RU2729203C1 - Frequency converter and air cooling method of air cooling - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: group of inventions relates to electrical engineering, in particular to areas of automated electric drive (ED) and conversion equipment with forced ventilation system. Sealed housing of frequency converter (FC) along length is divided into two compartments, one of which is sealed with internal cooling circuit, which includes separate modules. Between the modules within the air channel there is a control unit enclosed in a separate body of trapezoidal shape. Along the perimeter of the modules there are ventilation channels with air drying system elements installed in them. Each of modules is equipped with at least two pairs of air-to-air heat exchangers installed in blown air channels arranged within unsealed compartment to form external cooling circuit. Each pair of heat exchangers includes at least one fan, wherein fan of the first pair of heat exchangers is connected to external cooling circuit, and fan of the second pair of heat exchangers is included into internal circuit and installed in sealed air channel between heat exchangers.

EFFECT: technical result is higher efficiency of air cooling.

10 cl, 7 dwg

Description

The claimed technical solution relates to the field of electrical engineering, in particular, to the areas of an automated electric drive (ED) and converter technology with a forced ventilation system and can be used to build medium-voltage / high-voltage frequency converters and other electrical devices of cabinet design.

At the moment, there are known methods and systems for cooling high-voltage electrical equipment that emit significant dissipated energy in the form of heat, which provide removal of the generated heat through both natural and forced ventilation.

In cabinets made in the form of a sealed shell, a two-circuit cooling system is used, the internal circuit of which is closed and connected to the external one by means of a heat exchanger.

Depending on the type of refrigerant used, a distinction is made between liquid, air and mixed cooling systems, each of which has its own advantages and disadvantages depending on the operating conditions.

One of the most common can be considered an air forced cooling system, due to the relative simplicity of the design and ease of use. The main task in the development of this area of technology is the development of sealed shells with reduced overall dimensions, simplification of the design, increase in maintainability and performance.

The claimed technical solution provides a solution to such problems.

A test container (10, 40, 70) is known from the patent RU 2614155 dated 16.10.2012, it includes a body in the form of a rectangular parallelepiped (12, 42, 72), with electrical components located in it (14, 16, 90, 94, 96) transformer test systems, which in test mode represent an appropriate heat source, and a cooling system with at least one heat exchanger (18, 20, 44, 46, 114). Contains a device (22, 24, 48, 49) for movement, with which at least one heat exchanger (18, 20, 44, 46, 114) can be moved from the transport position inside the container (12, 42, 72) to the working a position that is at least partially outside the container (12,42,72). The cooling system includes a closed cooling circuit (110) of the refrigerant, and at least one heat exchanger is a condenser (114), and at least one evaporator (112) is provided in the inside of the container, which is connected to the condenser via cooling circuit (110).

The disadvantages of the described technical solution include an increase in overall dimensions in the operating position, and the presence of flexible connections of heat exchangers can lead to their failure and leakage of the circuit.

From the utility model patent RU 144730 dated 03/10/2014, a method for cooling the transformer compartment of a high-voltage electrical device is known, where four tangential fans are used, installed in the lower part of the multiwinding transformer cabinet. Three axial fans are installed on the doors of the multi-winding transformer cabinet, which provide air supply from the room to the inside.

The disadvantages of the described technical solution include a large number of fans, which leads to an increase in the size of the device.

From patent for invention No. US9545037 (B2) "System and method of cooling electric drives" there is a method of forced air cooling of an electronic device, according to which the housing is made with at least one sealed compartment protected from contact with the external environment into the specified housing contain both power and low-current electronic components, as well as a heat exchanger connected to a sealed compartment. The air duct adjacent to the upper and lower sealed compartments forms a common wall with the said compartments, which serves as a radiator for the power electronic components installed on it. According to the described method, the cooling system includes an upper heat exchanger located in the air channel and mounted on a common wall with the possibility of air passage from the upper sealed compartment, as well as a lower heat exchanger located in the air channel and installed on the common wall with the possibility of air passage from lower sealed compartment. Each of the heat exchangers is an air-to-air cross-flow heat exchanger having a plurality of passageways formed between rows of plates having substantially flat parallel central portions.

The disadvantages of the described method include the air flow pattern, according to which air enters the heat exchangers heated after passing through the radiator, thereby reducing the efficiency of the heat exchanger.

From the patent for CN203416157 (U) dated 01/29/2014, a medium and high voltage frequency converter with a circulating cooling system is known. The device is made in a monoblock casing in the form of a rectangular parallelepiped, includes power and low-current electronic components placed in at least one sealed compartment with a two-circuit forced air cooling system, with at least one air-to-air heat exchanger.

