JPH11319763A - Production of concrete block - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for producing a concrete block in which an insulating oil-sealing instrument is trapped by preventing insulating oil from being drawn from the inside of the insulating oil-sealing instrument and completely interrupting both insulating oil and the outside air and preventing leakage of insulating oil. SOLUTION: The whole insulating oil-sealing instrument 20 is coated with coal tar 40 by making the insulating oil-sealing instrument 20 closed in which sealing oil is sealed. A network body 42 made of metal is fitted from the upside of this coal tar 40. Then, synthetic resin 44 is covered from the upside of the network body 42 made of metal. The insulating oil-sealing instrument 20 covered with the synthetic resin 44 is held in a formwork and concrete is poured into the formwork to cover the whole insulating oil-sealing instrument 20 with concrete and thereby it is formed into a concrete block 52. Thereafter, the surface of the concrete block 52 is coated with a weathering preventive of concrete.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for manufacturing a concrete block in which an insulating oil-filled device in which insulating oil is filled is sealed in a concrete block so that the insulating oil does not leak.

[0002]

2. Description of the Related Art Devices such as transformers, circuit breakers, and capacitors used for power transmission and distribution (hereinafter referred to as insulating oil filled devices) are filled with insulating oil for insulating and cooling internal windings and the like. I have. Conventionally, polychlorinated biphenyl (hereinafter referred to as PCB) has been used for this insulating oil. Since this PCB is resistant to heat and chemically stable, it is often used as a heat carrier, but it is extremely harmful to the human body and its production is currently prohibited. Conventionally, the treatment of the insulation oil-filled equipment after the life of such insulation oil-filled equipment has expired involves extracting the insulation oil from the insulation oil-filled equipment,
A method of separately treating the insulating oil and the insulating oil-filled device has been used. However, at this stage, a method of completely detoxifying PCBs has not been established yet, and at present, a method of heating and incinerating PCBs by raising the temperature to 1,000 and several hundred degrees Celsius has been adopted. It is extremely difficult to completely burn PCB. In addition, cinders after heating and incineration of the PCB also require advanced treatment.
Further, the inside of the housing of the device from which the insulating oil has been taken out is washed to remove the attached insulating oil, and the washed housing is treated as industrial waste according to the respective materials. Trichloroethylene or perchlorethylene is used as a cleaning liquid for this cleaning.

[0003]

When discarding an insulating oil-filled device, the insulating oil is once extracted from the insulating oil-filled device, and the insulating oil and its casing are separately treated. However, there is a possibility that the insulating oil may be spilled or scattered when extracting the insulating oil, and in such a case, there is a problem that even a small amount of the insulating oil is very dangerous. In addition, under the present circumstances where it is difficult to completely detoxify PCBs by heat incineration, there is also a problem that heat incineration is performed, which has a very bad effect on the human body and the environment.

Therefore, the present invention has been made to solve the above problems, and an object of the present invention is to prevent the insulating oil from being extracted from the inside of the insulating oil filled device, completely shut off the insulating oil from the outside air, It is an object of the present invention to provide a method of manufacturing a concrete block that can contain insulating oil-filled equipment without leaking insulating oil.

[0005]

The present invention has the following arrangement to achieve the above object. That is, according to the method for manufacturing a concrete block according to the present invention, a step of applying coal tar to the entire insulating oil-filled device while keeping the insulating oil-filled device filled with the insulating oil hermetically sealed; A step of mounting a metal net from above, a step of coating a synthetic resin from above the metal net, and a step of housing the insulating oil-encapsulated device coated with the synthetic resin in a mold. A step of pouring concrete into the formwork, covering the entire insulating oil-filled device with concrete to form a concrete block, and applying a concrete weathering inhibitor to the surface of the concrete block. And By adopting this method, the insulation oil-filled equipment can be sealed in the concrete block without extracting the insulation oil from the insulation oil-filled equipment. It is possible to manufacture a concrete block that can completely shut off insulating oil and outside air without deforming or damaging the equipment even if it is an input equipment. Also,
In the step of coating the synthetic resin from above the metal mesh, the synthetic resin is coated from above the metal mesh, and before the synthetic resin solidifies, the glass is coated from above the synthetic resin. By attaching a fiber net and coating the synthetic resin again from above the glass fiber net, the glass fiber net can be enclosed in the synthetic resin, so that the synthetic resin is further strengthened. Things. In addition, after the step of coating the synthetic resin from above the metal net, if a step of attaching a heat insulating material from above the synthetic resin is included, cracks or the like of the synthetic resin due to a change in outside air temperature can be prevented. Can be prevented. Further, since the concrete block is formed as a reinforced concrete block, the concrete strength can be increased, and damage to the insulating oil sealing device inside the concrete can be prevented. The insulating oil-filled device is a pole transformer, and if the insulating oil contains polychlorinated biphenyl, the pole transformer is sealed in a concrete block without causing contamination by polychlorinated biphenyl. be able to.

