JP2894724B2 - Transmitter output switching method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial applications]

The present invention relates to a method for switching the output of a battery-powered transmitter.

[Prior art]

The power of the transmission power amplifier (final stage) of the wireless communication device mounted on the ship is supplied with DC power from a battery in an emergency case. When the transmission power amplifier is composed of a semiconductor and the transmission power is large, the power supply voltage is adjusted to a normal battery voltage in consideration of the operation efficiency of the final-stage power amplifier.
Must be higher than 24V. On the other hand, it is necessary to reduce the transmission power to a necessary and sufficient level in a sea area where ships frequently sail.In this case, if a method of reducing the transmission voltage by reducing the supply voltage to the power amplifier at the final stage is used, The operation efficiency of the power amplifier is improved.

[Problems to be solved by the invention]

Therefore, it is desirable that the voltage can be varied as a power supply to the marine radio communication device. As the voltage variable power supply, application of an inverter power supply that can obtain an arbitrary voltage from a fixed DC voltage can be considered. However, since this type of inverter power supply is composed of a complicated electronic circuit and is constantly driven, there is a possibility that a failure may occur.
If the inverter power supply breaks down, the output voltage naturally becomes 0 V, so that power cannot be supplied to the wireless communication device, and a serious problem has occurred such that important communication means are stopped. The present invention has been made in order to eliminate the above-described problems, and has as its object to provide a method that can easily and easily change the transmitter output.

[Means for Solving the Problems]

The switching method of the transmitter output according to the present invention, as a DC power supply for supplying a voltage to the final stage of the transmitter, allows an intermittent current to flow to a primary side of an insulating transformer by a switching means, and to a secondary side of the transformer. An inverter circuit that rectifies the generated induced voltage by a rectifier circuit to obtain a DC voltage is connected in series with each other so that the output voltage (Vo) of the inverter circuit is added to the voltage (Vb) of the battery for driving the inverter circuit. In addition, a voltage (Vb) is supplied when the inverter circuit is stopped, and a voltage (Vb + Vo) is supplied to the last stage of the transmitter when the inverter circuit is operating, thereby switching the transmitter output.

[Action]

According to the above method, if the operation of the inverter circuit, the output terminal of the input voltage V _o to the inverter circuit output voltage Vi is the voltage obtained by adding of the DC power supply (V _o + Vi) is the direct-current power supply is output, although a higher voltage to a final stage of the transmitter is applied, at the time of stopping the inverter circuit, the output voltage Vi of the inverter circuit becomes a 0V, the secondary of the isolation transformer of the input voltage V _o is the inverter circuit It is led to the output terminal of the DC power supply via the coil and the rectifier circuit.