The forced air cooling method includes creating a circulation channel, implementing forced air circulation, and a heat exchanger. The first heat exchange is carried out in the internal loop of the frequency converter, then the second heat exchange is carried out through the heat exchanger. The heat exchanger contains three independent channels, namely: a heat exchange channel, a cold air channel and a hot air channel.

The disadvantages of the described technical solution include the division of the air flow into two parts inside the compartment, which leads to the need to use an additional recirculating fan inside the compartment to obtain an air flow of sufficient density with the required flow rate and speed. Using a heat exchanger with an intermediate heat exchange channel can reduce the efficiency of the heat exchanger.

The technical solution described in patent CN203416157 (U) is taken as the closest analogue.

The technical problem to be solved by the claimed invention is to create an easy-to-use frequency converter (FC) enclosed in a compact sealed case with an integrated system of two-circuit forced air cooling.

The technical result obtained from the implementation of the claimed invention consists in improving maintainability, as well as improving the ergonomic characteristics of the sealed housing of the frequency converter with an increase in the efficiency of an integrated system of two-circuit forced air cooling.

The essence of the claimed invention lies in the fact that the sealed case of the inverter is divided along the length into two compartments, one of which is made sealed with an internal cooling circuit that includes separate modules. A dry-type high-voltage transformer is installed in the first module on a movable frame. The second module contains the inverter power cells on an insulated frame. Between the modules, within the air channel, a control unit is installed, enclosed in a separate trapezoidal casing, blown from three sides. Along the perimeter of the modules, ventilation ducts are arranged with elements of the air dehumidification system installed in them. Sealed external technological hatches are provided in these channels. Each of the modules is equipped with at least two pairs of air-to-air heat exchangers installed in blown air ducts arranged within the leaky compartment, forming an external cooling circuit. Each pair of heat exchangers contains at least one fan, and the fan of the first pair of heat exchangers is included in the external cooling circuit, and the fan of the second pair of heat exchangers is included in the internal circuit and installed in a sealed air channel between the heat exchangers.

The monoblock body is designed with four-sided access. The front side is equipped with sealed access doors to the transformer modules and the inverter power cells, respectively, as well as an access door to the control unit with built-in microprocessor controller. The side opposite to the front one contains a hermetically sealed compartment for connections and technological access hatches to the elements of the cooling system, in particular fans and heat exchangers.

The end walls of the case are equipped with technological hatches for transformer maintenance and access to the ventilation ducts of the cooling system. The sealed air channel located between the heat exchangers contains at least one fan of the internal circuit of the cooling system installed in the alignment of the air channels of the heat exchangers.

The heat exchangers are formed of prefabricated plates assembled according to the principle of sandwich panels including metal plates with a polymer spacer between them, and the prefabricated plates are separated by spacer inserts installed at the same distance and connected by threaded longitudinal elements installed outside the perimeter of the heat exchanger. Between at least three adjacent collecting plates by means of spacer inserts, two air paths perpendicular to each other are formed, made with the possibility of passing air in two directions, preventing it from mixing.

Based on the described constructive implementation, the method of air cooling of the frequency converter consists in the fact that separate modules are formed in the internal sealed circuit, containing high-voltage electrical components. Air channels are formed along the perimeter of the modules providing cyclical parallel movement of air flows in at least two successive modules. In the rear wall of each module, at least one fan is installed, by means of which the heated air is cyclically moved in the direction of a set of air-to-air heat exchangers installed in pairs in the blown air ducts, forming a second external cooling circuit. Each pair of heat exchangers is equipped with at least one fan, and each fan is installed in the alignment of the air channels of one pair of heat exchangers.

Also, according to a preferred embodiment of the claimed invention, the performance of the fans is controlled by means of an automated control system depending on the temperature value inside the sealed compartment. The air humidity inside the sealed compartment is monitored and the air is dehumidified by additional heating until moisture is released on thermoelectric devices equipped with partially permeable membranes.

According to the claimed invention, the control unit, enclosed in a separate trapezoidal housing, is installed within the air channel between the modules of the sealed compartment, providing cooling of the electronic components installed on its walls by means of a three-sided blowing.

The essence of the proposed technical solution is explained, but not limited to the following graphic materials:

Fig. 1 is a general view of the frequency converter;

figure 2 is a frequency converter, side view;

Fig. 3 is a transformer module;

figure 4 is a frequency converter, rear view;

Fig. 5 is a diagram of a two-circuit forced air cooling;

6 is a diagram of the installation of heat exchangers;

Fig. 7 is an air-to-air heat exchanger.

