KR101242748B1 - Checking system for rotor de-icing - Google Patents

Abstract

The present invention relates to a ground inspection system of a rotor ice making system for checking whether the rotor ice making system operates normally on the ground after mounting the rotor ice making system. And a check control unit which transmits the virtual operation signal and the virtual malfunction signal to the controller of the actual rotor ice making system and checks the operation state of the helicopter rotor ice making system on the ground.
In addition, the helicopter rotor ice making system check system according to the present invention is characterized in that it further comprises a rotor load for generating an operation signal and a failure signal of the virtual rotor blade heating mat.

Description

Helicopter rotor de-icing system

The present invention relates to a system for inspecting the ice making system of the helicopter rotor, and more particularly, to a ground inspection system of the rotor ice making system for checking whether the rotor ice making system operates normally on the ground after the rotor ice making system is installed.

In general, to check the helicopter rotor ice making system from the ground, using the test panel of the aircraft, only the system failure was confirmed.

However, the conventional method of checking the rotor ice making system has a problem in that it cannot confirm whether the development is completed according to the design requirements because only the failure of the system can be confirmed.

In addition, if the environmental factors for operating the equipment of the rotor ice making system is not satisfied, there is a problem that the operation of the rotor ice making system is impossible.

In addition, since the rotor ice system operates only when the blade rotates, the rotor ice machine does not operate when the blade is not rotated, and damage due to blade overheating may occur when the rotor ice system is operated through simulation of blade rotation and environmental conditions. There is concern.

The present invention has been proposed to solve the above conventional problems,

The purpose of the helicopter rotor ice making system inspection system according to the present invention is to transmit the heating mat virtual operation signal and virtual malfunction signal of the rotor blade to the controller of the rotor ice system, without being restricted by the inspection environment, the actual rotor ice system of the ground To check the function.

Another object is to provide a power supply for operating the rotor ice making system even when the blade non-rotating, further comprising a rotor load.

Still another object is to further include a rotor load, to generate an operation signal and a malfunction signal of the virtual rotor blade heating mat.

Still another object is to further include a control input unit for facilitating the setting of the control signals of the icing state and the malfunctioning state.

Still another object is to evaluate the state of the operation signal of the controller of the rotor ice-making system further comprising a check and evaluation unit.

Still another object is to further include a display unit to display the operation signal and the malfunction occurrence signal of the controller of the ice making system to the outside.

The helicopter rotor ice making system inspection system according to the present invention transmits a virtual rotor blade operation signal and a virtual abnormal control signal to a controller of an actual rotor ice making system, and includes an inspection control unit which checks the operation state of the helicopter rotor ice making system on the ground. Characterized in that.

In addition, the helicopter rotor ice making system inspection system according to the present invention is connected to the inspection control unit, characterized in that it further comprises a rotor load for generating an operation signal and a failure signal of the virtual rotor blade heating mat.

As described above, the helicopter rotor ice making system inspection system according to the present invention transmits the virtual operation signal and the virtual malfunction signal of the rotor blade heating mat to the controller of the rotor ice making system, thereby not being restricted by the inspection environment, and the actual rotor ice making. It is effective to check the function of the system on the ground.

In addition, by further comprising a rotor load, there is an effect that can supply power for operating the rotor ice making system even when the blade is not rotated.

In addition, by further comprising a rotor load, there is an effect that it is easy to generate an operation signal and a malfunction signal of the virtual rotor blade heating mat.

In addition, by further including a control input unit, there is an effect that it is easy to set the control signal of the icing state and malfunction condition.

In addition, by further including an inspection evaluation unit, there is an effect that can evaluate the state of the operation signal of the controller of the rotor ice making system.

In addition, the display unit may further include an operation signal and a malfunction occurrence signal of the controller of the ice making system.

1 is an overall configuration diagram of a helicopter rotor ice making system check system according to the present invention.
Figure 2 is a detailed configuration of the power supply unit of the helicopter rotor ice making system check system according to the present invention.
Figure 3 is a detailed configuration of the inspection control unit of the helicopter rotor ice making system inspection system according to the present invention.
Figure 4 is a detailed configuration of the environmental input unit of the helicopter rotor ice making system check system according to the present invention.
5 is a detailed configuration of the rotor blade power supply of the helicopter rotor ice making system check system according to the present invention.
Figure 6 is a detailed configuration of the rotor load of the helicopter rotor ice making system check system according to the present invention.
7 is a connection diagram of the helicopter rotor ice making system check system according to the present invention.
Figure 8 (a) and (b) is a view showing an embodiment of the inspection control unit and the rotor load of the helicopter rotor ice making system inspection system according to the present invention.

