KR102199552B1 - Power supply device to lnb - Google Patents

Abstract

The present invention relates to an LNB power supply for stably supplying power to the LNB, comprising a plurality of power outputs supplying power to at least one low noise block down converter (LNB), and the plurality of power outputs is a load It is possible to simultaneously supply power to the LNB above the threshold load.

Description

LNB power supply {POWER SUPPLY DEVICE TO LNB}

The present invention relates to an LNB power supply.

Satellite antennas refer to antennas for receiving radio waves from satellites. Parabolic antennas are mainly used as satellite antennas.

On the other hand, satellites send radio waves at about 10 to 13 GHz, while tuners can process signals with frequencies around 1 to 2 GHz. Therefore, a satellite antenna needs equipment that converts an RF signal received from a satellite into an IF signal that can be processed by a tuner.

LNB (Low Noise Block down converter) is a device that is installed on a satellite antenna and receives radio waves. LNB can also amplify weak satellite signals with low noise.

In order for the LNB to operate, power must be supplied from the outside, and a receiver device (eg, TV, set-top box, etc.) can supply power to the LNB. The receiver may include a tuner that receives an RF signal from the LNB and a power output that supplies power to the LNB. In addition, the LNB is generally installed in an outdoor space such as a roof, and the receiver is generally installed in an indoor space.

On the other hand, the LNB may increase the current load when the received radio wave is weak or the difference in ground (GND) from the receiver device is large. In addition, when the current load of the LNB increases, the load of the power output unit that supplies power to the LNB also increases, and when the load of the power output unit continues to increase, phenomena such as overheating or damage may occur in the power output unit. Accordingly, problems such as low reliability of the LNB or not supplying power to the LNB occur.

Therefore, even if the current load of the LNB increases, a method of stably supplying power to the LNB is required.

The present invention is to provide an LNB power supply device capable of stably supplying power to the LNB.

An object of the present invention is to provide an LNB power supply that prevents interference of RF signals received by other LNBs when receiving an RF signal through one LNB.

An LNB power supply device according to an embodiment of the present invention includes a plurality of power outputs supplying power to at least one LNB (Low Noise Block down converter), and the plurality of power outputs simultaneously powers an LNB having a load greater than or equal to a threshold load. Can supply.

Among the plurality of power output units, the first power output unit supplies power to the first LNB, and the second power output unit of the plurality of power output units is supplying power to the first LNB, and the load of the first LNB When is greater than or equal to the threshold load, power may be supplied to the first LNB.

The LNB power supply further includes a first current sensing unit that senses a current supplied to the first LNB, and the second power output unit powers the first LNB when the first current value detected by the first current sensing unit is greater than or equal to a set value. Can supply.

When the second power output unit supplies power to the first LNB, the LNB power supply may further include a second power cut-off unit configured to block power supply to the second LNB.

The second power output of the plurality of power outputs supplies power to the second LNB, the first power output of the plurality of power outputs is the second power output is supplying power to the second LNB, and the load of the second LNB When is greater than or equal to the threshold load, power may be supplied to the second LNB.

The LNB power supply further includes a second current sensing unit for sensing a current supplied to the second LNB, and the first power output unit powers the second LNB when the second current value detected by the second current sensing unit is greater than or equal to a set value. Can supply.

When the first power output unit supplies power to the second LNB, the LNB power supply device may further include a first power cut-off unit configured to cut off power supply to the first LNB.

An LNB power supply according to an embodiment of the present invention includes a first power output unit supplying power to a first LNB, and a second power output unit supplying power to a second LNB, and the first power output unit is When the power output unit is supplying power to the second LNB and the load of the second LNB is greater than or equal to the threshold load, the power output unit supplies power to the second LNB, and the second power output unit is supplying power to the first LNB, When the load of the first LNB is greater than or equal to the threshold load, power may be supplied to the first LNB.

The LNB power supply includes a first power supplement that selectively forms a power supply path from the second power output to the first LNB, and a second power supplement selectively forms a power supply path from the first power output to the second LNB. It may further include a power supplement.

The LNB power supply includes a first power cut-off unit selectively blocking a power supply path from the first power output unit to the first LNB, and a second power supply unit selectively blocking a power supply path from the second power output unit to the second LNB. It may further include a power cut-off.

The LNB power supply may further include a control unit for controlling the first power supply unit, the second power supply unit, the first power supply unit and the second power supply unit.

Each of the first power supply unit, the second power supply unit, the first power supply unit, and the second power supply unit may be a switch.

The control unit controls the first power supplement to turn off when the first power output unit is in the first mode supplying power only to the first LNB, and the second power output unit is in the second mode to supply power only to the second LNB. 2 The power supplement can be controlled by turning off.

In the third mode in which the first power output unit and the second power output unit supply power to the first LNB, the control unit controls the first power supplement unit to turn on, the first power cut unit to turn on, and the second power cut unit to turn off. , In the fourth mode in which the first power output unit and the second power output unit supply power to the second LNB, the first power supplement unit is turned on, the first power cut unit is turned off, and the second power cut unit is turned on. have.