Further, according to the concrete block of the present invention, the coal oil is applied to the whole of the insulating oil-filled device in which the insulating oil is sealed, and the metal net is formed on the coal tar from above. The concrete block is also formed by being attached, being covered with a synthetic resin from above the metal net, and being covered with concrete from above the synthetic resin. According to this concrete block, since the insulating oil-filled device is sealed without extracting the insulating oil from the insulating oil-filled device, contamination due to scattering of the insulating oil when extracting the insulating oil from the insulating oil-filled device is prevented. In addition, the insulation oil and the outside air can be completely shut off. If the insulating oil-filled device is a pole transformer, and the insulating oil is polychlorinated biphenyl, the pole transformer is sealed so as not to cause contamination by polychlorinated biphenyl.

[0007]

Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings. First, the structure of the insulating oil-filled device will be described with reference to FIG. In addition,
In the present embodiment, the pole transformer is described as an example of the insulating oil-sealed device, but the insulating oil-sealed device is not limited to the pole transformer, but may be a transformer installed on the ground. You may. As shown in FIG. 1, the insulating oil-filled device 20 includes a housing 22 formed in a substantially cylindrical shape, and an internal device 24 including a primary winding, a secondary winding, an iron core, and the like provided in the housing 22. It is composed of Insulating oil 26 for immersing the internal equipment is injected into the housing 22, and the upper opening of the housing 22 is closed and sealed by a lid 28. This is because the insulating oil 26 is oxidized when it comes into direct contact with the outside air, and the life of the insulating oil-filled device 20 itself is shortened.
This is to prevent the insulating oil 26 from touching the outside air.
The insulating oil 26 is sealed in order to insulate the windings from each other and to cool the heat generated by the eddy current. As described in the prior art, PCBs were once mainly used. 32 is a low voltage terminal, 34 is a high voltage terminal,
Connection parts between these terminals 32 and 34 and the internal device 24 are omitted from the illustration. At the bottom of the housing 22,
An oil discharge valve 36 for extracting the insulating oil 26 is provided. To extract the insulating oil 26 from the insulating oil sealing device 20, the oil discharge valve 36 is opened.

Next, a preferred embodiment of a method for storing the insulating oil-filled device 20 will be described. As shown in FIG. 2, first, coal tar 40 is applied to the entire periphery of the insulating oil-filled device 20 to be stored. At this time, it is necessary that the insulation oil 26 inside the insulation oil sealing device 20 be completely sealed so as not to leak out. In addition, members that are attached to the outside of the housing 22 and that allow the inside and the outside of the housing 22 to communicate with each other should not be removed. However, in the present embodiment, the insulators of the low-voltage terminal 32 and the high-voltage terminal 34 provided on the lid 28 are removed because the hermetic seal in the housing 22 is maintained even when they are removed. ing. Further, the coal tar 40 is applied so that the thickness becomes about 1 cm to 2 cm. By applying the coal tar 40 to the entire periphery of the insulating oil-sealed device 20 in this manner, no matter what material the insulating oil-sealed device 20 is made of, when the synthetic resin 44 described later is coated with the synthetic resin 44, Adhesion with the insulating oil-filled device 20 can be performed strongly. That is,
Coal tar 40 is made of synthetic resin 44 and insulating oil-filled equipment 2
It has a role as an adhesive between zero.

When the coal tar 40 is applied to the bottom surface 20a of the insulating oil sealing device 20, first, the bottom surface 20a
Coal tar 40 is applied to parts other than
When the coal tar of the part other than 0a is dried, the bottom 20a
And apply coal tar 40 on the bottom surface 20a. When the insulating oil-filled device 20 is lifted, the already applied coal tar 40 is prevented from peeling off. The insulating oil-filled device 20 keeps the coal tar 4 on the bottom surface 20a until the coal tar 40 applied to the bottom surface 20a dries.
It must be lifted so that 0 does not stick to the ground and peel off. At this time, the insulating oil-filled equipment 2
A method of applying the coal tar to the bottom surface 20a by, for example, turning over the insulating oil-filled device 20 without lifting the zero is also conceivable, but the internal insulating oil 26 may flow out of the gap between the lid 28 and the housing 22 or the like. There is an insulation oil filled device 20
Rolling over is dangerous.

