KR102133968B1 - Method and device of controlling power in space electrical equipment - Google Patents

Abstract

Disclosed is a power control device and method for a space-based electrical and electronic device. According to an embodiment of the present invention, a power control device in a space electrical and electronic device includes a priority part (P) and a surplus part (R), and power in a space electrical and electronic device that provides a thermistor bias power source. The control device includes a first serial diode provided on the first CMD line for turning on the relay in the priority part P, and a second serial provided on a second CMD line for turning off the relay in the surplus part R. By connecting the diode and the first CMD line and the second CMD line in parallel, while an effective signal is input to the first CMD line via the first serial diode, via the second serial diode It may include a controller for inputting a valid signal to the second CMD line.

Description

METHOD AND DEVICE OF CONTROLLING POWER IN SPACE ELECTRICAL EQUIPMENT}

The present invention is applicable to electric and electronic devices that operate to prohibit hot redundant operations in electric and electronic devices that provide redundancy for space, and power control devices for electric and electronic devices for space and It's about how.

Space electrical and electronic devices provide redundancy to ensure stable operation during the life of a mission even if a failure occurs.

The definition of redundancy is defined as preparing a plurality of systems for all or part of the components related to the function so that the function of the electrical and electronic device is not completely lost even if a part of the electrical and electronic device fails due to some reason. can do. Multiple systems must be independent of each other, and even if one system fails, the other system should operate normally to maintain redundancy.

The plurality of systems may be divided into a primary part and a redundant part, and may support hot redundancy operation of simultaneously turning on the priority part P and the redundant part R. Depending on whether it is stressed or not, it is possible to support the cold redundancy operation in which only the priority P is always ON (only the surplus R is turned ON when the priority P is abnormal).

1 is a diagram illustrating a conventional analog information power supply structure for preventing errors due to cross acceptance.

In the power supply structure of FIG. 1, cross-strapping is supported in which the powers of the priority units P and CSTA A and the surplus units R and CSTA B are exchanged by a relay.

Based on CSTA A, in the cross-receipt, the internal power is always applied, whereas the external power may be selectively applied according to the operating method.

For example, the internal power generated by the internal voltage regulator is always applied to the relay for cross-reception, while the external power generated by the external voltage regulator can be selectively applied to the relay.

Here, the optional is, when the hot redundancy is operated, it is connected to the internal voltage regulator of CSTA B, and the power of the external voltage regulator of CSTA A is applied to the relay (CSTA A and CSTA B are turned on simultaneously), or the cold redundancy operation date At this time, it may mean that the power of the external voltage regulator of CSTA A is not applied to the relay (only CSTA B is ON).

In the power structure shown in FIG. 1, in order to drive the relay of CSTA A to ON, the internal voltage regulator and the external voltage regulator must simultaneously generate an output. At this time, due to the stress between the two regulators, the internal voltage of CSTA B Power may be generated from the regulator, and the relay of the CSTA B may also be turned on.

2 is a view showing in detail the relay structure.

FIG. 2 is an enlarged view of a relay including a regulator in a solid line in FIG. 1.

Under the premise that the CSTA A operates ON, the output is generated from the A regulator and the output is not generated from the B regulator, so that cold redundancy operation can be performed.

If the A regulator and the B regulator generate output simultaneously, stress can be generated between the A regulator and the B regulator, so both CSTA A and CSTA B can operate simultaneously.

In order to prohibit the structure that is both ON, a separate protection circuit is required, but the construction of the protection circuit can cause many problems in terms of cost and space utilization.

Accordingly, there is a need for a technique for exclusive ON that limits hot redundancy operation in which CSTA A and CSTA B are ON simultaneously without building a separate protection circuit.

According to an embodiment of the present invention, a hot redundant operation in which the relay of the priority portion P and the relay of the surplus portion R in the space electric and electronic device operate simultaneously at the same time can be prohibited, through a simple structural change, It is an object of the present invention to provide a power control device and method in an electric and electronic device for space use.

In addition, in another embodiment of the present invention, when either the relay of the priority unit P or the relay of the surplus unit R operates as ON, the other relay is operated as OFF to achieve Exclusive ON, Another object is to provide a power supply control device and method in a space electric and electronic device.

According to an embodiment of the present invention, a power control device in a space electrical and electronic device includes a priority part (P) and a surplus part (R), and power in a space electrical and electronic device that provides a thermistor bias power source. The control device includes a first serial diode provided on the first CMD line for turning on the relay in the priority part P, and a second serial provided on a second CMD line for turning off the relay in the surplus part R. By connecting the diode and the first CMD line and the second CMD line in parallel, while an effective signal is input to the first CMD line via the first serial diode, via the second serial diode It may include a controller for inputting a valid signal to the second CMD line.

