JP3299394B2 - Electric equipment cooling device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to, for example, a VVVF inverter control device and an electric device cooling device used for a water-cooled electric device such as a water-cooled generator or a fuel cell.

[0002]

2. Description of the Related Art In general, water-cooled electric equipment has many objects to be cooled. A voltage is applied (energized) to at least a part of these cooling targets. When cooling this water-cooled electric equipment using cooling water, the cooling water pipe of the electric equipment cooling device is connected to the joint through an insulating pipe, and the cooling water supplied through the cooling water pipe is , Each cooling object is cooled. At this time, since there is a potential difference between the cooling object and the cooling water pipe, a current corresponding to the potential difference and the resistance of the cooling water in the insulating pipe flows between the joints. Due to this current, the joint portion on the high potential side, that is, the side to which the positive voltage is applied is corroded.

[0003] Here, for convenience of explanation, the electric device is treated as one cooling object, and the phenomenon of corrosion will be described.
For example, if a positive voltage is applied to the electric device, and e is an electron, a joint (anode) that comes into contact with cooling water
The following oxidation reaction occurs on the surface. _{2H 2 O → O 2 + 4H} + + 4e ··· ( Equation ^{1) Me → Me n + +} ne ··· ( Equation 2) where, Me: metal, n: a number of electrons, when the metal is Fe , Fe → Fe ²⁺ + 2e. Further, the following reduction reaction occurs on the surface of the other joint (cathode) in contact with the cooling water via the insulating tube. _{2H 2 O + 2e → H 2} + 2OH - ··· ( Equation _{3) O 2 + 2H 2 O} + 4e → 4OH - ··· ( Equation 4) In this case, the joint in the (anode) surface, (Equation 1) H ⁺ is generated by the reaction of the reaction water. If corrosive ions (for example, SO ₄ ²⁻ , Cl ⁻ ) are present in the cooling water, H ⁺ attracts the corrosive ions, and the water on the inner surface of the nozzle becomes acidic (H ₂ SO 4).
₄ , HCl) to accelerate the corrosion reaction of (Equation 2)
The anode joint corrodes.

[0004] When the cooling water is acidic and its PH value is low, the oxidation-reduction reactions represented by (Equation 2) and (Equation 5) occur on the metal surfaces constituting the heat exchangers and electric parts in the cooling water system. Occurs. ^{Me → Me n + + ne ···} ( Equation 2) where, in the case where the metal is Cu is, Cu → Cu ²⁺ + 2
e. 2H ⁺ + 2e → H ₂ (Equation 5) And, as the PH value becomes lower, the reaction rate of (Equation 5) is accelerated, so that the corrosion reaction of (Equation 2) progresses and not only the joint but also Heat exchangers and electrical components in the cooling water system also corrode.

Further, when there is dissolved oxygen in the cooling water,
In the heat exchanger and electric parts in the cooling water system, an oxidation reaction represented by (Equation 2) occurs, and on the cooling water piping side, (Equation 4)
The reduction reaction represented by And, as the amount of dissolved oxygen increases, the reaction rate of (Equation 4) is accelerated,
The corrosion reaction of (Equation 2) proceeds, and not only the joints but also the heat exchangers and electric components in the cooling water system are corroded.

[0006] As described above, the main factor of corrosion of the joint is current, and the pH of the cooling water and dissolved oxygen are also involved. The factors causing corrosion of the heat exchanger and the electric components in the cooling water system are the pH of the cooling water and dissolved oxygen.

For this reason, when cooling electric equipment using cooling water, the length of the insulating tube is increased, the purity of the cooling water is increased, and the current flowing through the cooling water is suppressed as small as possible. Corrosion protection has been made. In addition, a device for removing dissolved oxygen has been developed and put into practical use as a method for preventing corrosion of heat exchangers and electric components in a cooling water system.

FIG. 10 shows the overall configuration of a conventional electric equipment cooling device in which such anticorrosion measures are taken. In the figure, 1 is a circulation pump for cooling water W, 2 is a heat exchanger, 3
Is an ion exchange resin tower for maintaining the purity of the cooling water W at a high purity (low electric conductivity) at all times. In the ion-exchange resin tower 3 for maintaining purity, a cation-exchange resin (R-H) and an anion-exchange resin (R) that capture cations and anions in the cooling water W and release H ⁺ and OH ⁻
-OH). Here, R represents a benzene ring. Reference numeral 4 denotes a cooling water pipe formed in an annular shape so as to include the circulation pump 1 and the heat exchanger 2. Reference numeral 5 denotes an ion exchange resin tower 3 for maintaining purity. This is a water treatment pipe for cooling water W connected by Q.