Hereinafter, a detailed description for implementing the helicopter rotor ice making system check system according to the present invention.

1 is a view showing the overall configuration of the helicopter rotor ice system check system according to the present invention, the power supply unit 10, the inspection control unit 20, the rotor ice system controller 30, the environmental input unit 40, the rotor It consists of a blade power supply 50, the rotor load 60.

The power supply unit 10 serves to supply power to the helicopter rotor ice making system check system, and as shown in FIG. 2, the control power supply 11, the load power supply 13, and the rotor ice making box are largely connected. It consists of 15 pieces.

The control power supply unit 11 supplies power to the inspection control unit 20 and the rotor ice making system, and the load power supply unit 13 supplies power to the rotor load unit 60 through the rotor ice making box 15. Play a role.

The power supply unit 10 according to the present invention may be selected from a power supply source of an aircraft, that is, an auxiliary power supply unit (APU-Auxiliary Power Unit), a ground power unit (GPU-Ground Power Unit) and a power generation power supply unit (GEN). Do.

The power supply unit 10 is not limited to the above configuration and may be diversified according to the power configuration.

The inspection control unit 20 is connected to the power supply unit 10, and transmits the virtual operation signal, the virtual malfunction signal, the freezing state signal and the temperature signal of the rotor blade heating mat to the rotor ice system controller 30, the helicopter rotor ice making Check the operation status of the system, and serves to display the operation signal and the malfunction occurrence signal of the ice-making system controller to the outside.

The inspection control unit 20 is composed of a control input unit 21, an inspection evaluation unit 23, and a display unit 25 as shown in FIG.

The control input unit 21 inputs the virtual operation signal, the virtual malfunction signal, the icing state signal, and the temperature signal of the rotor blade heating mat to the rotor ice making system controller 30, and the inspection evaluation unit 23 serves as a rotor. Evaluates the operation signal of the controller 30 of the actual rotor ice making system according to the virtual operation signal of the blade and the virtual malfunction signal, and the display unit 25 receives the operation signal and the malfunction occurrence signal of the rotor ice system 30 It serves to mark the outside.

The environment input unit 40 is connected to the check control unit 20, and serves to input the icing state signal and the temperature signal, as shown in FIG. 4, the icing detection unit 41, the icing rate display unit ( 43) and an external temperature input unit 45.

The freezing detection unit 41 detects freezing conditions in the air and transmits the detected freezing state signal to the freezing rate display unit 43, and the freezing rate display unit 43 is the freezing detection unit 41. It displays the freezing rate according to the freezing state signal received from the) and inputs the freezing state signal to the inspection control unit 20.

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The external temperature input unit 45 serves to input a temperature signal detected from an external temperature sensor or other equipment to the check controller 20.

The environment input unit 40 is not limited to the above configuration, and it is preferable to input various control signals according to the inspection purpose, and the freezing state signal and temperature transmitted to the inspection control unit 20 through the environment input unit 40. The signal is transmitted to the rotor ice system controller 30 in the form of analog data.

The rotor blade power supply unit 50 controls the load power of the rotor ice making connection box 15 according to an operation signal of the rotor ice system controller 30 or a control signal of the inspection control unit 20. And serves to supply power, and as shown in FIG. 5, the main rotor blade power supply 51, a power distribution device 53, and a tail rotor blade power supply 55 are included.

The main rotor blade power supply unit 51 serves to transfer the load power to be provided to the main rotor blade mechanically or electrically to the power distribution device 53.

The power distribution device 53 distributes power supplied to the main rotor blade according to a signal input through the main rotor blade power supply 51.

The tail rotor blade power supply unit 55 directly supplies load power to the tail rotor blades without a power distribution device.

The rotor blade power supply unit 50 is not limited to the above configuration, the power distribution device may be added or removed depending on the power supply method.

The rotor load unit 60 is connected to the rotor blade power supply unit 50 to generate a virtual operation signal of the rotor blade heating mat transmitted to the rotor ice making system controller 30, and generates a virtual malfunction signal. It serves to display the operation and malfunction of the rotor blade heating mat, and as shown in Figure 6, the main rotor / tail rotor blade load generator 61, malfunction input unit 63 and rotor blade heating mat operation indicator (65).