In addition, a method for controlling power in an electric and electronic device for space according to an embodiment of the present invention includes providing a first serial diode in a first CMD line for turning on a relay in a priority P, a second serial Providing a diode in a second CMD line for turning off the relay in the surplus portion (R), and in the controller, by connecting the first CMD line and the second CMD line in parallel, the first serial diode And inputting a valid signal to the second CMD line via the second serial diode while a valid signal is input to the first CMD line via.

According to an embodiment of the present invention, a hot redundant operation in which a relay of a priority portion (P) and a relay of a surplus portion (R) in an electric and electronic device for space operation are simultaneously ON can be prohibited. It is possible to provide a power control device and method in an electric and electronic device for space.

In addition, according to an embodiment of the present invention, when any one of the relay of the priority unit P and the relay of the surplus unit R operates as ON, the other relay is operated as OFF to achieve Exclusive ON. , It is possible to provide a power control device and method in the space electrical and electronic devices.

1 is a diagram illustrating a conventional analog information power supply structure for preventing errors due to cross acceptance.
2 is a view showing in detail the relay structure.
3 is a block diagram showing an internal configuration of a power control device in a space-based electric and electronic device according to an embodiment of the present invention.
4 is a diagram for explaining a circuit for implementing Exclusive ON using a parallel command, according to an embodiment of the present invention.
5 is a diagram illustrating a circuit for implementing Exclusive ON using PMOS according to the present invention.
6 is a view for explaining a structure using a two pole relay in parallel, according to an embodiment of the present invention.
7 is a view for explaining a structure using a 3 pole relay, according to an embodiment of the present invention.
8 is a flowchart illustrating a procedure of a power control method in an electric and electronic device for space according to an embodiment of the present invention.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. However, various changes may be made to the embodiments, and the scope of the patent application right is not limited or limited by these embodiments. It should be understood that all modifications, equivalents, or substitutes for the embodiments are included in the scope of rights.

The terms used in the examples are used for illustrative purposes only and should not be construed as limiting. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this specification, the terms "include" or "have" are intended to indicate the presence of features, numbers, steps, actions, components, parts or combinations thereof described in the specification, one or more other features. It should be understood that the existence or addition possibilities of fields or numbers, steps, operations, components, parts or combinations thereof are not excluded in advance.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person skilled in the art to which the embodiment belongs. Terms, such as those defined in a commonly used dictionary, should be interpreted as having meanings consistent with meanings in the context of related technologies, and should not be interpreted as ideal or excessively formal meanings unless explicitly defined in the present application. Does not.

In addition, in the description with reference to the accompanying drawings, the same reference numerals are assigned to the same components regardless of reference numerals, and redundant descriptions thereof will be omitted. In describing the embodiments, when it is determined that detailed descriptions of related known technologies may unnecessarily obscure the subject matter of the embodiments, the detailed descriptions will be omitted.

3 is a block diagram showing an internal configuration of a power control device in an electric and electronic device for space according to an embodiment of the present invention.

Referring to FIG. 3, according to an embodiment of the present invention, the power control device 300 (hereinafter abbreviated as “power control device”) in the electric/electronic device for spaces includes the first serial diode 310, It may be configured to include a second serial diode 320, and the controller 330. Further, according to an embodiment, the power control device 300 may be configured by selectively adding an OR gate 340, a PMOS 350, a 2-pole relay 360, and a 3-pole relay 370.

First, the first serial diode 310 is provided in the first CMD line for ON of the relay in the priority P. Here, the priority unit P is a system for providing a thermistor bias power supply included in a space electrical and electronic device, and may be a system that preferentially operates on according to cold redundancy operation.

In addition, the first CMD line may be a line formed for the purpose of transmitting a command to the relay of the priority P, and may refer to a CMD line for ON operation of the CSTA A, which is the priority P. For reference, the second CMD line, which will be described later, is for the OFF operation of the CSTA B, which is the surplus portion R, and the third CMD line is defined for the OFF operation of the CSTA A, which is the priority portion P.

That is, the first serial diode 310 may refer to a plurality of diodes connected in an array form mounted on the first CMD line for ON operation of the CSTA A, which is the priority P.

In addition, the second serial diode 320 is provided on the second CMD line for OFF of the relay in the surplus portion R.

The surplus portion R is also a system that provides a thermistor bias power source, and may be included in the electric and electronic device for space by pairing with the priority portion P.