Reference numeral 6 denotes a flow control valve provided on the upstream side of the ion-exchange resin tower 3 for maintaining purity in the water treatment pipe 5, and reference numeral 7 denotes a cooling object provided on the downstream side of the heat exchanger 2 in the cooling water pipe 4. The electrical equipment 8 is an insulating pipe connected between the joint 9 and the joint 9 at the end of the cooling water pipe 4, and 10 is the cooling water pipe 4
Is a storage tank for the cooling water W that communicates with the communication point Q through the pipe 11. The joint portion 9 and the insulating pipe 8 are illustrated in an enlarged manner, and have substantially the same diameter as the cooling water pipe 4 in practice.

FIG. 11 shows details around the joint 9 connected to the insulating tube 8. The joint portions 9 are attached to both ends of the cooling water pipe 4, and small-diameter portions 9 a at the ends are inserted into the insulating pipe 8. The end 8a of the flanged insulating tube 8 and the joint 9 are pressurized and connected by a cap nut 12 screwed to the outer periphery of the joint 9. The joint 9 is made of, for example, stainless steel.

Next, the operation of the conventional electric equipment cooling device will be described. When the circulation pump 1 is operated, a part of the cooling water W is sent to the cooling water pipe 4 and supplied to the heat exchanger 2, and the rest of the cooling water W is sent to the water treatment pipe 5 to maintain the purity. Is supplied to the ion-exchange resin tower 3. In this case, the flow ratio between the flow rate on the cooling water pipe 4 side and the flow rate on the water treatment pipe 5 side is determined by the opening of the flow control valve 6.
After passing through the heat exchanger 2, the cooling water W thus cooled is supplied into the electric device 7, cools the electric device 7, and is returned to the circulation pump 1 again.

The cooling water W from which ions have been removed through the ion-exchange resin through the ion-exchange resin tower 3 for maintaining purity.
Is combined with the cooling water on the cooling water pipe 4 side, and then returned to the circulation pump 1 again. Therefore, even if ions are generated in the cooling water W due to corrosion or the like, the ions are always removed by the ion-exchange resin in the ion-exchange resin tower 3 for maintaining purity. Is maintained. Since the storage tank 10 communicates with the cooling water pipe 4 and the water treatment pipe 5 via the pipe 11, the storage tank 10 is connected to the inside of the electric equipment cooling device.
Is always filled with cooling water W except for the upper part.

Here, when a voltage is applied to the electric equipment 7, the cooling water W in the insulating pipe 8 is interposed between the electric equipment 7 and the cooling water pipe 4, and between the joint 9. Electric current flows. However, the quality of the cooling water W is maintained at a high level of purity, and the length of the insulating tube 8 is increased, so that the resistance of the cooling water W is increased. As a result, the current flowing between the joints 9 is small. Therefore, in such an electric equipment cooling device, corrosion hardly occurs at the joint portions 9 (on the anode side) on both sides of the insulating tube 8.

[0014]

However, in recent years,
In such an electric equipment cooling device, the length of the insulating tube 8 tends to be shortened as the water-cooled electric equipment becomes smaller and more sophisticated. For this reason, in the recent electric device cooling device, a sufficient current flows between the joint portions 9 via the cooling water W, and a corrosion reaction in the anode portion is promoted, and corrosion occurs in the joint portion 9. There was a problem of getting it. In addition, with the downsizing of electric devices, a simple method of preventing corrosion of heat exchangers and electric components in a cooling water system is required.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and can sufficiently suppress the corrosion of a joint portion even if the insulating tube is shortened. It is an object of the present invention to provide an electric equipment cooling device capable of easily preventing corrosion of a container and electric components.

[0016]

According to a first aspect of the present invention, a cooling water is passed through an electric device to which a voltage is applied.
Performs the cooling of this electrical equipment, attach the insulating tube between the joint portion of the cooling water pipe of the electrical device, be those insulation have been made for the cooling water pipe of the electrical device
Then, by passing the cooling water, the ion exchange resin tower for maintaining the purity of the cooling water at a high purity by the ion conversion resin at all times, and the cooling water system in a state where the water quality of the cooling water is maintained at the high purity. In an electric equipment cooling device provided with a corrosion prevention means for reducing a corrosion factor in each part,
The means is disposed near the insulating pipe in the cooling water pipe.
And a second joint portion on both sides of the cooling water pipe, and
The electric field strength between the second joints is between the joints on both sides of the insulating tube.
With an ion collecting tube maintained larger than the electric field strength of
It has been done .

[0017]

Further, the second aspect of the invention, corrosion prevention means, by passing cooling water, a PH adjusting to maintain the PH value of the cooling water always neutral or weakly alkaline by ion exchange resin Ri ion exchange resin column der, PH
Ion exchange resin tower for adjustment is ion exchange resin tower for purity maintenance
And are arranged in parallel .

Further, a third aspect of the invention, corrosion prevention means, by passing cooling water, slightly soluble base to maintain the PH value of the cooling water always neutral or weakly alkaline by poorly soluble bases Todea is, purity maintained poorly soluble basic tower
Are arranged in parallel with the ion-exchange resin tower .