After the coal tar 40 is applied to the entire periphery of the insulating oil-filled device 20, a metal net 42 is mounted on the surface of the coal tar 40 as shown in FIG. As the metal net 42, it is preferable to use a stainless net which does not easily generate rust, but other materials may be used. When the metal net 42 is mounted on the surface of the coal tar 40, when the synthetic resin 44 described later is coated, the synthetic resin 44 bites into the metal net 42 and is solidified, and the synthetic resin 44 is solidified. The strength of the solidified synthetic resin can be increased. The metal net 42 is attached to the entire periphery of the insulating oil-filled device 20, but the entire periphery is 1 mm.
It is not necessary to cover with the nets 42. For example, a net body 42 that is separately separated may be attached to the outer peripheral surface of the housing 22, the upper surface of the lid 28, and the bottom surface 20a.

[0011] Next, as shown in FIG.
2 is sprayed so as to cover the synthetic resin 44. The method of coating the synthetic resin 44 is not limited to spraying, but may be coating or the like. As an example of the synthetic resin 44, it is preferable to use polyethylene. Polyethylene has high resistance to oil and chemicals, and can more strongly protect the insulating oil-filled device 20. This synthetic resin 44 is preferably coated to a thickness of about 3 cm to 5 cm so that no gap is formed around the entire periphery of the insulating oil filled device 20. As described above, since the synthetic resin 44 is sprayed around the entire periphery of the insulating oil-sealed device 20, the insulating oil-sealed device 20 can be completely sealed to shut off the insulating oil 26 from the outside air. Similarly to the coal tar 40 described above, the synthetic resin 44 is also provided on the bottom surface 20a of the insulating oil-filled device 20.
Must be sprayed. Spraying on the bottom surface 20a is performed when the synthetic resin 44 other than the bottom surface 20a is dried.
This is done by lifting 0a. This lifting is performed until the synthetic resin 44 sprayed on the bottom surface 20a is dried. At this time, as described above, the insulating oil-filled device 2
It is preferable to avoid rolling over 0.
When the synthetic resin 44 has solidified, it is preferable to cover the entire periphery of the insulating oil-filled device 20 with the heat insulating material 46. As the heat insulating material 46, rock wool, glass wool, or the like may be used. Thus, the surroundings of the synthetic resin 44 are covered with the heat insulating material 4.
6 so that changes in the outside air temperature
To prevent cracks and the like due to a change in the temperature of the synthetic resin 44.

As shown in FIG. 5, when the synthetic resin 44 is coated so that a net 45 made of glass fiber is sealed in the synthetic resin 44,
This is preferable because the strength of No. 4 further increases. That is, first, the first synthetic resin 44a is coated from above the metal net 42. And this first synthetic resin 44a
Before the resin is solidified, the glass fiber net 45 is attached from above the synthetic resin 44a, and the synthetic resin 44b is again covered from above the glass fiber net 45. Using such a method, the first coating of the synthetic resin 44
a and the next coated synthetic resin 44b are solidified to form an integrated synthetic resin 44 in which a glass fiber net 45 is enclosed.
Formed.

FIG. 6 shows the mold 48 and the insulating oil-filled device 20 housed in the mold 48. The formwork 48 is an insulating oil-filled device 2 in which the periphery of the solidified synthetic resin 44 is covered with a heat insulating material 46.
0 is a frame for forming a concrete block 52 shown in FIG. It is preferable that the internal shape of the formwork 48 is formed in a rectangular parallelepiped shape so that the shapes of the concrete blocks 52 can be easily stacked on each other. When a waterproofing agent is mixed with the concrete so as to maintain the waterproofness, the weathering of the concrete can be prevented. When the insulating oil-filled device 20 is stored in the form 48 as it is, the bottom surface 20a of the insulating oil-filled device 20 contacts the inner bottom surface 48a of the form 48, and the bottom surface 20a is not covered with concrete. A plurality of concrete columns 50 are installed in the formwork 48,
It is preferable that the insulating oil-filled device 20 be placed on the support 50. When the concrete is poured after the insulating oil-filled device 20 is placed on the column 50, the poured concrete is mixed with the bottom surface 20 a of the insulating oil-filled device 20 and the form 4.
8 and solidifies together with the support column 50 by flowing into the inner bottom surface 48a. In this way, it is possible to form the concrete block 52 in which the entire insulating oil sealing device 20 is covered with concrete.