That is, the second serial diode 320 may refer to a plurality of diodes connected in an array form mounted on the second CMD line for the OFF operation of the CSTA B, which is the surplus portion R.

According to an embodiment, when an oscillation signal is simultaneously inputted from the voltage regulator of the priority part P and the voltage regulator of the surplus part R, the second serial diode 320, the voltage regulator of the surplus part R By passing the oscillation signal of as an effective signal input to the second CMD line, the surplus portion R is kept inactive while the priority portion P is activated.

That is, when a situation in which the priority portion P and the excess portion R are simultaneously turned on, the second serial diode 320 transmits an effective signal for turning off the excess portion R to the second CMD line. , While the priority portion P is ON, the excess portion R is induced to be at least OFF to avoid hot redundancy operation.

The controller 330 connects the first CMD line and the second CMD line in parallel. That is, the controller 330 inputs the valid signal to the second CMD line via the second serial diode 320 while the valid signal is input to the first CMD line via the first serial diode 310. can do.

Through this, the controller 330 can implement the activation of the priority part P by the first CMD line and the deactivation of the surplus part R by the second CMD line, so that the priority part P and the excess It is possible to avoid hot redundancy operation in which whether or not (R) operates simultaneously.

The structure of the controller 330 will be described in more detail in FIG. 4.

4 is a diagram for explaining a circuit for implementing Exclusive ON using a parallel command, according to an embodiment of the present invention.

As shown in FIG. 4, the circuit 400 includes an A relay 442 configured in connection with the A Regulator 440 and a B relay 452 configured in connection with the B Regulator 450.

The first CMD line 444 connecting the ON terminal of the A relay 442 and the second CMD line 454 connecting the OFF terminal of the B relay 452 are connected in parallel by the controller 430. It is done. Each of the first CMD line 444 and the second CMD line 454 is equipped with a first serial diode 410 and a second serial diode 420 that rectify an effective signal in one direction.

According to the cold redundancy operation, if only the A relay 442 is to be operated, a valid signal regarding an ON command may be transmitted to the first CMD line 444 on which the first serial diode 410 is mounted. The valid signal regarding the OFF command may be transmitted to the second CMD line 454 where the 2 serial diodes 420 are mounted.

That is, the controller 430 connects the first CMD line 444 for ON and the second CMD line 454 for OFF in parallel to activate the A relay 442 and deactivate the B relay 452. Can be achieved at the same time.

Therefore, according to the circuit structure as shown in FIG. 4, when the command to turn on the A relay 442 is transmitted, the parallel connection enables the realization of the A relay 442 and the B relay 452 at the same time. Exclusive ON can be achieved.

In addition, the pulse CMD that turns off the relay is input to each relay by the diode OR structure 460, so that individual relays can be turned off independently.

The diode OR structure 460 receives CSTA A OFF and CSTA B ON in parallel at the A relay 442 side, and also receives CSTA A ON and CSTA B OFF in parallel at the B relay 452 side, from either As the OFF signal is input, the related relay can be turned OFF.

According to an embodiment, the power control device 300 of the present invention can ensure the cold redundancy operation by operating the relay of the priority unit P to OFF in consideration of the ON operation in the surplus unit R.

To this end, the power control device 300 may be configured to further include an OR gate 340.

The OR gate 340 may be a logic circuit that connects the voltage regulator of the surplus portion R to a first port and a third CMD line for turning off the relay in the priority portion P to a second port. have.

Through this, when the oscillation signal is input from the voltage regulator of the surplus portion R or the valid signal is input to the third CMD line, the OR gate 340 may turn off the relay in the priority portion P. have.

That is, when the relay of the priority unit P is in the ON state and the output of the voltage regulator of the surplus unit R is generated, the OR gate 340 switches the relay of the priority unit P to the OFF state. It is possible to avoid hot redundancy operation in which the relay of the negative (P) and the relay of the redundant (R) are turned on at the same time.

In addition, the OR gate 340 switches the relay of the priority P to the OFF state when the relay of the priority P is in the ON state and no further output is generated from the voltage regulator of the priority P. can do.

According to an embodiment, the power control device 300 of the present invention may achieve Exclusive ON by using a P-channel metal oxide semiconductor (PMOS).

To this end, the power control device 300 may further include a PMOS 350.

The PMOS 350 is provided on the first CMD line, and connects the voltage regulator of the surplus portion R to a gate. That is, the PMOS 350 may be configured to increase the voltage of the gate as the output is generated by the voltage regulator of the surplus portion R.

Thereafter, as the voltage regulator of the surplus portion R operates, the controller 330 uses an oscillation signal from the voltage regulator of the surplus portion R while the surplus portion R is activated, The blocking voltage at the gate of the PMOS 350 may be increased to deactivate the priority P.