In the fifth mode, in which the first power output unit supplies power to the first LNB and the second power output unit supplies power to the second LNB, the control unit turns on the first power supply unit and turns on the second power supply unit. The power supplemental unit may be turned off and the second power supplemental unit may be turned off.

According to the present invention, since a plurality of power output units distribute and supply the necessary power of the LNB, the load of each power output unit can be lowered, and accordingly, the possibility of damage to the power output unit due to an increase in the load of the LNB can be minimized. There is this.

In addition, even if a plurality of power output units share the power supply to the LNB, there is an advantage in that RF reception performance can be improved by minimizing a case in which RF signals received by other LNBs flow into the tuner and are interfered with.

In addition, there is an advantage of improving the reliability of the LNB and improving the life of the LNB power supply.

1 is a schematic diagram illustrating an LNB system.
2 is a schematic diagram showing an LNB system according to the first embodiment of the present invention.
3 is a schematic diagram illustrating an LNB system according to a second embodiment of the present invention.
4 is an exemplary diagram illustrating a state in which an LNB power supply device according to a second embodiment of the present invention operates in a first mode.
5 is an exemplary diagram illustrating a state in which an LNB power supply device according to a second embodiment of the present invention operates in a second mode.
6 is an exemplary diagram showing a state in which the LNB power supply device according to the second embodiment of the present invention operates in a third mode.
7 is an exemplary diagram showing a state in which the LNB power supply device according to the second embodiment of the present invention operates in a fourth mode.
FIG. 8 is an exemplary diagram illustrating a state in which the LNB power supply device according to the second embodiment of the present invention operates in a fifth mode.
9 is an exemplary diagram showing a state in which the LNB power supply device according to the second embodiment of the present invention operates in a sixth mode.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

1 is a schematic diagram illustrating an LNB system.

The LNB system may include a satellite antenna (1) (2) having an LNB (10) (20) and a receiving device (100).

The reception device 100 may be a display device such as a TV or a set-top box.

The reception device 100 may include a power output unit 110 and 120 supplying power to the LNB 10 and 20, and a tuner 130 receiving a signal from the LNB 10 and 20. However, the configuration of the reception device 100 shown in FIG. 1 is merely an example for convenience of description, and the reception device 100 is a configuration other than the tuner 130 and the power output units 110 and 120 It may further include.

The first LNB 10 may convert the received IF signal into an RF signal and transmit the converted RF signal to the tuner 130 through the first input port 131. Similarly, the second LNB 20 may convert the received IF signal into an RF signal, and transmit the converted RF signal to the tuner 130 through the second input port 132.

In addition, the first power output unit 110 may supply power to the first LNB 10, and the second power output unit 120 may supply power to the second LNB 20.

At this time, the first line L1 is connected between the first LNB 10 and the first input port 131, and the second line L2 is a point of the first line L1 and a first power output. It is connected between the unit 110, the third line (L3) is connected between the second LNB (20) input port 132, the fourth line (L4) is a point and a third line (L3). 2 It can be connected between the power output unit 120.

The first to fourth lines L1 to L4 may be cables capable of transmitting signals and power. For example, each of the first to fourth lines L1 to L4 may be a coaxial cable, but this is only exemplary. Hereinafter, it is assumed that each line connecting the components as well as the first line L1 to the fourth line L4 is a cable capable of transmitting signals and power.

In the case of the LNB system shown in FIG. 1, when the load of the first LNB 10 increases, the first power output unit 110 increases the power supply to the first LNB 10. In this case, when an overcurrent flows, the first power There may be a problem that the output unit 110 is damaged. Likewise, when the load of the second LNB 20 increases, the second power output unit 120 increases the power supply to the second LNB 20. In this case, when an overcurrent flows, the second power output unit 120 is damaged. Problems may arise.

Therefore, in order to improve this problem, in the present invention, when the load of the first LNB 10 or the second LNB 20 increases, the first power output unit 110 and the second power output unit 120 It is intended to share power supply to the first LNB 10 or the second LNB 20.

2 is a schematic diagram showing an LNB system according to the first embodiment of the present invention.

The LNB system according to the first embodiment of the present invention may further include a fifth line L5 connecting the second line L2 and the fourth line L4 in the LNB system shown in FIG. 1.

That is, the LNB system according to the first embodiment of the present invention includes a satellite antenna (1) (2) having an LNB (10) (20) and a reception device (100), and the reception device (100) includes an LNB (10). ), a power output unit 110, 120 for supplying power to 20, a tuner 130 receiving a signal from the LNB 10, 20, and the first line L1 is the first LNB ( 10) and the first input port 131, the second line L2 is connected between a point of the first line L1 and the first power output unit 110, and the third line L3 ) Is connected between the input port 132 of the second LNB 20, and the fourth line L4 is connected between a point of the third line L3 and the second power output unit 120, and The line L5 may be connected between a point of the second line L2 and a point of the fourth line L4.

On the other hand, unlike FIG. 2, according to an embodiment, the fifth line L5 is connected between the first line L1 and the third line L3, or the first line L1 and the fourth line It may be connected between L4) or may be connected between the second line L2 and the third line L3.