As shown in FIGS. 8 and 9, it is preferable to form reinforced concrete 56 inside the concrete forming the concrete block 52 in order to increase the strength of the concrete itself. In this case, the reinforcing member 54 is placed in the form 48 so as to surround the insulating oil filled device 20.
Are assembled, and the insulating oil-filled device 20 is placed in the center surrounded by the reinforcing bar material 54. Thereafter, by pouring concrete into the formwork 48, the insulating oil enclosing device 20 and the reinforced material 54 are covered with concrete, and a reinforced concrete block 56 containing the reinforced material 54 can be formed.
The diameter and the number of the reinforcing bars 54 may be appropriately changed depending on the size and weight of the insulating oil-sealed device 20 to be processed.

When the concrete is solidified, a weathering inhibitor (not shown) is applied to the entire surface of the concrete blocks 52 and 56.
It is good to spray. Examples of the weathering inhibitor include silicon and the like. By spraying the weathering inhibitor in this way, it is possible to prevent weathering of the concrete, maintain the shape of the concrete blocks 52 and 56 for a long period of time, and to safely enclose the insulating oil enclosing device 20.

The formed concrete blocks 52, 5
6 are stacked and stored. The storage location is preferably in a warehouse or the like having a roof or a wall so that weathering and the like can be prevented. However, it is often difficult to secure a wide place indoors. In such a case, the concrete blocks 52 and 56 may be embedded in the ground for storage.

Although the present invention has been described in detail with reference to the preferred embodiments, the present invention is not limited to these embodiments, and it should be noted that many modifications can be made without departing from the spirit of the invention. Of course.

[0018]

According to the method for manufacturing a concrete block according to the present invention, since the insulating oil is not extracted from the insulating oil-filled equipment, it is possible to prevent contamination due to scattering or the like when extracting the insulating oil, and to make any shape. It is possible to manufacture a concrete block capable of completely shutting off insulating oil and outside air without deforming or damaging the insulating oil-filled equipment. In addition, during the step of coating the synthetic resin from above the metal net, the synthetic resin is coated from above the metal net, and a glass fiber net is attached from above this synthetic resin, By coating the synthetic resin again from above the fiber net, the glass fiber net can be sealed in the synthetic resin, so that the synthetic resin can be further strengthened. In addition, after the step of coating the synthetic resin from above the metal net, if a step of attaching a heat insulating material from above the synthetic resin is included, it is possible to prevent cracking of the synthetic resin due to a change in outside temperature. Can be. Furthermore, since the concrete block is formed into a reinforced concrete block, the concrete strength can be increased, and damage to the insulating oil sealing device inside the concrete can be prevented. If the insulating oil-filled equipment is a pole transformer, and if the insulating oil contains polychlorinated biphenyls, the pole transformers should be sealed in concrete blocks without causing contamination by polychlorinated biphenyls. it can.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of an insulating oil-filled device as viewed from a side.

FIG. 2 is a side view showing a state in which coal tar is applied to the entire periphery of the insulating oil sealing device.

FIG. 3 is a side view showing a state in which a metal net is wound around the entire periphery of the insulating oil-filled device coated with coal tar.

FIG. 4 is a side view showing a state in which synthetic resin is sprayed on the entire periphery of the insulating oil-filled device equipped with the metal net, and a heat insulating material is attached on the entire periphery of the synthetic resin.

FIG. 5 is a side view showing a state where a glass fiber net is sealed and formed in a synthetic resin.

FIG. 6 is an explanatory view showing a state where an insulating oil-filled device is placed in a frame.

FIG. 7 is an explanatory view of a concrete block.

FIG. 8 is a cross-sectional view of a reinforced concrete block in which a reinforced material is put in a concrete block as viewed from a side.

FIG. 9 is a plan view of the reinforced concrete block shown in FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 20 Insulated oil filling device 22 Housing 24 Internal device 26 Insulating oil 28 Lid 32 Low pressure terminal 34 High pressure terminal 36 Oil discharge valve 40 Coal tar 42 Metal net 44 Synthetic resin 45 Glass fiber net 46 Heat insulating material 48 Formwork 50 Prop 52 Concrete block 54 Reinforcing material 56 Reinforced concrete block

[Procedure amendment]

[Submission date] April 23, 1999

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

Patent application title: Method for manufacturing concrete block

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for manufacturing a concrete block in which an insulating oil-filled device in which insulating oil is filled is sealed in a concrete block so that the insulating oil does not leak.