That is, when an output is generated from the voltage regulator of the surplus portion R to turn the relay of the surplus portion R to ON, the PMOS 350 changes the voltage of the gate connected to the voltage regulator of the surplus portion R. By increasing, the relay of the priority P can be switched to OFF or maintained.

In addition, in the power control device 300 of the present invention, as the voltage regulator of the surplus portion R to the gate of the PMOS 350 is connected, it is possible to perform the OFF of the surplus portion R at a desired time. have.

To this end, the second serial diode 320 is connected to a coil provided in the relay in the surplus portion R, so that when the valid signal is input, the relay in the surplus portion R is turned OFF to turn off the surplus portion R Can be disabled.

That is, the CMD line on which the second serial diode 320 is mounted is extended and connected to the coil in the relay of the surplus portion R, so that the CSTA B OFF command passes through the second serial diode 320 and the coil, Inactivation (OFF) of the surplus portion R may be induced.

Hereinafter, Exclusive ON by the PMOS 350 will be described in detail in FIG. 5.

5 is a diagram illustrating a circuit for implementing Exclusive ON using PMOS according to the present invention.

As shown in FIG. 5, the circuit 500 mounts the PMOS 510 in a path through which the pulse CMD is transmitted, and uses the PMOS 510 to control the transmission of the pulse CMD according to the power state. Can be implemented.

That is, the PMOS 510 is provided on the first CMD line 512 associated with CSTA A ON, and connects the B regulator 520 of the CSTA B, which is the surplus portion R, to the gate.

When the A relay 530 and the B relay 540 are OFF, the gate of the PMOS 510 maintains GND by a pull down resistor.

When GND is connected to the gate of the PMOS 510, since the PMOS 510 maintains the ON state, the pulse CMD can be normally transmitted to the individual relays. That is, the valid signal for turning ON the A relay 530 or turning the B relay 540 ON can be transmitted at any time when the gate of the PMOS 510 is GND.

Accordingly, either the A relay 530 or the B relay 540 is in a state that can be switched to ON.

When either the A relay 530 or the B relay 540 is turned on, the gate voltage of the relay increases because the output of the regulator connected to the ON relay is connected to the gate of the PMOS.

For example, when an output is generated from the B regulator 520 and the B relay 540 is turned on, the output of the B regulator 520 may be an input to the gate of the PMOS 510 connected to the A relay 530. Accordingly, as the voltage of the gate of the PMOS 510 increases, and the gate voltage becomes 5 V, the PMOS 510 may become OFF (OFF of A relay).

That is, when the B relay 540 is turned ON, since all paths are blocked by the PMOS 510, the Pulse CMD cannot be transmitted, and the A relay 530 is switched to OFF, thereby both relays All can be prevented from being turned on.

In addition, the OFF terminal of the relay is connected to the coil, so the relay can be OFF at any time. Accordingly, when the ON side of the relay is switched to OFF, since the gates of both sides of the PMOS are both GND, the relays on both sides can be switched to ON according to the command input.

According to an embodiment, the power supply control device 300 of the present invention can increase the gate voltage of the PMOS as necessary, thereby reliably turning off the PMOS.

To this end, the power control device 300 may be configured to further include a 2-pole relay 360 and a 3-pole relay 370.

First, the two-pole relay 360 is provided in parallel with the relay in the priority portion P, and the voltage regulator of the priority portion P can be selectively connected to the gate of the PMOS.

That is, the 2-pole relay 360 is a relay that is additionally installed in addition to the existing relay, for example, may be a means for selectively receiving and operating a voltage of 15V supplied to a voltage regulator.

The two-pole relay 360 further supplies an oscillation signal from the voltage regulator of the priority unit P to the gate of the PMOS while the surplus unit R is activated, so that the cutoff voltage is selected. The reference voltage can be exceeded.

That is, the 2-pole relay 360 adds to the voltage (5V) via the activated relay, and further supplies an additional voltage (15V) from the voltage regulator to the gate of the PMOS, so that the summed voltage (5+15V) is , It is possible to surely exceed the reference voltage (14V) for turning off the PMOS.

In one embodiment, the 2-pole relay 360 is supplied to the gate of the PMOS by supplying only the additional voltage (15V) from the voltage regulator to the gate of the PMOS, instead of the voltage (5V) via the relay being activated. It is possible to make the voltage at least higher than the reference voltage 14V.

6 is a view for explaining a structure using a 2 pole relay in parallel, according to an embodiment of the present invention.

As shown in FIG. 6, the circuit 600 can prevent both ON by using the PMOS 610 and a pull-down resistor.

