet-side cooling water channel 14 or by inclining it. In short, the cooling water W may be pressurized by the pressurizing device 4.

  In the first embodiment, an example in which air is supplied from the first inlet-side cooling water channel 14 to the first cooling water channel 11 by performing air blowing with the air blowing device 412 when the mold is cooled has been described. However, when the mold 2 is not cooled, air blowing may be performed by the air blowing device 412. Thereby, cooling water channels, such as the 1st entrance side cooling water channel 14 and the 1st cooling water channel 11, can be dried. Thereby, it can be made hard to produce rust in a cooling water channel.

  In the first embodiment, the first cooling water return channel 17, the first cooling water return pump 17p, and the first cooling water return pump motor 17m are provided as the first cooling water return means. However, a valve may be provided instead of the first cooling water return pump 17p and the first cooling water return pump motor 17m. For example, when the position where the intermediate tank 5 is disposed is higher than the position where the cooling water circulation tank 3 is disposed, and when the first cooling water return water channel 17 is connected to the bottom of the intermediate tank 5, etc. Instead of the first cooling water return pump 17p and the first cooling water return pump motor 17m, a valve may be provided. At this time, the cooling water W stored in the intermediate tank 5 may be returned to the cooling water circulation tank 3 by controlling the valve.

  In Example 1, the example which provided the 2nd entrance side cooling water channel 15 as a cooling water supply means was shown. However, in addition to the second inlet side cooling water channel 15, a second inlet side pump and its pump motor may be provided in the water channel 15 as the cooling water supply means. For example, when the cooling water W cannot be supplied from the second inlet-side cooling water channel 15 to the second cooling water channel 12 due to the reason that the second inlet-side cooling water channel 15 is relatively long or the like, Two inlet pumps and their pump motors are provided. Thereby, the cooling water W can be supplied from the second inlet-side cooling water channel 15 to the second cooling water channel 12.

  In the first embodiment, the second cooling water return channel 18, the second cooling water return pump 18p, and the second cooling water return pump motor 18m are provided as the second cooling water return means. However, the second cooling water return pump 18p and the second cooling water return pump motor 18m may not be provided as the second cooling water return means. For example, when the position where the second cooling water channel 12 is arranged is higher than the position where the cooling water circulation tank 3 is arranged, the normal supply supplied to the second cooling water channel 12 without the pump 18p and the pump motor 18m is provided. When the cooling water is returned from the second cooling water passage 12 to the cooling water circulation tank 3, the pump 18p and the pump motor 18m may not be provided.

  In Example 1, the example which applies the cooling device 1 of the metal mold | die 2 to the metal mold | die of an aluminum die-casting product was shown. However, the cooling device 1 for the mold 2 according to the present invention is not limited to a mold for an aluminum die-cast product, but can be applied to other molds such as a mold for a cast material other than aluminum (metal, etc.) or a mold for a resin molded product. Can also be applied.

2 Mold 3 Cooling water circulation tank 31 Deoxygenation device (deoxygenation means)
4 Pressurizing device (pressurizing means)
41 Pressurizing device body 5 Intermediate tank 51 Level sensor 7 Cooling water circulation drive controller 11 First cooling water passage 12 Second cooling water passage 13 Circulating tank outlet cooling water passage 13p Circulating tank outlet pump 14 First inlet cooling water passage (pressurizing means )
15 Second inlet cooling water channel (cooling water supply means)
16 Outlet cooling water channel 17 First cooling water return channel (first cooling water return means)
17p 1st cooling water return pump (1st cooling water return means)
18 Second cooling water return channel (second cooling water return means)
18p Second cooling water return pump (second cooling water return means)
W Cooling water

Claims (4)

A mold having a first cooling water channel;
A deoxidizing means for deoxidizing cooling water for cooling the mold, and a cooling water circulation tank for storing the cooling water;
A pressurizing means that communicates with the cooling water circulation tank, pressurizes the pressurized cooling water to the first cooling water channel, and supplies air to the first cooling water channel;
Storing the cooling water discharged from the first cooling water channel, and an intermediate tank opened to the atmosphere;
First cooling water return means for returning the cooling water stored in the intermediate tank to the cooling water circulation tank;
A mold cooling apparatus comprising: The mold cooling device according to claim 1,
The mold has a second cooling water channel,
A cooling water supply means that communicates with the cooling water circulation tank and supplies cooling water to the second cooling water channel;
And a second cooling water return means for returning the cooling water discharged from the second cooling water channel to the cooling water circulation tank. In the mold cooling apparatus according to claim 1 or 2,
The first cooling water return means returns the cooling water stored in the intermediate tank to the cooling water circulation tank when a predetermined amount of cooling water is stored in the intermediate tank. apparatus. The mold cooling device according to claim 3,
The first cooling water return means has a first cooling water return water passage communicating with the cooling water circulation tank, and a first cooling water return pump for returning the cooling water stored in the intermediate tank to the cooling water circulation tank. And
The intermediate tank is provided with a level sensor that detects the amount of cooling water stored in the intermediate tank,
A mold for operating the first cooling water return pump intermittently according to the amount of cooling water detected by the level sensor, and returning the cooling water stored in the intermediate tank to the cooling water circulation tank. Cooling system.