According to the first embodiment of the present invention, when the load of any one of the first LNB 10 and the second LNB 20 increases, the first power output unit 110 and the second power output unit 120 Together, power may be supplied to the LNB having an increased load, and in this case, the load of the first power output unit 110 or the second power output unit 120 may be reduced.

Specifically, as shown in FIG. 2, when the load of the first LNB 10 further increases while the first power output unit 110 is supplying power to the first LNB 10, the second power output The unit 120 may output power, and the output power may be supplied to the first LNB 10. Accordingly, since the second power output unit 120 supplies current to be further supplied by the first power output unit 110, the current load of the first power output unit 110 may be reduced.

Similarly, when the load of the second LNB 20 is further increased while the second power output unit 120 is supplying power to the second LNB 20, the first power output unit 110 20) can supply power. In this case, since the first power output unit 110 supplies current to be further supplied by the second power output unit 120, the current load of the second power output unit 120 may be reduced.

As described above, according to the first embodiment of the present invention, the first power output unit 110 and the second power output in the LNB system are relatively simple by adding only the fifth line L5, and without adding much cost. There is an advantage in that it is possible to reduce the current burden on the unit 120 and thus improve the life of the first power output unit 110 and the second power output unit 120.

Meanwhile, in the case of the first embodiment, while the first power output unit 110 is supplying power to the first LNB 10, the second power output unit 120 is configured to increase the load of the first LNB 10. When power is supplied to the first LNB 10, current output from the second power output unit 120 may flow not only to the first LNB 10 but also to the second LNB 20. In this case, since the second LNB 20 operates, the satellite signal can be received and converted into an RF signal, and the RF signal passes through the fifth line L5 and the tuner 130 through the first input port 131 May be supplied to. That is, the tuner 130 only needs a signal received through the first LNB 10, but there may be a problem in that the signal received through the second LNB 20 flows together and crosstalk.

Likewise, when the second power output unit 120 is supplying power to the second LNB 20, the first power output unit 110 becomes the second LNB 20 due to an increase in the load of the second LNB 20. Interference problems may occur even when the power is supplied to the device.

3 is a schematic diagram illustrating an LNB system according to a second embodiment of the present invention.

The LNB system according to the second embodiment of the present invention may include a satellite antenna (1) (2) having the LNB (10) (20) and a receiving device (100). The reception device 100 may be a display device such as a TV or a set-top box. The configuration of the reception device 100 illustrated in FIG. 3 is merely an example for convenience of description, and the reception device 100 may further include other configurations in addition to the configuration illustrated in FIG. 3.

The receiving device 100 may include a tuner 130 and an LNB power supply.

The LNB power supply includes a first power output unit 110, a second power output unit 120, a tuner 130, a first current sensing unit 115, a second current sensing unit 125, and a first power cutoff. At least some or all of the unit 111, the second power cut-off unit 121, the first power supplement 113, the second power supplement 123, and the control unit 140 may be included.

The plurality of power output units 110 and 120 supply power to at least one LNB. In addition, the plurality of power output units 110 and 120 may simultaneously supply power to the LNB having a load equal to or greater than the critical load.

Specifically, the first power output unit 110 may supply power to the first LNB 10. In addition, the first power output unit 110 may supply supplemental power to the second LNB 20 when the load of the second LNB 20 is greater than or equal to the threshold load. That is, when the load of the second LNB 20 is greater than or equal to the threshold load, the first power output unit 110 and the second power output unit 120 may simultaneously supply power to the second LNB 20.

Likewise, the second power output unit 120 may supply power to the second LNB 20, and the second power output unit 120 is the first LNB when the load of the first LNB 20 is greater than or equal to the threshold load. Supplementary power can be supplied with 10). That is, when the load of the first LNB 10 is greater than or equal to the threshold load, the first power output unit 110 and the second power output unit 120 may simultaneously supply power to the first LNB 10.

In summary, when the second power output unit 120 is supplying power to the second LNB 20 and the load of the second LNB 20 is greater than or equal to the threshold load, the first power output unit 110 is Power can be supplied to (20). When the first power output unit 110 is supplying power to the first LNB 10 and the load of the first LNB 10 is greater than or equal to the threshold load, the second power output unit 120 is connected to the first LNB 10 Can supply power to

In FIGS. 3 and 4 to 9 to be described later, the power output unit 110 and 120, the current sensing unit 115 and 125, the power cut-off unit 111 and 121, and the power supplement unit 113 and 123 Although it is shown that each is provided with two, this is merely an example for convenience of description. The power output unit 110, 120, current detection unit 115, 125, power cut-off unit 111, 121, and power supplement unit 113, 123 correspond to the LNB 10 and 20. It can be provided. That is, the power output unit 110, 120, the current detection unit 115, 125, the power cut-off unit 111, 121, the power supplement unit 113, 123 of the LNB (10) (20) It can be provided as many times.

The first current sensing unit 115 may determine whether the load of the first LNB 10 is greater than or equal to the threshold load. Specifically, the first current sensing unit 115 may acquire a current value supplied to the first LNB 10 by sensing a current flowing into the first LNB 10. The controller 140 may recognize that the load of the first LNB 10 is greater than or equal to the threshold load when the current value sensed by the first current sensing unit 115 is greater than or equal to the set value.