[0002]

2. Description of the Related Art Devices such as transformers, circuit breakers, and capacitors used for power transmission and distribution (hereinafter referred to as insulating oil filled devices) are filled with insulating oil for insulating and cooling internal windings and the like. I have. Conventionally, polychlorinated biphenyl (hereinafter referred to as PCB) has been used for this insulating oil. Since this PCB is resistant to heat and chemically stable, it is often used as a heat carrier, but it is extremely harmful to the human body and its production is currently prohibited. Conventionally, the treatment of the insulation oil-filled equipment after the life of such insulation oil-filled equipment has expired involves extracting the insulation oil from the insulation oil-filled equipment,
A method of separately treating the insulating oil and the insulating oil-filled device has been used. However, at this stage, a method of completely detoxifying PCBs has not been established yet, and at present, a method of heating and incinerating PCBs by raising the temperature to 1,000 and several hundred degrees Celsius has been adopted. It is extremely difficult to completely burn PCB. In addition, cinders after heating and incineration of the PCB also require advanced treatment.
Further, the inside of the housing of the device from which the insulating oil has been taken out is washed to remove the attached insulating oil, and the washed housing is treated as industrial waste according to the respective materials. Trichloroethylene or perchlorethylene is used as a cleaning liquid for this cleaning.

[0003]

When discarding an insulating oil-filled device, the insulating oil is once extracted from the insulating oil-filled device, and the insulating oil and its casing are separately treated. However, there is a possibility that the insulating oil may be spilled or scattered when extracting the insulating oil, and in such a case, there is a problem that even a small amount of the insulating oil is very dangerous. In addition, under the present circumstances where it is difficult to completely detoxify PCBs by heat incineration, there is also a problem that heat incineration is performed, which has a very bad effect on the human body and the environment.

Therefore, the present invention has been made to solve the above problems, and an object of the present invention is to prevent the insulating oil from being extracted from the inside of the insulating oil filled device, completely shut off the insulating oil from the outside air, It is an object of the present invention to provide a method of manufacturing a concrete block that can contain insulating oil-filled equipment without leaking insulating oil.

[0005]

The present invention has the following arrangement to achieve the above object. That is, according to the method for manufacturing a concrete block according to the present invention, a step of applying coal tar to the entire insulating oil-filled device while keeping the insulating oil-filled device filled with the insulating oil hermetically sealed; Mounting a metal net from above, and coating a synthetic resin from above the metal net,
Attaching a heat insulating material from above the synthetic resin;
A step of housing the mounted insulating oil-filled device in a formwork, a step of pouring concrete into the formwork and covering the entire insulating oil-filled device with concrete to form a concrete block; Applying a weathering agent for concrete. By adopting this method, the insulating oil filled apparatus can prevent contamination due to scattering or the like upon withdrawing in the containment in the concrete block without withdrawn insulating oil insulating oil filled device, outside the heat insulator
By preventing cracking of the synthetic resin due to a change in temperature, etc., it is possible to completely shut off the insulating oil from the outside air without deforming or damaging any type of insulating oil-filled equipment. Further, in the step of coating the synthetic resin from above the metal mesh, the synthetic resin is coated from above the metal mesh, and before the synthetic resin solidifies, By attaching a glass fiber net from above and coating the synthetic resin again from above the glass fiber net, it is possible to enclose the glass fiber net in the synthetic resin. It can be strong. Further, since the concrete block is formed as a reinforced concrete block, the concrete strength can be increased, and damage to the insulating oil sealing device inside the concrete can be prevented. The insulating oil-filled device is a pole transformer, and if the insulating oil contains polychlorinated biphenyl, the pole transformer is sealed in a concrete block without causing contamination by polychlorinated biphenyl. be able to.

