KR20230168821A - R410A gas insulated transformer - Google Patents

Abstract

The present invention has the following structure.
Transformers;
A radiator configured to expand the heat dissipation area in the enclosure of the transformer;
A sealing means configured to seal the enclosure of the transformer to prevent the gaseous R410A gas from leaking to the outside;
A gas injection unit configured to inject R410A, an insulating gas, into the enclosure of the transformer;
It relates to an R410A gas insulating transformer, characterized in that it is configured to eliminate the risk of fire, including a pressure measuring unit that measures the pressure of the R410A injected through the gas injection unit.

Description

R410A gas insulated transformer{R410A gas insulated transformer}

The present invention is a technology to increase the strength of insulation by injecting environmentally friendly gas to insulate a transformer.

The technology behind the invention is a fin-and-tube type heat exchanger that uses a flammable refrigerant and has two or more rows of multi-stage pipe arrangements, as disclosed in Korea Intellectual Property Office Patent Publication No. 10-2014-0103249 (2014.08.26). Even when functioning as an evaporator, in order to suppress degradation of the heat exchanger performance, heat transfer pipes having the same pipe inner diameter are arranged in the same row, and when the heat exchanger functions as an evaporator, the change in saturation temperature is the flammable refrigerant of R410A. It describes the use of R410A in an air conditioner in which the piping inner diameter of the heat transfer tube through which a refrigerant with a low dryness flows is approximately equivalent, and the inner diameter of the pipe through which a flammable refrigerant with a high dryness flows is configured to be smaller than the background inner diameter of the heat transfer tube through which a flammable refrigerant with a high dryness flows, so that the use of . .

In Korea Intellectual Property Office Patent Registration No. 10-0605797 (2006.08.01), in an air conditioner equipped with a plurality of utilization units, an increase in the cost of parts constituting the refrigerant circuit is suppressed even when the maximum operating pressure of the refrigerant circuit increases. do. The air conditioner (1) is equipped with a plurality of utilization units (5), and is equipped with a vapor compression type refrigerant circuit (10) and an accumulator (25). The refrigerant circuit 10 consists of a high-pressure section 10a composed of components capable of flowing high-pressure refrigerant with a maximum operating pressure of 3.3 MPa or more, and a high-pressure section 10a that allows only low-pressure refrigerant with a maximum operating pressure of less than 3.3 MPa to flow. It has a low-voltage section 10b configured by connecting possible components.

The accumulator 25 is one of the components constituting the low-pressure section 10b, and is capable of collecting the refrigerant circulating in the refrigerant circuit 10 as liquid refrigerant. The refrigerant flowing through the low-pressure section 10b and the high-pressure section 10a is R410A.

The second background technology is the use of R410A as a refrigerant in air conditioning devices.

The background technology of the Korean Intellectual Property Office Patent Publication No. 10-2010-0068143 (2010.06.22) aims to improve durability by suppressing the increase in acid value of refrigeration oil in refrigerant compressors and refrigeration cycle devices using the same. The refrigerant enclosed in the compressor is R410A, R407C, or R404A.

The third background technology also concerns refrigerants used in refrigerant compressors and refrigeration cycle devices.

According to Korea Intellectual Property Office Patent Publication No. 10-2018-0104512 (2018.09.21), the refrigeration capacity of the air conditioner is 5kW or more and 7kW or less, and the refrigerant circulating in the air conditioner is

A mixed refrigerant containing more than 50% of R410a is used, the compressor is a rotary compressor with a limit refrigerant volume of 1,600 cc, and the refrigerant pipe is a ductile stainless steel pipe with a delta ferrite matrix structure of 1% or less based on the particle size area. Since it is included, there is an advantage in that the strength and hardness of the refrigerant pipe can be maintained at a level higher than that of the copper pipe while maintaining good workability.

In the fourth background technology, a mixed refrigerant containing more than 50% of R410a is used as a refrigerant circulating in the air conditioner, and R410a gas has never been used for insulation.

The present invention was born under this background.

Korea Intellectual Property Office Patent Registration No. 10-0605797 (2006.08.01) Korea Intellectual Property Office Patent Registration No. 10-2354891 (2022.01.25) Korea Intellectual Property Office Patent Publication No. 10-2014-0103249 (2014.08.26) Korea Intellectual Property Office Patent Publication No. 10-2010-0068143 (2010.06.22) Korea Intellectual Property Office Patent Publication No. 10-2018-0104512 (2018.09.21)

The first task that the invention aims to solve is to reduce the risk of explosion and ignition of transformers in apartments, buildings, hospitals, and subways.

The second problem that the invention aims to solve is the problem of environmentally friendly transformers.