Likewise, the second current sensing unit 125 may determine whether the load of the second LNB 20 is greater than or equal to the threshold load. Specifically, the second current sensing unit 125 may acquire a current value supplied to the second LNB 20 by sensing the current flowing into the second LNB 20. The controller 140 may recognize that the load of the second LNB 20 is greater than or equal to the threshold load when the current value sensed by the second current sensing unit 125 is greater than or equal to the set value.

Accordingly, the second power output unit 120 supplies power to the first LNB 10 when the first current value sensed by the first current detection unit 115 is greater than or equal to the set value, and the first power output unit 110 ) May supply power to the second LNB 20 when the second current value sensed by the second current detection unit 120 is equal to or greater than the set value.

Meanwhile, the set value may be a current value that serves as a reference for determining whether the load of the LNB is greater than or equal to the threshold load. The setting value may be set differently according to the installation environment of the LNB system.

A first diode 10d may be installed at an output terminal of the first current detection unit 115 and a second diode 20d may be installed at an output terminal of the second current detection unit 125.

The first diode 10d prevents the current passing through the first current detector 115 from flowing back to the first current detector 115, and the second diode 20d prevents the second current detector 125 It is possible to prevent the current passing through) from flowing back to the second current sensing unit 125.

When the LNB power supply further includes the first and second diodes 10d and 20d, the first and second current sensing units 115 and 125 detect a re-inflow current after passing. There is an advantage in that errors in value measurement can be reduced, and accordingly, the accuracy of load measurement of the first and second LNBs 10 and 20 can be increased.

The first power cut-off unit 111 may selectively cut off power supplied from the first power output unit 110 to the first LNB 10. That is, the first power cut-off unit 111 may selectively cut off a power supply path from the first power output unit 110 to the first LNB 10.

In particular, the first power cut-off unit 111 supplies power from the first power output unit 110 to the second LNB 10 when the first power output unit 110 supplies power to the second LNB 20. Can be blocked.

The first power cut-off unit 111 may be a switch. The first power cut-off unit 111 may be turned on or off. When the first power cut-off unit 111 is turned on, power output from the first power output unit 110 may pass through the first power cut-off unit 111 and be supplied to the first LNB 10. However, when the first power cut-off unit 111 is turned off, the power output from the first power output unit 110 cannot pass through the first power cut-off unit 111, and thus the first power output unit Power output from (110) cannot flow into the first LNB (10).

Likewise, the second power cut-off unit 121 may selectively cut off power supplied from the second power output unit 120 to the second LNB 20. That is, the second power cut-off unit 121 may selectively cut off a power supply path from the second power output unit 120 to the second LNB 20.

In particular, the second power cut-off unit 121 supplies power from the second power output unit 120 to the second LNB 20 when the second power output unit 120 supplies power to the first LNB 10. Can be blocked.

The second power cut-off unit 121 may be a switch. The second power cut-off unit 121 may be turned on or off. When the second power cut-off unit 121 is turned on, power output from the second power output unit 120 may pass through the second power cut-off unit 121 and be supplied to the second LNB 20. However, when the second power cut-off unit 121 is turned off, the power output from the second power output unit 120 cannot pass through the second power cut-off unit 121, and accordingly, the second power output unit Power output from 120 cannot flow into the second LNB 20.

The first power cut-off unit 111 is turned off when the power to the first LNB 10 is cut off, and the second power cut-off unit 121 is turned off when the power to the second LNB 20 is cut off. Can be.

The first power supplement unit 113 may selectively form a power supply path from the second power output unit 120 to the first LNB 10.

The first power supplement 113 may be a switch. The first power supplement 113 may be turned on or off. When the first power supplement 113 is turned on, at least some of the power output from the second power output 120 may pass through the first power supplement 113, and the first power supplement 113 Power passing through) may be supplied to the first LNB 10.

In detail, the power passing through the first power supplementing unit 113 flows into the first path P1 through which the power output from the first power output unit 110 is supplied to the first LNB 10, It can be supplied to the first LNB 10 only when the first power cut-off unit 111 is turned on.

On the other hand, when the first power supplemental unit 113 is turned off, the power output from the second power output unit 120 cannot pass through the first power supplemental unit 113, and thus the first LNB 10 The power supply path in the direction is cut off.

The second power supplement unit 123 may selectively form a power supply path from the first power output unit 110 to the second LNB 20.

The second power supplement 123 may be a switch. The second power supplement 123 may be turned on or off. When the second power supplement 123 is turned on, at least some of the power output from the first power output 110 may pass through the second power supplement 123 and the second power supplement 123 Power passing through) may be supplied to the second LNB 20.

Specifically, the power that has passed through the second power supplement unit 123 flows into the second path P2 through which the power output from the second power output unit 110 is supplied to the second LNB 20, It can be supplied to the second LNB 20 only when the second power cut-off unit 121 is turned on.

On the other hand, when the second power supply unit 123 is turned off, the power output from the first power output unit 110 cannot pass through the second power supply unit 123, and thus the second LNB 20 The power supply path in the direction is cut off.