[0020] The fourth invention of the present invention, corrosion prevention means, and carbon dioxide absorber for absorbing carbon dioxide of the upper air layers of the storage over tank connected to the cooling water pipe, the storage And a breathe valve for preventing unnecessary inflow of air into the g-tank.

[0021]

[0022]

According to a fifth aspect of the present invention, the corrosion preventing means is a local water flow forming means provided near a connecting portion between the joint and the insulating pipe which comes into contact with the cooling water.

A sixth aspect of the present invention is that the corrosion preventing means is a spiral groove formed on the inner surface side of the joint portion which comes into contact with the cooling water.

[0025]

SUMMARY OF] According to this inventions, the cooling water passes through a purity maintain ion exchange resin column, the water quality of high purity (low electrical conductivity)
Is maintained. As a result, even if a potential difference occurs between the joints of the cooling water pipe, the resistance of the cooling water in the insulating pipe is large,
The current flowing between the joints due to the potential difference is suppressed,
Corrosion protection of the joint is achieved. Even in this case, when the length of the insulating tube, that is, the distance between the joints is shortened, the resistance of the cooling water is correspondingly reduced, and the current easily flows between the joints. Corrosion factors such as the concentration of corrosive ions remaining in the cooling water very slightly, the acidification of the cooling water, or the dissolved oxygen in the cooling water tend to cause corrosion at the joint. For this reason, in the first aspect of the present invention, corrosion prevention means is further provided to reduce the corrosion factor due to the cooling water around the joint in a state where the quality of the cooling water is maintained at high purity. We try to prevent corrosion. Further, by setting the water quality as described above, the heat exchanger and the electric components in the cooling water system can also be protected from corrosion.

According to the first aspect of the present invention, the electric field strength between the second joints on both sides of the insulating tube of the ion collector tube is larger than the electric field strength between the joints on both sides of the insulating tube. , Corrosive ions in the cooling water that are corrosion factors (eg, S
O ₄ ²⁻ and Cl ⁻ ) are collected and concentrated around the second joint on the anode side of the ion collecting tube. For this reason, corrosive ions in the cooling water are reduced as a whole, the amount of corrosive ions concentrated around the joint is reduced, and the corrosion of the joint is further improved. Further, by setting the water quality as described above, the heat exchanger and the electric components in the cooling water system can also be protected from corrosion.

According to the second aspect of the present invention, the cooling water passes through the ion-exchange resin tower for adjusting pH, and the cooling water is maintained at neutral or weakly alkaline. Therefore, the acidification of the cooling water, which is a corrosion factor, is prevented, and the joints, the heat exchanger in the cooling water system, and the electrical components are further prevented from being corroded.

According to the third aspect of the present invention, the cooling water passes through the hardly soluble base tower, the base is slightly dissolved in the cooling water, and the cooling water is maintained at neutral or weakly alkaline. Therefore, the acidification of the cooling water, which is a corrosion factor, is prevented, and the joints, the heat exchanger in the cooling water system, and the electrical components are further prevented from being corroded.

Further, according to the fourth aspect of the present invention, the carbon dioxide in the air layer of the storage tank is absorbed by the carbon dioxide absorbing device, and the carbon dioxide dissolves in the cooling water to acidify the cooling water. Is prevented. In addition, since a breathe valve is provided to suppress unnecessary inflow of air into the storage tank, the concentration of carbon dioxide in the air layer of the storage tank can be kept low.

[0030]

[0031]

According to the fifth aspect of the present invention, the water flow forming means forms a local water flow around the joint between the joint and the insulating pipe, and eliminates the stagnation of the cooling water around the joint. ing. Thus, the concentration of corrosive ions around the connection is prevented.

According to the sixth aspect of the present invention, the helical groove formed on the inner surface of the joint causes the cooling water flowing in the joint to be in a turbulent state. Therefore, concentration of corrosive ions in the joint portion is prevented.

[0034]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. Embodiment 1 FIG. FIG. 1 is a diagram showing the overall configuration of an electric equipment cooling apparatus according to Embodiment 1 of the present invention, and FIG. 2 is a cross-sectional view showing the vicinity of an ion collecting pipe. The same or corresponding portions as those of the electric device cooling device and the like shown in FIGS. 10 and 11 are denoted by the same reference numerals, and description thereof will be omitted.

In the drawing, reference numeral 20 denotes an ion collecting pipe as a corrosion preventing means provided in the cooling water pipe 4 near the insulating pipe 8. The ion collector pipe 20 includes an insulating tube portion 20a having a flange portion 20a ₁ at both end portions, the insulating pipe part 2
0a connected to cooling water pipes 4 and 4A (for convenience of explanation,
The cooling water pipe 4 between the insulating pipe 8 and the ion collecting pipe 20 is indicated by reference numeral 4A), and is used to connect the joint 20b as a second joint, and the joint 20b and the insulating pipe 20a. And the cap nut 20c. The electric field strength (for example, 2 KV / cm) between the pair of joints 20 b of the ion collecting tube 20 is larger than the electric field strength (for example, 1 KV / cm) between the joints 9 on both sides of the insulating tube 8. A constant voltage is applied to the joint 20b of the ion collecting pipe 20 on the side of the cooling water pipe 4A.