Also, the PMOS 610 may be turned off only when the voltage of the gate node is less than the reference voltage Vth than the voltage of the source node.

In FIG. 6, while exemplifying the 2-pole relay 630 provided in parallel with the A relay, when an output is generated from the B regulator and the B relay 620 of the surplus portion R is turned on, the 2-pole relay 630 Through operation, it is exemplified that 15 V of the A regulator is supplied to the PMOS 610.

As the gate of the PMOS 610, there is an effect that the sum of the voltage of 5V from the activated B relay 620 and 15V from the 2-pole relay 630 is input, so that the PMOS 610 is turned off. The reference voltage is exceeded 14V, and the OFF of the PMOS 610 can be reliably guaranteed.

In another embodiment, instead of 5V from the activated B relay 620, only 15V from the 2-pole relay 630 is supplied to the gate of the PMOS 610 to become a gate voltage exceeding the reference voltage 14V. , The OFF of the PMOS 610 can be reliably guaranteed.

Through such a circuit structure, the power supply control device 300 of the present invention, when the relay of the surplus portion R is turned ON, turns off the PMOS of the priority portion P, so that the relay of the priority portion P is surely It is possible to keep OFF.

In addition, the 3-pole relay 370 is included in the relay in the priority unit P, and the voltage regulator of the priority unit P can be selectively connected to the gate of the PMOS.

That is, the 3-pole relay 370 further supplies an oscillation signal from the voltage regulator of the priority portion P to the gate of the PMOS while the surplus portion R is activated, so that the blocking voltage is selected. The reference voltage can be exceeded.

That is, the 3-pole relay 370 selectively supplies only the additional voltage (15V) from the voltage regulator to the gate of the PMOS, instead of the voltage (5V) via the activated relay, thereby inputting the voltage to the gate of the PMOS. It can be made at least higher than this reference voltage (14V).

7 is a view for explaining a structure using a 3 pole relay, according to an embodiment of the present invention.

As shown in FIG. 7, the circuit 700 can prevent both ON by using the PMOS 710 and a pull-down resistor.

Also, the PMOS 710 may be turned off only when the voltage of the gate node is less than the reference voltage Vth than the voltage of the source node.

In FIG. 7, while exemplifying a three-pole relay in which one pole is added to the existing two-pole relay, an output is generated from the B regulator, and when the B relay 720 of the surplus portion R is turned on, the three-pole relay 730 ), it is exemplified that 15V of A regulator is supplied to PMOS(710).

Instead of 5V from the activated B relay 720, only 15V from the 3-pole relay 730 is supplied to the gate of the PMOS 710 to become a gate voltage exceeding the reference voltage of 14V, and the PMOS 710 OFF can be guaranteed.

Through such a circuit structure, the power supply control device 300 of the present invention, when the relay of the surplus portion R is turned ON, turns off the PMOS of the priority portion P, so that the relay of the priority portion P is surely It is possible to keep OFF.

According to an embodiment of the present invention, a hot redundant operation in which a relay of a priority portion (P) and a relay of a surplus portion (R) in an electric and electronic device for space operation are simultaneously ON can be prohibited. It is possible to provide a power control device and method in an electric and electronic device for space.

In addition, according to an embodiment of the present invention, when any one of the relay of the priority unit P and the relay of the surplus unit R operates as ON, the other relay is operated as OFF to achieve Exclusive ON. , It is possible to provide a power supply control device and method in the space electrical and electronic devices.

Hereinafter, the operation flow of the power control device 300 according to embodiments of the present invention will be described in detail in FIG. 8.

8 is a flowchart illustrating a procedure of a power control method in an electric and electronic device for space according to an embodiment of the present invention.

The power control method in the electric/electronic device for space according to the present embodiment may be performed by the power control device 300 described above.

First, the power control device 300 includes a first serial diode in the first CMD line for turning on the relay in the priority P (810). Here, the priority unit P is a system for providing a thermistor bias power supply included in a space electrical and electronic device, and may be a system that preferentially operates on according to cold redundancy operation.

The first CMD line may be a circuit formed for the purpose of transmitting a command to the relay of the priority P, and may refer to a CMD line for ON operation of CSTA A, which is the priority P. In addition, the second CMD line is defined for the OFF operation of CSTA B, which is the surplus portion R, and the third CMD line is defined for the OFF operation of CSTA A, which is the priority portion P.

The first serial diode may refer to a plurality of diodes connected in an array form, mounted on the first CMD line for ON operation of the CSTA A, which is the priority P.