A third diode 113d may be installed at an output terminal of the first power supplementing unit 113, and a fourth diode 123d may be installed at an output terminal of the second power supplementing unit 123.

The third diode 113d prevents the current that has passed through the first power supplementing unit 113 from flowing back to the second path P2, and the fourth diode 123d prevents the second power supplementing unit 123 from flowing back. It is possible to prevent the passed current from flowing back into the first path P1.

The control unit 140 includes first and second power output units 110 and 120, first and second current sensing units 115 and 125, first and second power cut-off units 111 and 121, Each of the first and second power supplement units 113 and 123 may be controlled.

The controller 140 may control whether power is output from each of the first power output unit 110 and the second power output unit 120 and an amount of power output. The controller 140 may receive a current value sensed by each of the first and second current detectors 115 and 125. The controller 140 may turn on or off each of the first and second power cut-off units 111 and 121 and the first and second power supplements 113 and 123.

The controller 140 may operate the LNB power supply in any one of the first to sixth modes.

According to an embodiment, the controller 140 may include a first logic circuit 141 and a second logic circuit 142 and a controller 140 that perform an AND operation. The controller 140 may determine an operation mode of the LNB power supply by inputting a control signal to the first and second logic circuits 141 and 142.

The controller 140 may input a control signal having 1 or 0 as data to the first and second logic circuits 141 and 142.

According to the power output state of each of the first and second power output units 110 and 120 and a control signal input to each of the first and second logic circuits 141 and 142, the operation mode of the LNB power supply is It can be different. The operation mode of the LNB power supply will be described in detail with reference to FIGS. 4 to 9.

Meanwhile, the LNB power supply is at least one of the fourth and fifth diodes 110d and 120d, the first and second state detection units 117 and 127, and the third and fourth logic circuits 111a and 121a. You can include some or all of them.

The fourth diode 110d may prevent the power from flowing back to the first power output unit 110 and the first state detection unit 117, and the fifth diode 120d may be the second power output unit 120 And reverse flow of power to the second state detection unit 127 may be prevented.

The first state sensing unit 117 inputs a state signal indicating whether the first power output unit 110 outputs power to the first logic circuit 141, and the second state sensing unit 127 outputs a second power. A status signal indicating whether the unit 120 outputs power may be input to the second logic circuit 142.

The first state detection unit 117 may be a switch, and may include first and second resistors R1 and R2 for a switch operation. Likewise, the second state detection unit 127 may be a switch and may include third and fourth resistors R3 and R4 for operating the switch.

The third and fourth logic circuits 111a and 121a may perform a NOT operation. Each of the third and fourth logic circuits 111a and 121a may determine whether to apply a voltage to the first and second power cut-off units 111 and 121.

Meanwhile, the positions and types of the first to fourth logic circuits 141, 142, 111a, and 121a may be changed according to the design of the LNB power supply. In addition, the power cut-off units 111 and 121, the power supplements 113 and 123, and the state detection units 117 and 127 shown in FIG. 3 are field effect transistors (FETs), but these are only exemplary. Therefore, it is not limited thereto.

Next, an operation mode of the LNB power supply device according to an embodiment of the present invention will be described with reference to FIGS. 4 to 9.

4 is an exemplary diagram illustrating a state in which an LNB power supply device according to a second embodiment of the present invention operates in a first mode.

The first mode may be a mode in which the first power output unit 110 supplies power to the first LNB 10 and operates so that power is not supplied to the second LNB 20.

When the load of the first LNB 10 is sensed, the first power output unit 110 may output power. In addition, when the load of the first LNB 10 is less than the threshold load and the load of the second LNB 20 is not detected, the second power output unit 120 may not output power.

As the first power output unit 110 outputs power, the first state detection unit 117 is turned on, and accordingly, data 1 may be input to the first logic circuit 142. As the second power output unit 120 does not output power, the second state detection unit 127 is turned off, and accordingly, data 0 may be input to the second logic circuit 143.

In addition, the controller 141 may input data 0 to the first logic circuit 142 and the second logic circuit 143, respectively. As a result, the first logic circuit 142 and the second logic circuit 143 may each output data 0.

As the first logic circuit 142 outputs data 0, the first power supplement 113 is turned off, and the fourth logic circuit 121a may output data 1.

As the first power supplementing unit 113 is turned off, a power supply path from the second power output unit 120 to the first LNB 10 is cut off.

As the fourth logic circuit 121a outputs data 1, the second power cut-off unit 121 is turned on. However, since the second power output unit 120 does not output power, the second LNB 20 has power Is not supplied.

Meanwhile, as the second logic circuit 143 outputs data 0, the second power supplement 123 is turned off, and the third logic circuit 111a may output data 1.

As the second power supplement unit 123 is turned off, a power supply path from the first power output unit 110 to the second LNB 20 is cut off.

As the third logic circuit 111a outputs data 1, the first power cut-off unit 111 is turned on, and accordingly, the power output from the first power output unit 110 is supplied to the first LNB 10. I can.

5 is an exemplary diagram illustrating a state in which an LNB power supply device according to a second embodiment of the present invention operates in a second mode.