Next, the operation of the ion collecting tube 20 will be described. The cooling water W always passes through the ion exchange resin tower 3 for maintaining purity, thereby removing cations and anions dissolved therein and maintaining the water quality at high purity. SO ₄ ^2- , C
l ^-) may also be present. In this case, the insulating tube 8 is relatively short,
When the electric resistance of the cooling water W in the insulating pipe 8 is relatively small,
Since a current flows between the joints 9 on both sides of the insulating tube 8, the corrosive ions collect around the joint 9 on the anode side among the joints 9 on both sides of the insulating tube 8.

However, the joint 20 of the ion collecting pipe 20
Since the electric field intensity between b and b is greater than the electric field intensity between the joints 9 on both sides of the insulating tube 8, a large amount of corrosive ions in the cooling water W are collected on the anode side of the joint 20 b of the ion collecting tube 20. The corrosive ions collected in the joint 20b on the anode side are maintained there while voltage is applied between the joints 20b, and the purity of the flowing cooling water increases. Therefore, the concentration of corrosive ions in the cooling water W decreases, and in this electric equipment cooling device, even when the length of the insulating pipe 8 is relatively short, the concentration of corrosive ions around the joint 9 is reduced. Reduction is achieved, and corrosion of the joint 9 can be prevented.

In this case, the joint 20 of the ion collecting pipe 20
Since b may be corroded by corrosive ions, its material is a corrosion-resistant material (for example, Pt, Ti, Ir)
O ₂ , TiN, ITO (Indium Tin Oxi)
de)) or those obtained by coating a conductive ceramic such as SnO ₂ on a metal or an insulator.

The ion collecting tube 20 is connected to the electric device 7.
It is not necessary to provide for all the insulating tubes 8 connected to the joint portions 9 (only two are shown in FIG. 1, but there are actually many). Just do it. Therefore, there is no need to manufacture a large number of joint portions 9 using expensive corrosion-resistant or anti-corrosion materials, and it is possible to suppress an increase in the cost of the apparatus.

The joint 20b of the ion collecting tube 20 may be made porous. In this case, the joint 20b
The contact area between the water and the cooling water W is increased, the effect of concentrating corrosive ions is increased, and corrosion of the joint 9 can be further prevented.

Embodiment 2 FIG. FIG. 3 is a diagram illustrating an overall configuration of an electric equipment cooling device according to a second embodiment of the present invention.

In the drawing, reference numeral 21 denotes a pH-adjusting ion-exchange resin tower as corrosion prevention means provided in the water treatment pipe 5 in parallel with the purity-maintaining ion-exchange resin tower 3. A cation exchange resin (R-Na or RC) having Na or Ca as an exchange group is provided in the ion exchange resin tower 21 for pH adjustment.
a) and an anion exchange resin (RO) having OH as an exchange group.
H) is filled. Reference numeral 22 denotes a flow control valve for setting a flow ratio between the flow rate of the cooling water W passing through the ion exchange resin tower 3 for maintaining purity and the flow rate of the cooling water W passing through the ion exchange resin tower 21 for adjusting pH. It has the same function as the valve 6. Except for the ion collecting tube 20, other configurations are the same as those of the electric device cooling device according to the first embodiment.

In the second embodiment, even when the cooling water W is acidic due to the dissolution of carbon dioxide gas in the air into the cooling water W, the cooling water W is supplied to the pH-adjusting ion-exchange resin tower 21.
When passed through a inner, cations of the ions in the cooling water W is substituted in the Na ⁺ or Ca ^+, are collected in the cation exchange resin, the anion OH ^- is replaced, collecting the anion exchange resin Is done. Then, NaOH or Ca (OH) ₂ is generated in the cooling water W, and the PH value in the cooling water W increases. In this case, the opening degree of the flow control valve 22 is adjusted, and the cooling water W is maintained at neutral or slightly alkaline. Therefore, in this electric equipment cooling device, even when the length of the insulating pipe 8 is relatively short, the acidification of the cooling water W due to the dissolution of carbon dioxide gas or the like is prevented, and the joint 9 and the heat exchanger in the cooling water system are prevented. 2. Corrosion of electric parts can be prevented.

The NaOH or Ca (OH) ₂ generated in the pH-adjusting ion exchange resin tower 21 is used for cooling water W
At the same time, it is removed by passing through the ion exchange resin tower 3 for maintaining purity, and the purity of the cooling water increases.