The third problem that the invention aims to solve is the problem of lightening the weight of the transformer.

The fourth problem that the invention aims to solve is the problem of significantly lowering the maintenance and repair costs of transformers.

In order to solve the above problems, it has the following configuration.

Transformers;

A radiator configured to expand the heat dissipation area in the enclosure of the transformer;

A sealing means configured to seal the enclosure of the transformer to prevent the gaseous R410A gas from leaking to the outside;

A gas injection unit configured to inject R410A, an insulating gas, into the enclosure of the transformer;

The R410A gas insulation transformer is configured to eliminate the risk of fire, including a pressure measuring unit that measures the pressure of the R410A injected through the gas injection unit.

Here, in order to further increase the insulation strength of the transformer, it is desirable to increase the pressure of the injected R410A gas to 1 to 3.0 kgf/cm ² .

The second example is as follows.

Transformers;

A radiator configured to expand the heat dissipation area in the enclosure of the transformer;

The enclosure of the transformer includes a sealing means configured to mix gaseous R410A with air or carbon dioxide and seal the mixed gas to prevent it from leaking to the outside;

A gas injection unit configured to inject the mixed gas, which is an insulating gas, into the enclosure of the transformer;

The R410A gas insulating transformer is configured to further increase the insulation strength through the mixed gas and eliminate the risk of fire, including a pressure measuring unit that measures the pressure of the mixed gas injected through the gas injection unit.

Here, the sealing strength of the sealing means is preferably configured to seal even when the maximum pressure of the gas injected into the transformer is 3.3 kgf/cm ² .

Here, the air is preferably carbon dioxide.

Here, in order to further increase the insulation strength of the transformer, it is desirable to increase the pressure of the injected mixed gas to 1 to 3.0 kgf/cm ² .

Here, the mixing ratio of the mixed gas is preferably configured to satisfy R410A gas: carbon dioxide = 7:3 to 8:2.

Here, the mixing ratio of the mixed gas is preferably configured to satisfy R410A gas: air = 8:2.

Here, the sealing means is preferably configured to weld the enclosure of the transformer.

Here, the sealing means is preferably configured to weld the radiator.

The first effect of the invention is to reduce the risk of explosion and ignition of transformers in apartments, buildings, hospitals, and subways.

The second effect of the invention is to produce an environmentally friendly transformer.

The third effect of the invention is to have the effect of lightening the weight of the transformer.

The fourth effect of the invention is to significantly reduce the maintenance and repair costs of transformers.

Figure 1a is a front view of the R410A gas insulated distribution three-phase transformer.
Figure 1b is a plan view of the R410A gas insulated distribution three-phase transformer.
Figure 1c is a diagram showing the state in which R410A gas is injected into the R410A gas insulated distribution 3-phase transformer.
Figure 2a is a front view of the elbow-shaped R410A gas-insulated three-phase transformer.
Figure 2b is a plan view of the elbow-shaped R410A gas-insulated three-phase transformer.
Figure 2c is a diagram showing the state in which R410A gas is injected into the elbow-shaped R410A gas insulated three-phase transformer.
Figure 3a is a plan view of the R410A gas-insulated single-phase columnar transformer.
Figure 3b is a front view of the R410A gas-insulated single-phase columnar transformer.
Figure 3c is a diagram showing the state in which R410A gas is injected into the R410A gas-insulated single-phase columnar transformer, viewed from a different direction than 3b.
Figure 4a is a plan view of the elbow-shaped R410A gas-insulated single-phase columnar transformer.
Figure 4b is a front view of the elbow-shaped R410A gas-insulated single-phase columnar transformer.
Figure 4c is a diagram showing the state in which R410A gas is injected into the elbow-shaped R410A gas-insulated single-phase columnar transformer, viewed from a different direction than 4b.

In order to have the above effect, it has the following configuration.

The explanation with reference to the drawings is as follows.

The drawing shows an R410A gas insulated distribution transformer using a general insulator type bushing.

In the drawing, it consists of a high pressure bushing (106) and a low pressure bushing (114).

A moving handle 118 is provided when moving the transformer.

The tap changer 132 is also configured to be switched as needed.

The transformer enclosure 102 is equipped with a radiator 116, which expands the heat dissipation area of the enclosure 102 so that R410A, a heating medium, can effectively cool the heat generated inside the transformer.

The transformer enclosure (102) must be sealed to prevent R410A gas from leaking to the outside, and there are moving handles (118) on the left and right sides to allow the transformer to be moved.

The drawing shows a cable 134 connected to the high voltage section.