The second mode may be a mode in which the second power output unit 120 supplies power to the second LNB 20 and operates so that power is not supplied to the first LNB 10.

When the load of the second LNB 20 is sensed, the second power output unit 120 may output power. In addition, when the load of the second LNB 20 is less than the threshold load and the load of the first LNB 10 is not detected, the first power output unit 110 may not output power.

As the second power output unit 112 outputs power, the second state detection unit 127 is turned on, so that data 1 may be input to the second logic circuit 143. As the first power output unit 110 does not output power, the first state detection unit 117 is turned off, and thus data 0 may be input to the first logic circuit 142.

In addition, the controller 141 may input data 0 to the first logic circuit 142 and the second logic circuit 143, respectively. As a result, the first logic circuit 142 and the second logic circuit 143 may each output data 0.

As the second logic circuit 143 outputs data 0, the second power supplement 123 is turned off, and the third logic circuit 111a may output data 1.

As the second power supplement unit 123 is turned off, a power supply path from the first power output unit 110 to the second LNB 20 is cut off.

As the third logic circuit 111a outputs data 1, the first power cut-off unit 111 is turned on. However, since the first power output unit 110 does not output power, the first LNB 10 has power Is not supplied.

Meanwhile, as the first logic circuit 123 outputs data 0, the first power supplement 113 is turned off, and the fourth logic circuit 121a may output data 1.

As the first power supplementing unit 113 is turned off, a power supply path from the second power output unit 120 to the first LNB 10 is cut off.

As the fourth logic circuit 121a outputs data 1, the second power cut-off unit 121 is turned on, and accordingly, the power output from the second power output unit 120 is supplied to the second LNB 20. I can.

6 is an exemplary diagram showing a state in which the LNB power supply device according to the second embodiment of the present invention operates in a third mode.

The third mode is a mode in which the first power output unit 110 and the second power output unit 120 supply power to the first LNB 10 and do not supply power to the second LNB 20. Can be

When the load of the first LNB 10 is sensed, the first power output unit 110 may output power. In addition, when the current value sensed by the first current detection unit 115 is greater than or equal to the set value, it is recognized that the load of the first LNB 10 is greater than or equal to the threshold load, so the second power output unit 120 also outputs power. can do.

As the first power output unit 110 outputs power, the first state detection unit 117 is turned on, and accordingly, data 1 may be input to the first logic circuit 142. Likewise, as the second power output unit 120 outputs power, the second state detection unit 127 is turned on, and thus data 1 may be input to the second logic circuit 143.

On the other hand, the controller 141 inputs data 1 to the first logic circuit 142 when the load of the first LNB 10 is greater than or equal to the threshold load and the load of the second LNB 20 is not detected, Data 0 may be input to the second logic circuit 143. As a result, the first logic circuit 142 may output data 1 and the second logic circuit 143 may output data 0.

As the first logic circuit 142 outputs data 1, the first power supplement 113 is turned on, and the fourth logic circuit 121a may output data 0.

As the first power supplementing unit 113 is turned on, a power supply path from the second power output unit 120 to the first LNB 10 is formed. In addition, as the fourth logic circuit 121a outputs data 0, the second power cut-off unit 121 is turned off. Accordingly, the power output from the second power output unit 120 may not be supplied to the second LNB 20 and may flow into the first path P1.

Meanwhile, as the second logic circuit 143 outputs data 0, the second power supplement 123 is turned off, and the third logic circuit 111a may output data 1.

As the second power supplement unit 123 is turned off, a power supply path from the first power output unit 110 to the second LNB 20 is cut off. As the third logic circuit 111a outputs data 1, the first power cut-off unit 111 is turned on.

Accordingly, power output from the first power output unit 110 and power output from the second power output unit 120 may be supplied to the first LNB 10 together.

In this way, when the load of the first LNB 10 is excessively increased, the second power output unit 120 supplies power together with the first power output unit 110, so that the first power output unit 110 Can reduce the load. In addition, since the power supply to the second LNB 20 is completely cut off, the signal received by the second LNB 20 cannot be received by the second LNB 20 because the signal is introduced to the tuner 130. Can be minimized.

7 is an exemplary diagram showing a state in which the LNB power supply device according to the second embodiment of the present invention operates in a fourth mode.

In a fourth mode, the first power output unit 110 and the second power output unit 120 supply power to the second LNB 20 and operate so that power is not supplied to the first LNB 10. Can be

When the load of the second LNB 20 is sensed, the second power output unit 120 may output power. In addition, when the current value sensed by the second current detection unit 125 is greater than or equal to the set value, it is recognized that the load of the second LNB 20 is greater than or equal to the threshold load, so the first power output unit 110 also outputs power can do.

As the second power output unit 120 outputs power, the first state detection unit 127 is turned on, so that data 1 may be input to the second logic circuit 143. Likewise, as the first power output unit 110 outputs power, the first state detection unit 117 is turned on, and thus data 1 may be input to the first logic circuit 142.

On the other hand, the controller 141 inputs data 0 to the first logic circuit 142 when the load of the second LNB 20 is greater than or equal to the threshold load and the load of the first LNB 10 is not detected, Data 1 may be input to the second logic circuit 143. As a result, the first logic circuit 142 may output data 0, and the second logic circuit 143 may output data 1.