The main rotor / tail rotor blade load generator 61 has a virtual voltage equal to an operation signal of an actual rotor blade heating mat according to a control signal of the check controller 20 transmitted through the rotor blade power supply 50. It serves to generate the current value load.

The malfunction input unit 63 simulates a step-by-step failure of the heating mat of the main rotor / tail rotor blade through the main rotor / tail rotor blade load generation unit 61 as a virtual voltage / current value. The rotor blade heating mat operation indicator 65 functions to demonstrate the operation of the main rotor / tail rotor blade load generator 61.

The inspection control unit 20 transmits a signal input from the rotor load unit 60 and the environment input unit 40 to the rotor ice controller 30, and the rotor ice controller according to the freezing state signal and the temperature signal ( The operation signal of 30) can be checked.

More specifically, the inspection control unit 20 according to the present invention is a virtual operation signal or a virtual malfunction signal of the rotor blade heating mat generated through the rotor load unit 60, that is, the main rotor blade and the tail rotor blade heating mat. By transmitting a voltage / current value to the rotor ice making system controller 30, the operation signal of the rotor ice making system controller 30 can be checked.

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In addition, the inspection control unit 20 displays a FAIL Lamp on the aircraft when a malfunction of the rotor ice system controller 30 occurs.

The inspection evaluator 23 evaluates the operation signal of the controller 30 of the actual rotor ice making system according to the virtual operation signal of the rotor blade heating mat and the virtual malfunction signal input to the inspection control unit 20.

As described above, the helicopter rotor ice making system inspection system according to the present invention transmits the virtual rotor blade operation signal and the virtual abnormal control signal to the controller of the rotor ice making system, thereby not restricting the inspection environment, In the absence of rotation, the function of the actual rotor ice system can be checked in advance on the ground.

Although the embodiments of the present invention have been described above, the technical idea of the present invention is not limited to the above embodiments, and various helicopter rotor ice-making system inspection systems may be implemented in a range not departing from the technical idea of the present invention.

10: power supply unit 11: control power supply unit
13 load power supply 15 rotor deicing junction box
20: check control unit 21: control input unit
23: inspection evaluation unit 25: display unit
30: rotor ice system controller 40: environmental input unit
41: freezing detection unit 43: freezing rate display unit
45: external temperature input unit 50: rotor blade power supply
51: main rotor blade power supply
53: power distribution device
55: tail rotor blade power supply
60: rotor load portion 61: rotor blade load generation portion
63: malfunction input unit
65: rotor blade heating mat operation display

Claims (8)

A rotor load for generating a virtual motion signal and a virtual failure signal of the rotor blade heating mat;
And a check control unit which transmits the virtual operation signal and the virtual malfunction signal to an actual rotor ice system controller and checks the operation state of the helicopter rotor ice system on the ground.
The inspection control unit,
Helicopter rotor ice system check system comprising a check evaluation unit for evaluating the operation signal of the controller of the actual rotor ice system according to the virtual operation signal and the virtual failure signal of the rotor blade heating mat. delete The method of claim 1,
The rotor load portion,
A malfunction input unit for inputting a current / voltage value of each rotor blade heating mat as a malfunction signal;
A rotor blade load generation unit connected to the malfunction input unit to generate a virtual operation signal and a malfunction signal of a main rotor blade and a tail rotor blade heating mat as a load of a current / voltage value;
And a rotor blade heating mat operation indicator connected to the load generator to display a virtual operation signal of each heating mat of the main rotor blade and the tail rotor blade. The method of claim 3,
Is connected to the rotor blade load generation unit, further comprising a rotor blade power supply, the rotor blade power supply unit
A main rotor blade power supply for supplying power for driving the main rotor;
Helicopter rotor ice making system check system comprising a tail rotor blade power supply for supplying power for driving the tail rotor. The method of claim 1,
It is connected to the inspection control unit, and further comprises an environment input unit for inputting a freezing state signal and a temperature signal,
The environment input unit,
An ice detection unit for detecting an ice state in the air;
A freezing rate display unit connected to the freezing detection unit to display a freezing rate according to the freezing state signal detected by the freezing detection unit, and to transmit the freezing rate to the inspection control unit;
And an external temperature input unit configured to input a temperature signal detected by an external temperature sensor to the inspection control unit. delete delete The method of claim 1,
The inspection control unit,
Helicopter rotor ice system check system further comprises a display unit for displaying the virtual operation signal and the virtual failure signal (fail) of the rotor blade heating mat to the outside.

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