The pressure measuring unit 108 is provided to determine whether the R410 gas is injected at an appropriate pressure, whether the gas is leaking, and whether there is a shortage of gas during use.

When injecting or collecting R410A gas again, it is injected or collected through the gas injection unit 120.

The gray color in the drawing means that R410A gas is used as an insulating medium.

Inside the transformer, like a transformer that uses insulating oil as an insulating medium, a winding is placed in the core and the winding and the bushing are connected with a cable (134) so that the electricity entering the high-voltage bushing (106) changes to low voltage through the low-pressure bushing (114). It shows the structure of a transformer that can be used.

A transformer is constructed, and a radiator 116 is constructed to expand the heat dissipation area in the transformer's enclosure 102.

In the transformer shown in Figures 1c, 2c, and 3c, the R410A gas is shown to be spread inside the transformer, and the part indicated by reference numeral 142 indicates the corresponding location inside the transformer.

The primary and secondary windings 142 are wound around the core 140, which is the basic structure, and the number of primary and secondary windings 142 is configured to distribute electricity at an appropriate voltage.

In addition, reference numeral 138 corresponding to the upper core fastener 138 indicates the entire horizontal rectangular area indicated by a solid line.

The lower core fastener 146 indicates the entire horizontal rectangular area indicated by a solid line.

The enclosure 102 of the transformer is configured with a sealing means to prevent the gaseous R410A gas from leaking to the outside.

A gas injection unit 120 is configured to inject R410A, an insulating gas, into the enclosure 102 of the transformer.

The R410A gas insulation transformer is configured to eliminate the risk of fire by including a pressure measuring unit that measures the pressure of the R410A injected through the gas injection unit 120.

The enclosure 102 must be made of thick steel plate to prevent damage to the enclosure 102 and the radiator 116 when filled with gas at a maximum pressure of 3.0 kgf/cm ² .

where 3.0kgf/cm ² The reason for applying is that the insulation properties of R410A gas can be most optimized.

In order to further increase the insulation strength of the transformer, the pressure of the R410A gas injected is 1 to 3.0 kgf/cm. ² It is desirable to increase it to .

Pressure of R410A gas is 3.0kgf/cm ² In this case, considering the transformer volume and cost, this is the desirable value for the best insulation strength.

In Figure 5, it is configured by atmospheric pressure and kgf/cm ² I think the units of the department should be unified.

Please indicate one of the two.

In order to increase the insulation performance, the insulation distance between the enclosure 102 and the middle body is secured, and the insulation performance is increased by mixing R410A gas and carbon dioxide at a ratio of 7:3 to 8:2.

In the case of R410A gas, R410A insulation varies depending on atmospheric pressure, but has an insulation of about 0.6 to 0.7 (33kV when the distance between electrodes is 6mm).

In order to improve the insufficient insulation performance of R410A, it is important to increase the pressure, but this can be further strengthened by mixing other gases.

Carbon dioxide, which is currently being developed as an eco-friendly refrigerant and insulator in most countries, can be seen as one of the insulating mixed gases.

Although pure carbon dioxide alone cannot act as an insulator yet, it can be used as a mixed gas to reinforce R410A.

In the case of pure R410A gas, when an insulation breakdown test is performed with a 6mm electrode, the insulation strength is approximately 60kV at 3kgf/cm ² .

However, when the same electrode test is performed at 3kgf/cm ² when carbon dioxide is 20% and R410A gas is 80%, the insulation strength is 66kv.

In the case of 30% carbon dioxide and 70% R410A gas, the dielectric strength was about 1~2kV lower than that of 100% pure R410A, and it is better to use pure R410A gas.

Nevertheless, if you want to reduce the ratio of R410A gas to reduce costs, the ratio of 7:3 is the best ratio.

This is because the insulation strength decreases as the carbon dioxide ratio increases, so if the carbon dioxide ratio is increased to 40%, the performance deteriorates and the insulation of the transformer cannot be guaranteed.

If you focus on strengthening insulation, it is most effective to use a mixed gas with a ratio of 2:8 of carbon dioxide and R410A gas. If you use a ratio of 10% carbon dioxide and 90% R410A gas, it is effective in terms of cost and performance. It's not effective. If it is difficult to obtain a mixed gas, pure R410A gas can be used without difficulty by maintaining a pressure of only 3.0 kgf/cm ² and used in single-phase, three-phase main phase, and distribution transformers.

In the case of dry air from which moisture has been removed, it can be used as an insulator and was mixed with R410A, but the effect is less than that of carbon dioxide.

If you want to reduce costs more than carbon dioxide, it is possible to mix it with dry air and use it at a ratio of 2:8.

In addition, the insulation performance is reinforced with the radiator 116.