As the second logic circuit 143 outputs data 1, the second power supplement 123 is turned on, and the third logic circuit 111a may output data 0.

As the second power supplement unit 123 is turned on, a power supply path from the first power output unit 110 to the second LNB 20 is formed. In addition, as the third logic circuit 111a outputs data 0, the first power cut-off unit 111 is turned off. Accordingly, the power output from the first power output unit 110 may not be supplied to the first LNB 10 and may flow into the second path P2.

Meanwhile, as the first logic circuit 142 outputs data 0, the first power supplement 113 is turned off, and the fourth logic circuit 121a may output data 1.

As the first power supplementing unit 113 is turned off, a power supply path from the second power output unit 120 to the first LNB 10 is cut off. As the fourth logic circuit 121a outputs data 1, the second power cut-off unit 121 is turned on.

Accordingly, power output from the first power output unit 110 and power output from the second power output unit 120 may be supplied to the second LNB 20 together.

In this way, when the load of the second LNB 20 is excessively increased, the first power output unit 110 supplies power together with the second power output unit 120, so that the second power output unit 120 Can reduce the load. In addition, since the power supply to the first LNB 10 is completely cut off, the signal received by the first LNB 10 cannot be received by the first LNB 10 and thus the signal received by the first LNB 10 flows into the tuner 130. Can be minimized.

FIG. 8 is an exemplary diagram illustrating a state in which the LNB power supply device according to the second embodiment of the present invention operates in a fifth mode.

The fifth mode is a mode in which the first power output unit 110 supplies power to the first LNB 10 and the second power output unit 120 supplies power to the second LNB 20. I can.

When a load is sensed in each of the first LNB 10 and the second LNB 20, each of the first power output unit 110 and the second power output unit 120 may output power.

As the first power output unit 110 outputs power, the first state detection unit 117 is turned on, and accordingly, data 1 may be input to the first logic circuit 142. Likewise, as the second power output unit 120 outputs power, the second state detection unit 127 is turned on, and thus data 1 may be input to the second logic circuit 143.

On the other hand, the controller 141 inputs data 0 to the first logic circuit 142 when a load is detected in each of the first LNB 10 and the second LNB 20, and the second logic circuit 143 You can enter data 0 in. As a result, the first logic circuit 142 may output data 0, and the second logic circuit 143 may output data 0.

As the first logic circuit 142 outputs data 0, the first power supplement 113 is turned off, and the fourth logic circuit 121a may output data 1.

As the first power supplementing unit 113 is turned off, a power supply path from the second power output unit 120 to the first LNB 10 is cut off. In addition, as the fourth logic circuit 121a outputs data 1, the second power cut-off unit 121 is turned on. Accordingly, power output from the second power output unit 120 may be supplied only to the second LNB 20. In addition, the power output from the second power output unit 120 is blocked from flowing into the first path P1.

Similarly, as the second logic circuit 143 outputs data 0, the second power supplement 123 is turned off, and the third logic circuit 111a may output data 1.

As the second power supplement unit 123 is turned off, a power supply path from the first power output unit 110 to the second LNB 20 is cut off. As the third logic circuit 111a outputs data 1, the first power cut-off unit 111 is turned on. Accordingly, power output from the first power output unit 110 may be supplied only to the first LNB 10. In addition, the power output from the first power output unit 110 is blocked from flowing into the second path P2.

As described above, when a load is generated in each of the first LNB 10 and the second LNB 20, the first power output unit 110 and the second power output unit 120 each of the first LNB 10 and the second LNB 20 2 Power can be supplied to each of the LNBs 20.

9 is an exemplary diagram showing a state in which the LNB power supply device according to the second embodiment of the present invention operates in a sixth mode.

The sixth mode may be a mode in which power is not supplied to either of the first LNB 10 and the second LNB 20.

When a load is not detected in each of the first LNB 10 and the second LNB 20, each of the first power output unit 110 and the second power output unit 120 may not output power.

Since the first power output unit 110 does not output power, the first state detection unit 117 is turned off, and thus data 0 may be input to the first logic circuit 142. Likewise, since the second power output unit 120 does not output power, the second state detection unit 127 is turned off, and thus data 0 may be input to the second logic circuit 143.

On the other hand, when the load is not detected in each of the first LNB 10 and the second LNB 20, the controller 141 inputs data 0 to the first logic circuit 142, and the second logic circuit 143 ), you can enter data 0. As a result, the first logic circuit 142 may output data 0, and the second logic circuit 143 may output data 0.

As the first logic circuit 142 outputs data 0, the first power supplement 113 is turned off, and the fourth logic circuit 121a may output data 1.

As the first power supplementing unit 113 is turned off, a power supply path from the second power output unit 120 to the first LNB 10 is cut off. In addition, as the fourth logic circuit 121a outputs data 1, the second power cut-off unit 121 is turned on. However, since the first power output unit 120 does not output power, power is also not supplied to the first LNB 10.

Similarly, as the second logic circuit 143 outputs data 0, the second power supplement 123 is turned off, and the third logic circuit 111a may output data 1.