[0006]

Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings. First, the structure of the insulating oil-filled device will be described with reference to FIG. In addition,
In the present embodiment, the pole transformer is described as an example of the insulating oil-sealed device, but the insulating oil-sealed device is not limited to the pole transformer, but may be a transformer installed on the ground. You may. As shown in FIG. 1, the insulating oil-filled device 20 includes a housing 22 formed in a substantially cylindrical shape, and an internal device 24 including a primary winding, a secondary winding, an iron core, and the like provided in the housing 22. It is composed of Insulating oil 26 for immersing the internal equipment is injected into the housing 22, and the upper opening of the housing 22 is closed and sealed by a lid 28. This is because the insulating oil 26 is oxidized when it comes into direct contact with the outside air, and the life of the insulating oil-filled device 20 itself is shortened.
This is to prevent the insulating oil 26 from touching the outside air.
The insulating oil 26 is sealed in order to insulate the windings from each other and to cool the heat generated by the eddy current. As described in the prior art, PCBs were once mainly used. 32 is a low voltage terminal, 34 is a high voltage terminal,
Connection parts between these terminals 32 and 34 and the internal device 24 are omitted from the illustration. At the bottom of the housing 22,
An oil discharge valve 36 for extracting the insulating oil 26 is provided. To extract the insulating oil 26 from the insulating oil sealing device 20, the oil discharge valve 36 is opened.

Next, a preferred embodiment of a method for storing the insulating oil-filled device 20 will be described. As shown in FIG. 2, first, coal tar 40 is applied to the entire periphery of the insulating oil-filled device 20 to be stored. At this time, it is necessary that the insulation oil 26 inside the insulation oil sealing device 20 be completely sealed so as not to leak out. In addition, members that are attached to the outside of the housing 22 and that allow the inside and the outside of the housing 22 to communicate with each other should not be removed. However, in the present embodiment, the insulators of the low-voltage terminal 32 and the high-voltage terminal 34 provided on the lid 28 are removed because the hermetic seal in the housing 22 is maintained even when they are removed. ing. Further, the coal tar 40 is applied so that the thickness becomes about 1 cm to 2 cm. By applying the coal tar 40 to the entire periphery of the insulating oil-sealed device 20 in this manner, no matter what material the insulating oil-sealed device 20 is made of, when the synthetic resin 44 described later is coated with the synthetic resin 44, Adhesion with the insulating oil-filled device 20 can be performed strongly. That is,
Coal tar 40 is made of synthetic resin 44 and insulating oil-filled equipment 2
It has a role as an adhesive between zero.

When the coal tar 40 is applied to the bottom surface 20a of the insulating oil filling device 20, first, the bottom surface 20a
Coal tar 40 is applied to parts other than
When the coal tar of the part other than 0a is dried, the bottom 20a
And apply coal tar 40 on the bottom surface 20a. When the insulating oil-filled device 20 is lifted, the already applied coal tar 40 is prevented from peeling off. The insulating oil-filled device 20 keeps the coal tar 4 on the bottom surface 20a until the coal tar 40 applied to the bottom surface 20a dries.
It must be lifted so that 0 does not stick to the ground and peel off. At this time, the insulating oil-filled equipment 2
A method of applying the coal tar to the bottom surface 20a by, for example, turning over the insulating oil-filled device 20 without lifting the zero is also conceivable, but the internal insulating oil 26 may flow out of the gap between the lid 28 and the housing 22 or the like. There is an insulation oil filled device 20
Rolling over is dangerous.

After applying the coal tar 40 to the entire periphery of the insulating oil-filled device 20, a metal net 42 is mounted on the surface of the coal tar 40 as shown in FIG. As the metal net 42, it is preferable to use a stainless net which does not easily generate rust, but other materials may be used. When the metal net 42 is mounted on the surface of the coal tar 40, when the synthetic resin 44 described later is coated, the synthetic resin 44 bites into the metal net 42 and is solidified, and the synthetic resin 44 is solidified. The strength of the solidified synthetic resin can be increased. The metal net 42 is attached to the entire periphery of the insulating oil-filled device 20, but the entire periphery is 1 mm.
It is not necessary to cover with the nets 42. For example, a net body 42 that is separately separated may be attached to the outer peripheral surface of the housing 22, the upper surface of the lid 28, and the bottom surface 20a.