The second embodiment is to inject mixed gas.

A transformer is constructed, and a radiator 116 is constructed to expand the heat dissipation area in the transformer's enclosure 102.

The enclosure 102 of the transformer is constructed by mixing gaseous R410A with air and using a sealing means to seal the mixed gas so that it does not leak to the outside.

A gas injection unit 120 is configured to inject the mixed gas, which is an insulating gas, into the enclosure 102 of the transformer.

The R410A gas insulating transformer is configured to further increase the insulation strength through the mixed gas, including a pressure measuring unit that measures the pressure of the mixed gas injected through the gas injection unit 120, and to eliminate the risk of fire.

The sealing strength of the sealing means is such that it is sealed even when the maximum pressure of the gas injected into the transformer is 3.3 kgf/cm ² .

More preferably, the air is carbon dioxide.

The sealing means is configured to weld the enclosure 102 of the transformer.

The sealing means is preferably configured to weld the radiator 116.

Of course, the sealing means can be bolted together using a cover tightening bolt (130) with a gasket in between.

The configuration of the transformer of the present invention is different from that of a transformer equipped with existing insulating oil in that it does not have a breathing apparatus, an oil temperature gauge, or an oil level gauge.

The difference is that it does not have the above configuration, whereas it has a gas pressure gauge and a gas inlet.

The respirator slows down the oxidation of the insulating oil and is composed of silica gel to absorb moisture and prevent the insulating oil from being oxidized.

However, as a period of one year passes, the actual car gel is no longer meaningless, and in existing inventions, it is inevitable that the insulating oil oxidizes over time.

The oil temperature gauge, which is not present in the present invention, is an instrument that indicates the temperature of the oil lubricated inside during operation of the engine or T/M.

It lights up or changes when the oil usage exceeds the specified level due to internal damage, poor lubrication, oil shortage, etc., and sometimes a warning sound is installed.

A flow meter is a measuring instrument that specifies the flow rate based on mass, volume, or differential pressure.

The pros and cons of replacing a transformer using insulating oil with a transformer using R410A gas are as follows.

First of all, R410A gas has little risk of explosion or ignition.

Transformers using insulating oil often explode or ignite due to burnout or external shock, causing damage to transformers, buildings, and people.

In the case of molded transformers, the risk of explosion and ignition is lower than that of transformers using insulating oil, but when ignition occurs, there is a high risk of casualties due to the toxic gases emitted when the epoxy insulation burns.

However, in the case of the R410A gas insulated transformer of the present invention, there is no risk of ignition or explosion because R410A gas is a non-flammable material.

Therefore, it has the advantage of being installed in places vulnerable to fire, such as apartments, buildings, hospitals, and subways.

The volume of the transformer is relatively small.

In the case of an oil-immersed transformer using insulating oil, there are many additional components such as a breathing apparatus and conservator.

However, in the case of the R410A gas insulated transformer, since it is sealed, there is no need for a respirator or conservator, so the transformer volume can be configured to be relatively small.

By reducing the number of components, there is also a cost reduction effect.

In oil-immersed transformers, the oil deteriorates when it comes in contact with air. To prevent this, place a cylindrical container called a conservator on top of the enclosure (102) and connect it to the enclosure (102) to ensure that no air exists in the enclosure (102). It is composed.

As a result, the surface area where the oil contacts the air is reduced, and air does not directly enter the transformer enclosure 102 due to breathing, thereby preventing oil deterioration.

This configuration is an essential configuration in conventional transformers.

However, in the present invention, this configuration is not necessary, so the volume of the transformer is reduced and there is a corresponding economic effect.

The present invention eliminates the need for insulating oil replacement.

In the case of oil-immersed transformers using insulating oil, insulating oil replacement is performed approximately every 5 to 10 years.

In order to replace the transformer insulating oil, a lot of work costs such as dobby, insulating oil, waste oil, and crane are incurred, but in the R410A gas insulated transformer, there is no need for replacement of the above items.

Even if additional gas is to be injected, the gas can be injected through the gas injection unit 120 using a light gas cylinder, thereby significantly reducing time and cost.

Relatively eco-friendly.

In the case of oil-immersed transformers, insulating oil is used, causing environmental pollution due to waste oil and ground pollution due to insulating oil leakage.

Additionally, in the case of molded transformers, there is no way to dispose of the epoxy mold when the life of the transformer has expired, causing serious environmental pollution.

On the other hand, in the case of R410A gas insulated transformer, R410A gas has zero ozone depletion and there is no worry about oil leakage.

R410A gas is a very eco-friendly material because it takes about 14 to 17 years to decompose in natural conditions.