Embodiment 3 FIG. FIG. 4 is a diagram showing an overall configuration of an electric equipment cooling device according to Embodiment 3 of the present invention.

In the figure, reference numeral 23 denotes a hardly soluble base tower as a corrosion preventing means provided in the water treatment pipe 5 in parallel with the ion exchange resin tower 3 for maintaining purity. This hardly soluble base tower 2
3 is filled with limestone or soda lime which is a hardly soluble base having a predetermined shape. Reference numeral 24 denotes a flow control valve for setting a flow ratio between the flow rate of the cooling water W passing through the ion exchange resin tower 3 for maintaining purity and the flow rate of the cooling water W passing through the poorly soluble base tower 23. They have the same function. Except for the ion collecting tube 20, other configurations are the same as those of the electric device cooling device according to the first embodiment.

In the third embodiment, when the cooling water W is passed through the hardly soluble base tower 23, the limestone or soda lime in the hardly soluble base tower 23 slightly dissolves in the cooling water W, PH rises. Then, also dissolved carbonic acid gas to the cooling water W, OH generated by dissolution of limestone and soda lime ^- are neutralized by. Thus, acidification of the cooling water W due to dissolution of carbon dioxide gas is prevented. In this case, the opening of the flow control valve 24 is adjusted, and the cooling water W is maintained at neutral or weakly alkaline. Therefore, in this electric equipment cooling device, even when the length of the insulating tube 8 is relatively short, the joint 9, the heat exchanger 2 of the cooling water system, and the corrosion of the electric parts are prevented by preventing the cooling water W from being acidified. Prevention can be achieved. Limestone and soda lime slightly dissolved in the cooling water W are removed by passing through the ion exchange resin tower 3 for maintaining purity.

Embodiment 4 FIG. FIG. 5 is a diagram showing an overall configuration of an electric equipment cooling device according to Embodiment 4 of the present invention.

In the figure, 25 is the storage tank 10
Is a carbon dioxide gas absorbing device that communicates with the air layer 10a on the upper side. The carbon dioxide gas absorbing device 25 is filled with a carbon dioxide gas absorbent (for example, soda lime, NaOH or BaOH). Reference numeral 26 denotes a breathe valve that opens when a pressure difference occurs between the storage tank 10 and the outside air. This breathe valve 26 is mounted in the atmosphere side pipe of the carbon dioxide absorption device 25. In this case, the carbon dioxide absorption device 2
5 and the breeze valve 26 constitute a corrosion prevention means. Except for the ion collecting tube 20, other configurations are the same as those of the first embodiment.
Is the same as the electric equipment cooling device.

In the fourth embodiment, the carbon dioxide absorbing device 25
Since the carbon dioxide gas absorbent communicates with the air layer 10a of the storage tank 10, the carbon dioxide gas in the air layer 10a is absorbed, and the outside air taken into the storage tank 10 always passes through the inside. Therefore, carbon dioxide in the outside air is also absorbed. In this case, since outside air is taken into the storage tank 10 only when necessary through the breathe valve 26, the storage tank 10
The concentration of carbon dioxide in the air layer 10a is kept low at all times.

For this reason, in this electric equipment cooling device, the carbon dioxide gas is prevented from being dissolved into the cooling water W in the storage tank 10 via the air layer 10a of the storage tank 10, and the cooling water W is acidified. Is prevented. Therefore, in this electric equipment cooling device, even if the length of the insulating tube 8 is relatively short, the joint portion 9 and the cooling water heat exchanger 2, Corrosion of electric components can be prevented.

Reference Example 1 FIG. 6 is a diagram showing the overall configuration of the electric equipment cooling device according to Embodiment 1 of the present invention.

In the figure, 27 is the storage tank 10
Is a heating deaerator as a corrosion prevention means provided on one side of the apparatus. The heating and degassing device 27 is provided in the storage tank 1
0, a U-shaped pipe 27a provided to communicate with the storage tank 10, and this pipe 27a
And a stop valve 27c provided on the pipe 27a. Except for the ion collecting tube 20, other configurations are the same as those of the electric device cooling device according to the first embodiment.

In the first embodiment , the stop valve 27c is opened,
By heating the pipe 27a with the heater 27b, the cooling water W in the pipe 27a is heated and
Convection while circulating between the inside and the storage tank 10.
Then, the temperature of the cooling water W increases, and the dissolved oxygen is released to the outside. Therefore, in this electric equipment cooling device, by reducing the amount of dissolved oxygen in the cooling water W, even when the length of the insulating pipe 8 is relatively short, the joint portion 9, the heat exchanger 2 of the cooling water system, It is possible to prevent corrosion of parts.

Reference Example 2 FIG. 7 is a diagram showing an overall configuration of an electric equipment cooling device according to Embodiment 2 of the present invention.