[0010] Next, as shown in FIG.
2 is sprayed so as to cover the synthetic resin 44. The method of coating the synthetic resin 44 is not limited to spraying, but may be coating or the like. As an example of the synthetic resin 44, it is preferable to use polyethylene. Polyethylene has high resistance to oil and chemicals, and can more strongly protect the insulating oil-filled device 20. This synthetic resin 44 is preferably coated to a thickness of about 3 cm to 5 cm so that no gap is formed around the entire periphery of the insulating oil filled device 20. As described above, since the synthetic resin 44 is sprayed around the entire periphery of the insulating oil-sealed device 20, the insulating oil-sealed device 20 can be completely sealed to shut off the insulating oil 26 from the outside air. Similarly to the coal tar 40 described above, the synthetic resin 44 is also provided on the bottom surface 20a of the insulating oil-filled device 20.
Must be sprayed. Spraying on the bottom surface 20a is performed when the synthetic resin 44 other than the bottom surface 20a is dried.
This is done by lifting 0a. This lifting is performed until the synthetic resin 44 sprayed on the bottom surface 20a is dried. At this time, as described above, the insulating oil-filled device 2
It is preferable to avoid rolling over 0.
When the synthetic resin 44 has solidified, it is preferable to cover the entire periphery of the insulating oil-filled device 20 with the heat insulating material 46. As the heat insulating material 46, rock wool, glass wool, or the like may be used. Thus, the surroundings of the synthetic resin 44 are covered with the heat insulating material 4.
6 so that changes in the outside air temperature
To prevent cracks and the like due to a change in the temperature of the synthetic resin 44.

As shown in FIG. 5, when the synthetic resin 44 is coated so that a net 45 made of glass fiber is sealed in the synthetic resin 44,
This is preferable because the strength of No. 4 further increases. That is, first, the first synthetic resin 44a is coated from above the metal net 42. And this first synthetic resin 44a
Before the resin is solidified, the glass fiber net 45 is attached from above the synthetic resin 44a, and the synthetic resin 44b is again covered from above the glass fiber net 45. Using such a method, the first coating of the synthetic resin 44
a and the next coated synthetic resin 44b are solidified to form an integrated synthetic resin 44 in which a glass fiber net 45 is enclosed.
Formed.

FIG. 6 shows the mold frame 48 and the insulating oil-filled device 20 housed in the mold frame 48. The formwork 48 is an insulating oil-filled device 2 in which the periphery of the solidified synthetic resin 44 is covered with a heat insulating material 46.
0 is a frame for forming a concrete block 52 shown in FIG. It is preferable that the internal shape of the formwork 48 is formed in a rectangular parallelepiped shape so that the shapes of the concrete blocks 52 can be easily stacked on each other. When a waterproofing agent is mixed with the concrete so as to maintain the waterproofness, the weathering of the concrete can be prevented. When the insulating oil-filled device 20 is stored in the form 48 as it is, the bottom surface 20a of the insulating oil-filled device 20 contacts the inner bottom surface 48a of the form 48, and the bottom surface 20a is not covered with concrete. A plurality of concrete columns 50 are installed in the formwork 48,
It is preferable that the insulating oil-filled device 20 be placed on the support 50. When the concrete is poured after the insulating oil-filled device 20 is placed on the column 50, the poured concrete is mixed with the bottom surface 20 a of the insulating oil-filled device 20 and the form 4.
8 and solidifies together with the support column 50 by flowing into the inner bottom surface 48a. In this way, it is possible to form the concrete block 52 in which the entire insulating oil sealing device 20 is covered with concrete.

As shown in FIGS. 8 and 9, it is preferable to form reinforced concrete 56 inside the concrete forming the concrete block 52 in order to increase the strength of the concrete itself. In this case, the reinforcing member 54 is placed in the form 48 so as to surround the insulating oil filled device 20.
Are assembled, and the insulating oil-filled device 20 is placed in the center surrounded by the reinforcing bar material 54. Thereafter, by pouring concrete into the formwork 48, the insulating oil enclosing device 20 and the reinforced material 54 are covered with concrete, and a reinforced concrete block 56 containing the reinforced material 54 can be formed.
The diameter and the number of the reinforcing bars 54 may be appropriately changed depending on the size and weight of the insulating oil-sealed device 20 to be processed.

When the concrete has solidified, a weathering inhibitor (not shown) is applied to the entire surface of the concrete blocks 52 and 56.
It is good to spray. Examples of the weathering inhibitor include silicon and the like. By spraying the weathering inhibitor in this way, it is possible to prevent weathering of the concrete, maintain the shape of the concrete blocks 52 and 56 for a long period of time, and to safely enclose the insulating oil enclosing device 20.

The formed concrete blocks 52, 5
6 are stacked and stored. The storage location is preferably in a warehouse or the like having a roof or a wall so that weathering and the like can be prevented. However, it is often difficult to secure a wide place indoors. In such a case, the concrete blocks 52 and 56 may be embedded in the ground for storage.