The weight of the transformer of the present invention is light.

Since the weight occupied by insulating oil or mold epoxy is replaced by R410A gas, the weight is relatively light and the work efficiency is very high.

However, in the present invention, the manufacturing cost of the enclosure 102 increases.

In the case of an oil-immersed transformer, no problem occurs even if the enclosure 102 is made thin.

However, in the case of the R410A gas insulated transformer, the insulation must be increased by increasing the internal pressure, so it is necessary to weld the upper part of the enclosure 102 to prevent gas leakage.

It can be composed of upper and lower tightening bolts (144) with a high-performance gasket in between.

Therefore, although the manufacturing cost of the enclosure 102 is high for an oil-immersed transformer, it is manufactured so strong that it has long durability.

Additionally, cooling performance is reduced. In the case of oil-immersed transformers, the cooling performance of R410A gas is lower than that of insulating oil.

The possibility of upper gas leakage is prevented by welding the upper cover of the enclosure 102.

It is a high-performance gasket and can be connected using the upper and lower tightening bolts (144).

In the case of an insulating oil type inlet transformer, the upper part of the upper enclosure (102) is connected by bolting. If this method is applied as is, gas may leak in the future when the bolt fastening becomes loose. To prevent this phenomenon, the upper part of the transformer is Weld the area and check if gas is leaking with an R410A gas meter.

It can be joined with a cover tightening bolt (130) with a high-performance gasket in between.

The R410A gas, which has poor insulation, is configured to increase the pressure inside the enclosure (102) to improve insulation and increase the insulation distance differently depending on the design capacity and voltage.

Figure 5 is a diagram showing the relationship between the insulation distance for each internal pressure and the breakdown voltage.

Terms or words used in this specification and claims should not be construed as limited to their common or dictionary meanings, and the inventor may appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted with meaning and concept consistent with the technical idea of the present invention based on the principle that it is.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention, so at the time of filing this application, they can be replaced. It should be understood that various equivalents and variations may exist.

100:R410A gas insulated columnar transformer
102: Enclosure 104: Cover 106: High pressure bushing 108: Pressure measuring unit 112: Hand hole
114: Low pressure bushing 116: Radiator 118: Mobile handle
120: Gas injection part
130: Cover fastening bolt 132: Tap changer 134: Cable 138: Upper core fastener
140: Core 142: 1st and 2nd windings 144: Upper and lower fastening bolts 146: Lower core fasteners

Claims (9)

Transformers;
A radiator configured to expand the heat dissipation area in the enclosure of the transformer;
A sealing means configured to seal the enclosure of the transformer to prevent the gaseous R410A gas from leaking to the outside;
A gas injection unit configured to inject R410A, an insulating gas, into the enclosure of the transformer;
R410A gas insulating transformer, characterized in that it is configured to eliminate the risk of fire, including a pressure measuring unit that measures the pressure of the R410A injected through the gas injection unit. The R410A gas insulating transformer according to claim 1, wherein the pressure of the R410A gas injected is increased to 1 to 3.0 kgf/cm ² in order to further increase the insulation strength of the transformer. Transformers;
A radiator configured to expand the heat dissipation area in the enclosure of the transformer;
The enclosure of the transformer includes a sealing means configured to mix gaseous R410A and dehumidified air or carbon dioxide and seal the mixed gas to prevent it from leaking to the outside;
A gas injection unit configured to inject the mixed gas, which is an insulating gas, into the enclosure of the transformer;
R410A gas insulating transformer, characterized in that it is configured to further increase the insulation strength through the mixed gas and eliminate the risk of fire, including a pressure measuring unit that measures the pressure of the mixed gas injected through the gas injection unit. The R410A gas insulated transformer according to claim 1 or 3, wherein the sealing strength of the sealing means is such that it is sealed even when the maximum pressure of the gas injected into the transformer is 3.3 kgf/cm ² . The R410A gas insulated transformer according to claim 3, wherein the pressure of the injected mixed gas is increased to 1 to 3.0 kgf/cm ² in order to further increase the insulation strength of the transformer. The R410A gas insulating transformer according to claim 3, wherein the mixing ratio of the mixed gas is configured to satisfy R410A gas:air=8:2. The R410A gas insulating transformer according to claim 3, wherein the mixing ratio of the mixed gas is configured to satisfy R410A gas: carbon dioxide = 7:3 to 8:2. The R410A gas insulated transformer according to any one of claims 1 to 3, wherein the sealing means is configured to weld the enclosure of the transformer. The R410A gas insulated transformer according to any one of claims 1 to 3, wherein the sealing means is configured to weld the radiator.