In the figure, reference numeral 28 denotes an oxygen scavenger as a corrosion preventing means provided in the water treatment pipe 5 between the ion-exchange resin tower 3 for maintaining purity and the flow control valve 6. The oxygen trapping device 28 is filled with a base metal (for example, Al, Mg, Zn) that is easily oxidized and has a predetermined shape. Except for the ion collecting tube 20, other configurations are the same as those of the electric equipment cooling device according to the first embodiment.

Generally, Cu having good heat conductivity is used for heat exchangers and electric parts to be cooled by water-cooled electric equipment, Fe is used for piping and the like, and Cu ²⁺ , F
e ²⁺ is generated. These heavy metal ions are present in the cooling water to increase the conductivity, and act to increase the value of the current flowing between the joints 9. In Reference Example 2 , the dissolved oxygen and heavy metals (for example, Fe ²⁺ , Cu ²⁺ ) in the cooling water W are passed through the cooling water W through the oxygen Be captured. Therefore, in this electric equipment cooling device, by reducing the amount of dissolved oxygen in the cooling water W, even when the length of the insulating pipe 8 is relatively short, the joint 9, the cooling water heat exchanger 2, It is possible to prevent corrosion of parts. Further, in this electric equipment cooling device, by also reducing the heavy metal dissolved in the cooling water W, it is possible to suppress an increase in the current value flowing between the joints 9 on both sides of the insulating pipe 8.
Corrosion of the joint 9 can be prevented.

Embodiment 5 FIG. FIG. 8 is an enlarged sectional view showing the vicinity of a joint of an electric equipment cooling device according to Embodiment 5 of the present invention.

In the figure, reference numeral 29 denotes a ring as a corrosion prevention means which protrudes from the small-diameter portion 9a of the joint portion 9 on the side where the cooling water W flows to the insulating tube 8 toward the insulating tube 8 and whose tip is rounded in an arc shape. Projections (local water flow forming means). A fixed gap 29a is formed between the outer peripheral surface of the ring-shaped projection 29 and the inner surface of the insulating tube 8. The ion collecting tube 20
Except for the above, other configurations are the same as those of the electric equipment cooling device according to the first embodiment.

When the shape of the small diameter portion 9a of the joint portion 9 is such that it forms a step with the insulating tube 8 as shown in FIG. 11, it flows into the insulating tube 8 from the joint portion 9 side. The cooling water W stagnates at this step and concentrates corrosive ions at this step. In the fifth embodiment , the joint 9
By providing the ring-shaped protrusion 29 on the small diameter portion 9a of
The cooling water W wraps around the gap 29a outside the ring-shaped projection 29 and generates a turbulent flow, so that there is no stagnation of the cooling water W between the insulating pipe 8 and the joint portion 9. Further, the arc-shaped tip of the ring-shaped projection 29 reduces the electric field.

Therefore, in this electric equipment cooling device,
The prevention of the concentration of corrosive ions caused by the stagnation of the flow of the cooling water W and the relaxation of the electric field at the arc-shaped tip of the ring-shaped projection 29 allow the joint 9 even when the length of the insulating tube 8 is relatively short. Corrosion can be prevented.

Embodiment 6 FIG. FIG. 9 is an enlarged cross-sectional view showing the vicinity of a joint portion of an electric equipment cooling device according to Embodiment 6 of the present invention.

In the figure, reference numeral 30 denotes a spiral groove as a corrosion preventing means which is spirally formed on the inner surface of the joint portion 9. Except for the ion collecting tube 20, other configurations are the same as those of the electric equipment cooling device according to the first embodiment.

In the sixth embodiment , the turbulent state of the cooling water W flowing in the joint 9 is amplified by the spiral groove 30 formed on the inner surface of the joint 9, and the cooling water W On the inner surface side or at the joint between the joint 9 and the insulating tube 8,
Concentration of corrosive ions is prevented. Therefore, in this electric device cooling device, corrosion of the joint 9 is prevented by preventing corrosive ions from concentrating around the joint 9 even when the length of the insulating tube 8 is relatively short. be able to.

[0065]

Since the present invention is configured as described above, it has the following effects.

According to the first aspect of the present invention, the cooling water is passed through the ion exchange resin tower for maintaining the quality of the cooling water at a high purity by the ion conversion resin, and the water quality of the cooling water is maintained. While maintaining high purity, it is equipped with corrosion prevention means for reducing the corrosion factor of each part of the cooling water system, so that the corrosion prevention means concentrates corrosive ions around the joint, acidifies the cooling water, Corrosion factors such as dissolved oxygen in cooling water can be reduced, and joints can be sufficiently prevented from corroding even if insulation tubes are shortened due to miniaturization and high performance of water-cooled electric equipment. And a cooling device for electric equipment which can also prevent corrosion of electric components. And the corrosion prevention means is the insulation in the cooling water piping.
Around the cooling water pipe,
A joint part, and the electric field strength between the second joint parts is
Maintained greater than the electric field strength between the joints on both sides of the edge tube
Ion collection tube
Corrosive ions in the cooling water are collected around the joint and the joint
Concentration of corrosive ions around is prevented,
Corrosion can be further prevented.