As the second power supplement unit 123 is turned off, a power supply path from the first power output unit 110 to the second LNB 20 is cut off. In addition, as the third logic circuit 111a outputs data 1, the first power cut-off unit 111 is turned on. However, since the second power output unit 120 does not output power, power is also not supplied to the second LNB 20.

4 to 9, when the second power output unit 120 is supplying power to the second LNB 20 and the load of the second LNB 20 is greater than or equal to the threshold load, the first power output unit ( 110) supplies power to the second LNB 20 to reduce the load burden of the second power output unit 120. Likewise. When the first power output unit 110 is supplying power to the first LNB 10 and the load of the first LNB 10 is greater than or equal to the threshold load, the second power output unit 120 is connected to the first LNB 10. By supplying power, the load burden of the first power output unit 110 can be reduced. Accordingly, there is an effect of improving the life of the LNB power supply device.

In addition, a path for supplying supplementary power through the first and second power cut-off units 111 and 121 and the first and second power supplements 113 and 123 is formed, as well as the satellite RF signal. There is an advantage of being able to isolate a path so as not to be confused. That is, by blocking a power supply path to an LNB that is not in use, there is an advantage in that interference of satellite signals can be prevented, and thus the reliability of RF signal reception performance can be improved.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention.

Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

Claims (15)

Including a plurality of power outputs and a power cut-off unit for supplying power to at least one LNB (Low Noise Block down converter),
The first power output unit of the plurality of power output units
Supply power to the first LNB,
The second power output unit of the plurality of power output units
When the first power output unit is supplying power to the first LNB and the load of the first LNB is greater than or equal to a threshold load, supplying power to the first LNB,
The power cut-off unit blocks power supply to the second LNB when the second power output unit supplies power to the first LNB.
LNB power supply. delete The method of claim 1,
Further comprising a first current sensing unit for sensing a current supplied to the first LNB,
The second power output unit
Supplying power to the first LNB when the first current value sensed by the first current sensing unit is greater than or equal to a set value
LNB power supply. delete The method of claim 1,
The second power output unit of the plurality of power output units
Supply power to the second LNB,
The first power output unit of the plurality of power output units
When the second power output unit is supplying power to the second LNB and the load of the second LNB is greater than or equal to a threshold load, supplying power to the second LNB
LNB power supply. The method of claim 5,
Further comprising a second current sensing unit for sensing the current supplied to the second LNB,
The first power output unit
Supplying power to the second LNB when the second current value sensed by the second current sensing unit is greater than or equal to a set value.
LNB power supply. The method of claim 5,
The LNB power supply device includes a first power cut-off part configured to cut off power supply to the first LNB when the first power output part supplies power to the second LNB. A first power output unit supplying power to the first LNB;
A second power output unit supplying power to the second LNB;
A first power cut-off unit;
A second power cut-off unit;
A first current detector configured to detect a current value supplied to the first LNB and determine whether a load of the first LNB is greater than or equal to a threshold load; And
A second current detector configured to detect a current value supplied to the second LNB and determine whether a load of the first LNB is greater than or equal to a threshold load,
The first power output unit
When the second power output unit is supplying power to the second LNB and the load of the second LNB is greater than or equal to a threshold load, supplying power to the second LNB,
The second power output unit
When the first power output unit is supplying power to the first LNB and the load of the first LNB is greater than or equal to a threshold load, supplying power to the first LNB,
The first power cut-off unit
When the first power output unit supplies power to the second LNB, it cuts off power supply to the first LNB,
The second power cut-off unit
When the second power output unit supplies power to the first LNB, blocking power supply to the second LNB
LNB power supply. The method of claim 8,
A first power supplement unit selectively forming a power supply path from the second power output unit to the first LNB; And
Further comprising a second power supplement to selectively form a power supply path from the first power output to the second LNB
LNB power supply. delete The method of claim 9,
Further comprising a control unit for controlling the first power supplement, the second power supplement, the first power cut off and the second power cut off.
LNB power supply. The method of claim 11,
Each of the first power supply unit, the second power supply unit, the first power supply unit, and the second power supply unit is a switch.
LNB power supply. The method of claim 12,
The control unit
When the first power output unit is in a first mode in which power is supplied only to the first LNB, the first power supplement is turned off,
When the second power output unit is in a second mode in which power is supplied only to the second LNB, the second power supplement unit is turned off.
LNB power supply. The method of claim 12,
The control unit
When the first power output unit and the second power output unit are in a third mode supplying power to the first LNB, the first power supplement unit is turned on, the first power supply unit is turned on, and the second power unit is turned off. Control with
When the first power output unit and the second power output unit are in a fourth mode supplying power to the second LNB, the first power supplement unit is turned on, the first power supply unit is turned off, and the second power unit is turned on. Controlled by
LNB power supply. The method of claim 12,
The control unit
When the first power output part supplies power to the first LNB and the second power output part supplies power to the second LNB in a fifth mode, the first power cut-off part is turned on, and the second power cut-off part Turning on, turning off the first power supplement, and controlling the second power supplement to turn off
LNB power supply.

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