In addition, the power control device 300 includes a second serial diode in the second CMD line for OFF of the relay in the surplus portion R (820).

The surplus portion R is also a system that provides a thermistor bias power source, and may be included in the electric and electronic device for space by pairing with the priority portion P.

The second serial diode may refer to a plurality of diodes connected in an array form, mounted on the second CMD line for the OFF operation of the CSTA B, which is the surplus portion R.

According to an embodiment, when an oscillation signal is simultaneously inputted from the voltage regulator of the priority part P and the voltage regulator of the surplus part R, the second serial diode oscillates the voltage regulator of the surplus part R. By passing as a valid signal input to the second CMD line, the surplus portion R is kept inactive while the priority portion P is activated.

That is, when a situation occurs in which the priority portion P and the excess portion R are simultaneously turned on, the second serial diode transmits an effective signal to turn off the excess portion R to the second CMD line, thereby giving priority to the second serial diode. While (P) is ON, the excess portion (R) is induced to be at least OFF to avoid hot redundancy operation.

In addition, the power control device 300 connects the first CMD line and the second CMD line in parallel (830). Step 830 may be a process of inputting a valid signal to the second CMD line via a second serial diode while a valid signal is input to the first CMD line via a first serial diode.

Through this, the power control device 300 can implement the activation of the priority part P by the first CMD line and the deactivation of the surplus part R by the second CMD line, thereby providing the priority part P It is possible to avoid hot redundancy operation in which the and the surplus portion R operate simultaneously.

According to an embodiment, the power control device 300 of the present invention can ensure the cold redundancy operation by operating the relay of the priority unit P to OFF in consideration of the ON operation in the surplus unit R.

To this end, the power control device 300 may be configured to further include an OR gate.

The OR gate may be a logic circuit that connects the voltage regulator of the surplus portion R to a first port and a third CMD line for turning off the relay in the priority portion P to a second port.

Through this, when the oscillation signal is input from the voltage regulator of the surplus portion R or the valid signal is input to the third CMD line, the relay in the priority portion P can be turned OFF.

That is, when the relay of the priority section P is in the ON state and the output of the voltage regulator of the surplus section R is generated, the OR gate switches the priority section P to the OFF state, thereby switching the priority section P to the priority section P. ) And the redundancy (R) relay can be avoided by operating hot redundancy.

In addition, the OR gate can switch the relay of the priority P to the OFF state when the relay of the priority P is in the ON state and no further output is generated from the voltage regulator of the priority P. .

According to an embodiment, the power control device 300 of the present invention may achieve Exclusive ON by using a P-channel metal oxide semiconductor (PMOS).

To this end, the power control device 300 may further include a PMOS.

A PMOS is provided on the first CMD line, and connects the voltage regulator of the surplus portion R to a gate. That is, the PMOS may be configured to increase the voltage of the gate as the output is generated by the voltage regulator of the surplus portion R.

Thereafter, the power control device 300 uses the oscillation signal from the voltage regulator of the surplus portion R while the surplus portion R is activated, as the voltage regulator of the surplus portion R operates. Thus, the blocking voltage at the gate of the PMOS can be increased to deactivate the priority P.

That is, when an output is generated from the voltage regulator of the redundant portion R in order to switch the relay of the redundant portion R to ON, the PMOS increases the voltage of the gate connected to the voltage regulator of the redundant portion R, The relay of the priority portion P can be switched to OFF or maintained.

In addition, in the power supply control device 300 of the present invention, as the voltage regulator of the surplus portion R to the gate of the PMOS is connected, OFF of the surplus portion R can be performed at a desired time.

To this end, the second serial diode is connected to a coil provided in the relay in the surplus portion R to deactivate the surplus portion R by turning off the relay in the surplus portion R when an effective signal is input. Can.

That is, the CMD line on which the second serial diode is mounted is extended and connected to the coil in the relay of the surplus portion R, so that the CSTA B OFF command is passed through the second serial diode and the coil, so that the surplus portion R Deactivation (OFF) can be induced.

According to an embodiment, the power supply control device 300 of the present invention can increase the gate voltage of the PMOS as necessary, thereby reliably turning off the PMOS.

To this end, the power control device 300 may further include a 2-pole relay.

First, the 2-pole relay is provided in parallel with the relay in the priority section P, and the voltage regulator of the priority section P can be selectively connected to the gate of the PMOS.

That is, the 2-pole relay is a relay that is additionally installed in addition to the existing relay, and may be, for example, a means for selectively receiving and operating a voltage of 15V supplied to a voltage regulator.

The two-pole relay further supplies an oscillation signal from the voltage regulator of the priority unit P to the gate of the PMOS while the surplus unit R is activated, so that the cutoff voltage is the selected reference voltage. Can be exceeded.