[0067]

Further, according to the second aspect of the present invention, the corrosion prevention means allows the cooling water to pass through, so that the PH value of the cooling water is always neutral or slightly alkaline by the ion exchange resin. It consists of a PH adjusting ion exchange resin column to maintain a, PH adjusting ion exchange resin column is ion for purity maintained
Since it is arranged in parallel with the exchange resin tower , acidification of the cooling water is prevented, and corrosion of the joint portion, the heat exchanger in the cooling water system, and electric components can be further prevented.

Further, according to the third aspect of the present invention, the corrosion prevention means allows the cooling water to pass through, so that the PH value of the cooling water is always neutral or slightly alkaline by the hardly soluble base. Consists of a hardly soluble base tower
Is arranged in parallel with the ion exchange resin tower for maintaining purity , acidification of the cooling water is prevented, and corrosion of the joint portion, the heat exchanger in the cooling water system, and electrical components can be further prevented.

According to the fourth aspect of the present invention, the anticorrosion means is provided for absorbing carbon dioxide in the upper air layer in the storage tank communicating with the cooling water pipe. Since it is configured to have an absorption device and a breathe valve that prevents unnecessary inflow of air into the storage tank, acidification of the cooling water due to dissolution of carbon dioxide gas into the cooling water is prevented, The joint portion, the heat exchanger in the cooling water system, and the corrosion of electric components can be further prevented.

[0071]

[0072]

Further, according to the fifth aspect of the present invention, the corrosion preventing means is constituted by a local water flow forming means provided in the vicinity of the joint between the joint part which comes into contact with the cooling water and the insulating pipe. Therefore, local turbulence is generated around the joint to prevent the corrosive ions from being concentrated around the joint, thereby further preventing corrosion of the joint.

Further, according to the sixth aspect of the present invention, since the corrosion preventing means is constituted by the spiral groove formed on the inner surface side of the joint portion which comes into contact with the cooling water, the cooling means flowing through the joint portion is provided. By increasing the turbulent state of water, the concentration of corrosive ions around the joint is prevented, and the corrosion of the joint can be further prevented.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating an overall configuration of an electric equipment cooling device according to a first embodiment of the present invention.

FIG. 2 is a cross-sectional view illustrating the vicinity of an ion collecting pipe of the electric device cooling device according to the first embodiment of the present invention.

FIG. 3 is a diagram illustrating an overall configuration of an electric equipment cooling device according to a second embodiment of the present invention.

FIG. 4 is a diagram illustrating an overall configuration of an electric equipment cooling device according to a third embodiment of the present invention.

FIG. 5 is a diagram illustrating an overall configuration of an electric equipment cooling device according to a fourth embodiment of the present invention.

FIG. 6 is a diagram showing an overall configuration of an electric equipment cooling device according to Embodiment 1 of the present invention.

FIG. 7 is a diagram showing an overall configuration of an electric equipment cooling device according to Embodiment 2 of the present invention.

FIG. 8 is an enlarged sectional view showing the vicinity of a joint of an electric equipment cooling apparatus according to Embodiment 5 of the present invention.

FIG. 9 is an enlarged sectional view showing the vicinity of a joint of an electric equipment cooling device according to Embodiment 6 of the present invention.

FIG. 10 is a diagram showing an overall configuration of a conventional electric device cooling device.

FIG. 11 is a cross-sectional view showing the vicinity of a joint portion of a conventional electric device cooling device.

[Explanation of symbols]

3 Ion exchange resin tower for maintaining purity, 4 cooling water piping, 7
Electrical equipment, 8 Insulation pipe, 9 Joint, 10 Storage tank, 10a Air layer, 20 Ion collecting pipe, 20
a Insulating tube part, 20b Joint part (second joint part), 21
Ion exchange resin tower for pH adjustment (corrosion prevention means), 23
Poorly soluble basic column (corrosion preventing means), 25 carbon dioxide absorber (corrosion preventing means), 26 Breeze valve (corrosion prevention means), 2 9 ring projection (local water flow forming means, corrosion prevention means) 30 spiral Grooves (corrosion prevention means).