The frequency converter (Fig. 1) is made in a monoblock casing in the form of a rectangular parallelepiped with openings for doors and access hatches on four sides. The body 1 is divided in length into two compartments. One compartment 2 is made sealed with an internal cooling circuit that includes individual modules 3,4 (figure 2). A high-voltage multi-winding transformer 6 (Fig. 3) of dry design is installed in the transformer module 3 on the movable frame 5. The movable frame is made in the form of a roller platform 7, which is installed on the guides 8 that allow the transformer to be removed during maintenance. To remove the transformer, a technological hatch 10 is provided in the end wall 9 (Fig. 1). In working order, the technological hatch 10 is hermetically closed. Above the technological hatch 10 is a compartment 11 for external connections, which can also be made in the form of a separate modular switching cell.

In module 4, power cells 12 (figure 2) of the inverter are installed on an insulated frame made of polymer material. The cells are easily removable and interchangeable, each of the cells is equipped with a mechanical bypass. Access to the cell module is realized through doors 13 (Fig. 1) on the front panel of the cabinet.

All cabinet doors are equipped with electric and mechanical locking mechanisms 14 for locking the door, which restrict access to the inside in the presence of supply voltage on the structural elements.

The side of the body (Fig. 4), opposite the front one, contains a hermetically sealed compartment of connections 15 and technological hatches 16 for access to the elements of the cooling system, in particular fans and heat exchangers.

The specified design makes it possible to increase the maintainability and usability of the device.

Between the modules of the transformer 3 and the inverter 4 within the air channel is installed a control unit 17 (Fig. 5), enclosed in a separate trapezoidal casing, blown from three sides. The walls of the block 17 serve as radiators for the low-current electronic components of the control system installed on them. This design solution allows efficient cooling of the control unit without the use of additional fans and coolers.

Along the perimeter of modules 3,4 ventilation ducts 18 are arranged, forming an air barrier of cooled air 19, between the outer walls of the case and the internal equipment, preventing its additional heating.

Elements of the air dehumidification system are installed in the ventilation ducts of the sealed compartment. Elements of the air dehumidification system can be presented in the form of Peltier thermoelectric devices installed on coolers 20 and combined with partially permeable membranes, which provide moisture removal from the housing without breaking its tightness. Coolers 20 (Fig. 6) are placed in a leaky circuit and installed on the path of the directional air flow 21. Also, the air dehumidification system contains a set of air heaters, installed within the sealed compartment and can be presented in the form of known electric heating devices (not shown in the images).

The ventilation ducts are equipped with hermetically sealed external technological hatches, which provide all-round access to the elements of the ventilation and air dehumidification system.

Each of the modules 3,4 is equipped with at least two pairs of air-air heat exchangers 22 (Fig. 6; 7) installed in the blown air ducts 23 arranged within the unpressurized compartment 24 (Fig. 1), forming an external circuit 25 ( 6) cooling. Each pair of heat exchangers contains at least one fan, and the fan 26 of the first pair of heat exchangers 27 is included in the external cooling circuit, and the fan 28 of the second pair of heat exchangers 29 is included in the internal circuit and installed in a sealed air channel 30 between the heat exchangers 29. Fans 28 of the internal circuits are installed at the extreme points of the sealed air channel 30 along the vertical axis of each module 3,4 in the alignment of the air channels of a pair of heat exchangers 29.

Heat exchangers 22 (Fig. 7) are formed from prefabricated plates 31 assembled according to the principle of sandwich panels including metal plates with a polymer spacer between them, and the prefabricated plates are separated by spacer inserts 32 installed at the same distance and connected by threaded longitudinal elements 33 installed outside along the perimeter of the heat exchanger ... Between at least three adjacent collecting plates by means of spacer inserts, two air paths perpendicular to each other are formed, made with the possibility of passing air in two directions, preventing it from mixing.

The blown air channels 23 (FIG. 6) are equipped with protective grilles 34.

The method of operation of the cooling system of the sealed case of the inverter according to the claimed technical solution is directly related to the design solutions described above and can be implemented using the essential features of the claimed invention, ensuring the achievement of the specified technical result.

According to the claimed method, the forced air cooling system of the inverter is double-circuit, where one of the circuits is internal 35, it is made sealed with protection against moisture and dust in accordance with the standard not lower than IP 56, (NEMA 4).

In the internal sealed circuit, separate modules 3,4 are formed that accommodate high-voltage electrical components, in particular a multi-winding high-voltage transformer 6 of a dry design (FIG. 3) and a set of power cells 12 of the inverter (FIG. 2).

Along the perimeter of modules 3,4, air channels 18 are formed (Fig. 5) providing a cyclical parallel movement of air flows 19 in at least two serial modules 3,4, also creating an air barrier of cooled air providing additional protection of the internal equipment from the thermal effects of the environment ... In (figure 5) shows one of the number of sequential modules 3,4 a diagram of the movement of air flows, in which they are essentially identical.