That is, the 2-pole relay adds to the voltage (5V) via the activated relay, and further supplies an additional voltage (15V) from the voltage regulator to the gate of the PMOS, so that the summed voltage (5+15V) adds the PMOS. It is possible to reliably exceed the reference voltage (14V) for OFF.

In one embodiment, the 2-pole relay replaces the voltage (5V) via the activated relay and supplies only the additional voltage (15V) from the voltage regulator to the gate of the PMOS, so that the voltage input to the gate of the PMOS is referenced. It can be made at least higher than the voltage 14V.

In another embodiment, the power control device 300 may further include a 3-pole relay.

A 3-pole relay is included in the relay in the priority P, and a voltage regulator of the priority P can be selectively connected to the gate of the PMOS.

That is, the three-pole relay further supplies an oscillation signal from the voltage regulator of the priority unit P to the gate of the PMOS while the surplus unit R is activated, so that the cutoff voltage is the selected reference voltage. Can be exceeded.

That is, the 3-pole relay replaces the voltage (5V) via the activated relay and selectively supplies only the additional voltage (15V) from the voltage regulator to the gate of the PMOS, so that the voltage input to the gate of the PMOS is the reference voltage. It can be made at least higher than (14V).

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According to an embodiment of the present invention, a hot redundant operation in which a relay of a priority portion (P) and a relay of a surplus portion (R) in an electric and electronic device for space operation are simultaneously ON can be prohibited. It is possible to provide a power control device and method in an electric and electronic device for space.

In addition, according to an embodiment of the present invention, when any one of the relay of the priority unit P and the relay of the surplus unit R operates as ON, the other relay is operated as OFF to achieve Exclusive ON. , It is possible to provide a power supply control device and method in the space electrical and electronic devices.

The method according to the embodiment may be implemented in the form of program instructions that can be executed through various computer means and recorded on a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, or the like alone or in combination. The program instructions recorded on the medium may be specially designed and constructed for the embodiments or may be known and usable by those skilled in computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical media such as CD-ROMs, DVDs, and magnetic media such as floptical disks. -Hardware devices specifically configured to store and execute program instructions such as magneto-optical media, and ROM, RAM, flash memory, and the like. Examples of program instructions include high-level language code that can be executed by a computer using an interpreter, etc., as well as machine language codes made by a compiler. The hardware device described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

The software may include a computer program, code, instruction, or a combination of one or more of these, and configure the processing device to operate as desired, or process independently or collectively You can command the device. Software and/or data may be interpreted by a processing device or to provide instructions or data to a processing device, of any type of machine, component, physical device, virtual equipment, computer storage medium or device. , Or may be permanently or temporarily embodied in the transmitted signal wave. The software may be distributed on networked computer systems, and stored or executed in a distributed manner. Software and data may be stored in one or more computer-readable recording media.

As described above, although the embodiments have been described by the limited drawings, those skilled in the art can apply various technical modifications and variations based on the above. For example, the described techniques are performed in a different order than the described method, and/or the components of the described system, structure, device, circuit, etc. are combined or combined in a different form from the described method, or other components Alternatively, even if replaced or substituted by equivalents, appropriate results can be achieved.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

300: power control device in the space electronics
310: first serial diode 310 320: second serial diode
330: controller 340: OR gate
350: PMOS 360: 2-pole relay
370: 3-pole relay

Claims (14)