Although the present invention has been described in detail with reference to the preferred embodiments, the present invention is not limited to these embodiments, and many modifications can be made without departing from the spirit of the invention. Of course.

[0017]

According to the method for manufacturing a concrete block according to the present invention, since the insulating oil is not extracted from the insulating oil-filled equipment, it is possible to prevent contamination due to scattering and the like when extracting the insulating oil, and furthermore , it is possible to prevent the use of a metal block . Put a synthetic resin over the net
After the covering process, put the heat insulating material on the synthetic resin
Process, so that synthetic resin
It is possible to manufacture a concrete block that can completely prevent insulation oil from outside air without deforming or damaging any type of insulating oil-filled equipment by preventing cracks and the like . In addition, during the step of coating the synthetic resin from above the metal net, the synthetic resin is coated from above the metal net, and a glass fiber net is attached from above this synthetic resin, By coating the synthetic resin again from above the fiber net, the glass fiber net can be sealed in the synthetic resin, so that the synthetic resin can be further strengthened. Furthermore, since the concrete block is formed into a reinforced concrete block, the concrete strength can be increased, and damage to the insulating oil sealing device inside the concrete can be prevented. If the insulating oil-filled equipment is a pole transformer, and if the insulating oil contains polychlorinated biphenyls, the pole transformers should be sealed in concrete blocks without causing contamination by polychlorinated biphenyls. it can.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of an insulating oil-filled device as viewed from a side.

FIG. 2 is a side view showing a state in which coal tar is applied to the entire periphery of the insulating oil sealing device.

FIG. 3 is a side view showing a state in which a metal net is wound around the entire periphery of the insulating oil-filled device coated with coal tar.

FIG. 4 is a side view showing a state in which synthetic resin is sprayed on the entire periphery of the insulating oil-filled device equipped with the metal net, and a heat insulating material is attached on the entire periphery of the synthetic resin.

FIG. 5 is a side view showing a state where a glass fiber net is sealed and formed in a synthetic resin.

FIG. 6 is an explanatory view showing a state where an insulating oil-filled device is placed in a frame.

FIG. 7 is an explanatory view of a concrete block.

FIG. 8 is a cross-sectional view of a reinforced concrete block in which a reinforced material is put in a concrete block as viewed from a side.

FIG. 9 is a plan view of the reinforced concrete block shown in FIG.

[Description of Signs] 20 Insulation oil-filled equipment 22 Housing 24 Internal equipment 26 Insulation oil 28 Lid 32 Low pressure terminal 34 High pressure terminal 36 Oil discharge valve 40 Coal tar 42 Metal net 44 Synthetic resin 45 Glass fiber Net 46 Heat insulation 48 Formwork 50 Prop 52 Concrete block 54 Reinforcing material 56 Reinforced concrete block

Claims (7)

[Claims] 1. A step of applying a coal tar to the whole insulating oil-filled device while keeping the insulating oil-filled device filled with the insulating oil hermetically sealed, and mounting a metal net over the coal tar. Performing a step of coating a synthetic resin from above the metal net; a step of housing an insulating oil-filled device coated with the synthetic resin in a mold; and pouring concrete into the mold. A method for manufacturing a concrete block, comprising: a step of covering the entire insulating oil-filled device with concrete to form a concrete block; and a step of applying a concrete weathering inhibitor to the surface of the concrete block. 2. In the step of coating the synthetic resin from above the metal net, the synthetic resin is coated from above the metal net and the synthetic resin is solidified before the synthetic resin solidifies. The method for producing a concrete block according to claim 1, wherein a glass fiber net is mounted on the resin, and the synthetic resin is coated again on the glass fiber net. 3. The concrete according to claim 1, further comprising, after the step of coating the synthetic resin from above the metal net, a step of attaching a heat insulating material from above the synthetic resin. Block manufacturing method. 4. The method for producing a concrete block according to claim 1, wherein the concrete block is formed as a reinforced concrete block. 5. The method according to claim 1, wherein the insulating oil-filled device is a pole transformer, and the insulating oil contains polychlorinated biphenyl. . 6. A coal tar is applied to the entirety of the insulating oil-filled device in which the insulating oil is filled, and a metal net is attached from above the coal tar. A concrete block formed by covering a synthetic resin from above, and covering concrete from above the synthetic resin. 7. The concrete block according to claim 6, wherein the insulating oil filling device is a pole transformer, and the insulating oil is polychlorinated biphenyl.