In the rear wall of each module 3,4, at least one fan 28 of the internal circuit is installed, by means of which the heated air 36 is cycled in the direction of a set of air-air heat exchangers 22 installed in the blown air channels 23 in pairs, forming a second - external circuit 37 cooling. Each pair 27 of heat exchangers is equipped with at least one fan 26, each of the fans 26, 28 being installed in the alignment of the air channels of one pair of heat exchangers 29, 27, respectively. During the operation of the inverter, the productivity of the operation of the fans 26, 28 is controlled by an automated control system depending on the temperature value inside the sealed compartment 2. Also, before starting the inverter, the air humidity inside the sealed compartment is monitored and the internal air is dried by additional heating until moisture is released on thermoelectric devices equipped with partially permeable membranes. The control and monitoring of the internal equipment of the inverter is implemented on the basis of a programmable microprocessor controller 38 installed in the control unit. The control unit 17, enclosed in a separate trapezoidal casing, is installed within the air channels 18, between the modules 3,4 of the sealed compartment 2, providing cooling of the electronic components installed on its walls by means of a three-sided blowing.

The claimed technical solution contributes to the achievement of the specified technical result, providing optimal dimensions and tightness of the frequency converter housing, improved ergonomic performance, as well as effective forced air cooling of electrical elements placed in a sealed housing protected from moisture and dust according to the standard not lower than NEMA 4, by integrated dual-circuit cooling system.

Claims (10)

1. A frequency converter made in a monoblock casing in the form of a rectangular parallelepiped, including power and low-current electronic components, placed in at least one sealed compartment with a two-circuit forced air cooling system, with at least one air-to-air heat exchanger, characterized in that the sealed compartment contains separate modules, between which, within the air channel, a control unit is installed, enclosed in a separate trapezoidal casing blown from three sides; along the perimeter of these modules, ventilation ducts are arranged with elements of the air drying system installed in them, also in the indicated channels are equipped with sealed technological hatches, while each of the modules is equipped with at least two pairs of air-air heat exchangers installed in blown air channels arranged within the leaky compartment adjacent to the sealed one, forming an external circuit cooling, each pair of heat exchangers contains at least one fan, and the fan of the first pair of heat exchangers is included in the external cooling circuit, and the fan of the second pair of heat exchangers is included in the internal circuit and installed in a sealed air channel between the heat exchangers. 2. The frequency converter according to claim 1, characterized in that the casing of the monoblock design is made with the possibility of four-way access, while the front side is equipped with sealed doors for access to the transformer modules and power cells of the inverter, respectively, as well as an access door to the control unit with a built-in microprocessor controller , in this case, the side opposite to the front contains a hermetically sealed compartment for connections and access hatches to the elements of the cooling system, such as fans and heat exchangers. 3. The frequency converter according to claim 1, characterized in that the end walls of the housing are equipped with technological hatches for servicing the transformer and access to the ventilation ducts of the cooling system. 4. A frequency converter according to claim 1, characterized in that the sealed air channel arranged between the heat exchangers contains at least one fan of the internal circuit of the cooling system installed in the alignment of the air channels of the heat exchangers. 5. The frequency converter according to claim 1, characterized in that the heat exchangers are formed of prefabricated plates assembled according to the principle of sandwich panels, including metal plates with a polymer spacer between them, and the prefabricated plates are separated by spacer inserts installed at the same distance and are connected by threaded longitudinal elements installed outside the perimeter of the heat exchanger. 6. The frequency converter according to claim 1, characterized in that between the at least three adjacent prefabricated plates by means of spacers two air paths are formed, perpendicular to each other, made with the possibility of passing air in two directions, preventing it from mixing. 7. The method of air cooling of the frequency converter, according to which the forced air cooling system is double-circuit, where one of the circuits is internal, is hermetically sealed, characterized in that separate modules containing high-voltage electrical components are formed in the internal sealed circuit, air channels are formed around the modules , providing a cyclical parallel movement of air flows in at least two successive modules, also forming an air barrier from cooled air, while at least two fans are installed in the rear wall of each module, by means of which they provide a cyclic movement of heated air in the direction a set of air-to-air heat exchangers installed in pairs in the blown air ducts, forming an external cooling circuit, each pair of heat exchangers is equipped with at least one fan, and each fan is installed in the air passage stuffy channels of one pair of heat exchangers. 8. The method of air cooling of the frequency converter according to claim 7, characterized in that the productivity of the fans is controlled by means of an automated control system depending on the temperature value inside the sealed compartment. 9. The method of air cooling of a frequency converter according to claim 7, characterized in that the air humidity inside the sealed compartment is monitored and the air is dehumidified by additional heating until moisture is released on thermoelectric devices installed in the air ducts, followed by moisture removal outside the housing without breaking its tightness. 10. The method of air cooling of the frequency converter according to claim 7, characterized in that the control unit, enclosed in a separate trapezoidal housing, is installed within the air channel between the modules of the sealed compartment, providing cooling of the electronic components installed on its walls by means of three-sided blowing.

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