In the power control device in a space electrical and electronic device for providing a thermistor bias power supply, including a priority portion (P) and a surplus portion (R),
A first serial diode provided in a first CMD line for turning on the relay in the priority section (P);
A second serial diode provided on a second CMD line for OFF of the relay in the excess portion (R);
By connecting the first CMD line and the second CMD line in parallel, while the valid signal is input to the first CMD line via the first serial diode, the second CMD line is passed through the second serial diode. A controller that inputs a valid signal to the CMD line; And
A PMOS provided in the first CMD line and connecting a voltage regulator of the surplus portion R to a gate;
Including,
The controller,
As the voltage regulator of the surplus portion R operates, while the surplus portion R is activated,
Using the oscillation signal from the voltage regulator of the surplus portion R, the blocking voltage at the gate of the PMOS is increased to deactivate the priority portion P
Power control device in space electrical and electronic equipment. According to claim 1,
The power control device in the electric and electronic device for space,
OR gate connecting the voltage regulator of the surplus part (R) to the first port, and connecting the third CMD line for the OFF of the relay in the priority part (P) to the second port
Further comprising,
The OR gate,
When an oscillation signal is input from the voltage regulator of the surplus portion R or an effective signal is input to the third CMD line, the relay in the priority portion P is turned off.
Power control device in space electrical and electronic equipment. delete According to claim 1,
As the voltage regulator of the surplus portion R to the gate of the PMOS is connected,
The second serial diode,
By connecting to the coil provided in the relay in the surplus portion (R), when the valid signal is input, the relay in the surplus portion (R) is turned OFF to deactivate the surplus portion (R)
Power control device in space electrical and electronic equipment. According to claim 1,
The power control device in the electric and electronic device for space,
A two-pole relay that is provided in parallel with the relay in the priority P, and selectively connects the voltage regulator of the priority P to the gate of the PMOS.
Further comprising,
The 2-pole relay,
While the surplus portion R is activated,
The oscillation signal from the voltage regulator of the priority portion P is further supplied to the gate of the PMOS so that the cut-off voltage exceeds the predetermined reference voltage.
Power control device in space electrical and electronic equipment. According to claim 1,
The power control device in the electric and electronic device for space,
A three-pole relay that is included in the relay in the priority unit P and selectively connects the voltage regulator of the priority unit P to the gate of the PMOS.
Further comprising,
The three pole relay,
While the surplus portion R is activated,
The oscillation signal from the voltage regulator of the priority P is further supplied to the gate of the PMOS so that the cut-off voltage exceeds the predetermined reference voltage.
Power control device in space electrical and electronic equipment. According to claim 1,
When the oscillation signal is simultaneously input from the voltage regulator of the priority part P and the voltage regulator of the surplus part R,
The second serial diode,
The oscillation signal of the voltage regulator of the surplus portion R is passed as an effective signal input to the second CMD line, so that the surplus portion R is kept inactive while the priority portion P is activated.
Power control device in space electrical and electronic equipment. Providing a first serial diode in the first CMD line for turning on the relay in the priority section (P);
Providing a second serial diode on the second CMD line for OFF of the relay in the redundant portion (R);
In a controller, by connecting the first CMD line and the second CMD line in parallel, while an effective signal is input to the first CMD line via the first serial diode, via the second serial diode Inputting a valid signal to the second CMD line;
Connecting a voltage regulator of the excess part (R) to a gate of a PMOS provided in the first CMD line; And
As the voltage regulator of the surplus portion R operates, while the surplus portion R is activated,
In the controller, using the oscillation signal from the voltage regulator of the surplus portion (R), increasing the cut-off voltage at the gate of the PMOS, thereby deactivating the priority portion (P)
Power control method in a space electrical and electronic device comprising a. The method of claim 8,
Connecting a voltage regulator of the surplus portion (R) to the first port of the OR gate;
Connecting a third CMD line for OFF of the relay in the priority portion (P) to the second port of the OR gate; And
When an oscillation signal is input from the voltage regulator of the surplus portion R, or when an effective signal is input to the third CMD line,
In the OR gate, turning off the relay in the priority part (P).
Power control method in a space electric and electronic device further comprising a. delete The method of claim 8,
As the voltage regulator of the surplus portion R to the gate of the PMOS is connected,
Deactivating the redundant portion (R) by turning off the relay in the redundant portion (R) when inputting a valid signal by connecting the second serial diode to a coil provided in the relay in the redundant portion (R)
Power control method in a space electric and electronic device further comprising a. The method of claim 8,
Selectively providing a voltage regulator of the priority unit (P) to the gate of the PMOS by providing a two-pole relay in parallel with the relay in the priority unit (P); And
In the two-pole relay, while the surplus portion R is activated, the oscillation signal from the voltage regulator of the priority portion P is further supplied to the gate of the PMOS, so that the cutoff voltage is the selected reference voltage. Steps to exceed
Power control method in a space electrical and electronic device further comprising a. The method of claim 8,
Selectively providing a voltage regulator of the priority unit (P) to the gate of the PMOS by including a three-pole relay as a relay in the priority unit (P); And
In the three-pole relay, while the surplus portion R is activated, the oscillation signal from the voltage regulator of the priority portion P is further supplied to the gate of the PMOS, so that the cut-off voltage is the selected reference voltage. Steps to exceed
Power control method in a space electric and electronic device further comprising a. The method of claim 8,
When the oscillation signal is simultaneously input from the voltage regulator of the priority part P and the voltage regulator of the surplus part R,
In the second serial diode, while passing the oscillation signal of the voltage regulator of the surplus portion R as an effective signal input to the second CMD line, while the priority portion P is activated, the surplus portion ( Step to keep R) inactive
Power control method in a space electric and electronic device further comprising a.

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