──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Tadao Nishimori 8-1-1, Tsukaguchi-Honmachi, Amagasaki-shi Mitsubishi Materials and Materials Co., Ltd. (72) Inventor Shiro Yamauchi 8-1-1, Tsukaguchi-Honmachi, Amagasaki-shi Mitsubishi Electric Corporation Itami Works (72) Inventor Nobuyoshi Takahashi 8-1-1 Tsukaguchi Honcho, Amagasaki City Mitsubishi Electric Corporation Itami Works (72) Inventor Tomonori Hirayama 1-1-1 Wadazakicho, Hyogo-ku, Kobe-shi No.2 Mitsubishi Electric Corporation Kobe Works (56) References JP-A-59-18666 (JP, A) JP-A-4-36561 (JP, A) JP-A-55-76997 (JP, A) JP-A-6-101419 (JP, A) JP-A-6-66975 (JP, A) JP-A-2-121107 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) H05K 7 / 20 C23F 15/00 F25D 1/02

Claims (6)

(57) [Claims] A cooling water is passed through an electric device to which a voltage is applied to cool the electric device, and an insulating pipe is attached between joints of a cooling water pipe of the electric device,
An ion exchange resin tower for maintaining the water quality of the cooling water at a high purity by means of an ion conversion resin by passing the cooling water through the insulation of the cooling water pipe of the electric equipment. An electrical equipment cooling device comprising: a corrosion prevention unit configured to reduce a corrosion factor of each part of a cooling water system while maintaining the quality of the cooling water at high purity. Of the cooling water pipe is disposed near the insulating pipe.
An electric equipment cooling device having a joint portion, wherein the electric field strength between the second joint portions is maintained to be greater than the electric field strength between the joint portions on both sides of the insulating tube. apparatus. 2. Cooling the electric equipment by passing cooling water through the electric equipment to which a voltage is applied, and attaching an insulating pipe between joints of a cooling water pipe of the electric equipment,
An ion exchange resin tower for maintaining the water quality of the cooling water at a high purity by means of an ion conversion resin by passing the cooling water through the insulation of the cooling water pipe of the electric equipment. An electrical equipment cooling device comprising: a corrosion prevention unit that reduces a corrosion factor of each part of a cooling water system while maintaining a high quality of the cooling water, wherein the corrosion prevention unit passes the cooling water. This is a pH-adjusting ion-exchange resin tower for constantly maintaining the PH value of the cooling water at neutral or weakly alkaline with an ion-exchange resin, wherein the pH-adjusting ion-exchange resin tower is the purity-maintaining ion-exchange resin tower. An electric equipment cooling device, which is arranged in parallel with the electric equipment. 3. Cooling the electric equipment by passing cooling water through the electric equipment to which a voltage is applied, attaching an insulating pipe between joints of cooling water piping of the electric equipment,
An ion exchange resin tower for maintaining the water quality of the cooling water at a high purity by means of an ion conversion resin by passing the cooling water through the insulation of the cooling water pipe of the electric equipment. An electrical equipment cooling device comprising: a corrosion prevention unit that reduces a corrosion factor of each part of a cooling water system while maintaining a high quality of the cooling water, wherein the corrosion prevention unit passes the cooling water. Thereby, the cooling water PH value is a poorly soluble base tower that constantly maintains neutral or weakly alkaline with a poorly soluble base, and the poorly soluble base tower is disposed in parallel with the ion exchange resin tower for maintaining purity. An electric equipment cooling device, comprising: 4. Cooling the electric equipment by passing cooling water through the electric equipment to which a voltage is applied, and attaching an insulating pipe between joints of a cooling water pipe of the electric equipment,
An ion exchange resin tower for maintaining the water quality of the cooling water at a high purity by means of an ion conversion resin by passing the cooling water through the insulation of the cooling water pipe of the electric equipment. And an electrical equipment cooling device comprising: a corrosion prevention unit that reduces a corrosion factor of each part of the cooling water system while maintaining the quality of the cooling water at high purity. The storage tank is configured to include a carbon dioxide gas absorbing device that absorbs carbon dioxide in the upper air layer in the storage tank and a breathe valve that prevents unnecessary inflow of air into the storage tank. An electric equipment cooling device, comprising: 5. Cooling the electric equipment by passing cooling water through the electric equipment to which a voltage is applied, attaching an insulating pipe between joints of cooling water pipes of the electric equipment,
An ion exchange resin tower for maintaining the water quality of the cooling water at a high purity by means of an ion conversion resin by passing the cooling water through the insulation of the cooling water pipe of the electric equipment. And an anti-corrosion means for reducing corrosion factors of each part of the cooling water system while maintaining the quality of the cooling water at high purity, wherein the corrosion preventing means contacts the cooling water. A cooling device provided in the vicinity of a connecting portion between the joint portion and the insulating pipe. 6. Cooling the electric equipment by passing cooling water through the electric equipment to which a voltage is applied, attaching an insulating pipe between joints of cooling water pipes of the electric equipment,
An ion exchange resin tower for maintaining the water quality of the cooling water at a high purity by means of an ion conversion resin by passing the cooling water through the insulation of the cooling water pipe of the electric equipment. And an electrical equipment cooling device comprising: corrosion prevention means for reducing a corrosion factor of each part of the cooling water system while maintaining the quality of the cooling water at high purity; wherein the corrosion prevention means contacts the cooling water. A spiral groove formed on the inner surface side of the joint portion.