【Example】

FIG. 1 is a circuit diagram showing an embodiment based on a transmitter output switching method according to the present invention. DC 24 obtained from a DC power source such as a battery
The V + line is connected to one tap of a primary coil P of the isolation transformer 1, the other tap of the primary coil P is connected to the drain of a switching transistor 2, and the source of the transistor 2 is connected to the input. Connected to the negative voltage line. The + line of the input voltage is connected to one tap of the secondary coil S of the insulating transformer 1, and the other tap of the secondary coil S is connected to the reactor L of the smoothing circuit 4 via the rectifier 3. Is done. A smoothing capacitor C is connected between the other end m of the reactor L and the + line of the input voltage. The other end m of the reactor L is
The output voltage of this DC power supply device is a positive line, and the negative line of the input voltage is a negative line of the output voltage. An output voltage detection circuit 5 is connected between the + line and the − line of the output voltage, and a voltage detection signal from the output voltage detection circuit 5 is input to a switching pulse generation circuit 6. The switching pulse output from the switching pulse generating circuit 6 is sent to the gate of the transistor 2. Reference numeral 7 denotes a switch for turning on / off the operation of the switching pulse generation circuit. Next, the operation of the apparatus having the above configuration will be described. When the switch 7 is turned on to operate the switching pulse generation circuit 6, the switching pulse generation circuit 6
The pulse output from transistor 2 turns on / off transistor 2.
The current is repeatedly turned off, and as a result, an intermittent current flows through the primary coil P of the insulating transformer 1, and an induced voltage is generated in the secondary coil S. This induced voltage is rectified into a DC voltage by the rectifier 3 and the smoothing circuit 4, and the capacitor C is charged with the DC voltage Vi as the output voltage of the inverter circuit. Therefore,
The output voltage of this device is the input voltage 24V + the output voltage Vi of the inverter circuit. The voltage of (24V + Vi) is detected by the output voltage detection circuit 5, and the voltage detection signal is fed back to the switching pulse generation circuit 6, so that the output voltage Vi of the inverter circuit is reduced.
The frequency width of the switching pulse output from the switching pulse generation circuit 6 is controlled so as to be 24V. As a result, when the switch 7 is on, the output voltage of this device is kept constant at 48V. On the other hand, when the switch 7 is turned off, nothing is output from the switching pulse generating circuit 6, so that the transistor 2 remains off, no current flows through the primary coil P of the insulating transformer 1, and the voltage of the secondary coil S Is 0V. In this state, the + potential of the input voltage passes through the secondary coil S of the insulating transformer 1 and is guided to the + line of the output voltage via the rectifier 3 and the reactor L of the smoothing circuit 4, so that the + potential of the output voltage is increased.
The input voltage of 24 V is directly output between the line and the-line. By turning on or off the switch 7 in this manner, 48 V or 24 V is output as the output voltage of this device. When the switch 7 is turned off, the input voltage 24V is output as it is as the output voltage, so that the switch 7 is turned on. However, no switching pulse is output due to, for example, a failure of the switching pulse generating circuit 6. Even in such a case, since the input voltage of 24 V is secured as the output voltage, power can be supplied to the wireless communication device, so that the reliability is high. At this time, the secondary coil S of the insulating transformer 1 and the reactor L of the smoothing circuit 4
However, since the DC current always flows, the number of turns of the coil is small because the switching frequency is higher than that of the transformer used for the commercial frequency, and therefore, the current loss due to the coil is small. Further, if the required rated capacity of the device is 500 W, the inverter circuit can be configured to be small because the output capacity of the half is 250 W, and the conversion efficiency is high because 24 V is output as it is. The above embodiment is of a half-wave rectifier using one rectifier and is suitable for a relatively small-capacity DC power supply. As the large-capacity DC power supply, a full-wave rectifier shown in FIG. 2 is used. Are suitable. In FIG. 2, parts having the same functions as those in FIG. 1 are denoted by the same reference numerals. Reference numerals 11 and 12 denote line filters provided on the input voltage side and the output voltage side of the device for preventing noise loss.
Two switching transistors 2A and 2B are provided as switching transistors.
Connected to A and 2B sources, respectively. The drains of these transistors 2A and 2B are connected to tap portions on both sides of the primary coil P of the insulating transformer 1 'with a center tap, and are connected to the + line of the center tap input voltage of the primary coil P. Secondary coil S of insulation transformer 1 '
A rectifier 3 'for full-wave rectification is connected to the taps on both sides of the secondary coil S.
Connected to line. After the rectifier 3 ', a smoothing circuit 4 and an output voltage detecting circuit 5 are provided as in the previous embodiment. The switching pulse output from the switching pulse generating circuit 6 is input to the flip-flop circuit 13 and also to one input of each of the two AND gates 14 and 15. The output terminal Q and the inverted output terminal of the flip-flop circuit 13 are connected to the other input terminals of the AND gates 14 and 15, respectively. Each output section of these AND gates 14 and 15 is controlled by each gate G ₁ and G ₂ of the transistors 2A and 2B. The operation of the device having the above configuration will be described below. In response to the switching pulse output from the switching pulse generating circuit 6, a signal that switches between 1, 0, 1, 0... Is output from the output terminal Q of the flip-flop circuit 13, and 0, 1, and 0 are output from the inverted output terminal. 0, 1 ... signals are output. Therefore, when a pulse is output from the switching pulse generation circuit 6, one of the AND gates 14 and 15 is turned on and "1" is output, so that the transistors 2A and 2B are alternately turned on. Now, during the period when the transistor 2A is on, a current flows in the upper half of the primary coil P of the insulating transformer 1 'in the direction of the arrow in the figure, and during the next period when the transistor 2B is on, the primary A current flows in the lower half of the coil P in the direction of the arrow. As described above, the alternating current flows through the primary coil P, and the alternating voltage induced in the secondary coil S by this alternating current is full-wave rectified by the rectifier 3 '. By the inverter circuit having this circuit configuration, the capacitor C is charged with 24 V as in the previous embodiment, and the output voltage of this device becomes 48 V. On the other hand, when the switch 7 is turned off, or when the transistors 2A and 2B do not perform the switching operation due to the failure of the switching pulse generation circuit 6 or the like despite the switch 7 being turned on, the input voltage + Since the electric potential is guided from the center tap of the secondary coil S of the insulating transformer 1 'to the rectifier circuit 3' and thereafter via the secondary coil S, the output voltage is 24 V of the input voltage as in the previous embodiment.
Is output.

【The invention's effect】

As described above, the present invention is configured such that the output voltage of the inverter circuit is added to the input voltage of the DC power supply device, and the input voltage is output as it is when the inverter circuit is stopped. Since the transmitter output is switched by turning the circuit on and off,
Even in case of failure, the communication device can be operated with the battery voltage,
In addition, when the battery is operated at the battery voltage, the inverter circuit can be stopped, so that there is no circuit loss.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing one embodiment of a DC power supply device according to the present invention, and FIG. 2 is a circuit diagram of a DC power supply device showing another embodiment based on the present invention. 1,1 '…… Insulation transformer, 2,2A, 2B …… Transistor, 3,
3 ': rectifier, 4: smoothing circuit, 5: output voltage detection circuit, 6: switching pulse generation circuit, 7: switch, 11, 12 ... noise filter, 13: flip-flop circuit, 14, 15 ... And Gate.

Continuation of the front page (58) Field surveyed (Int. Cl. ⁶ , DB name) H02M 3/00-3/44 H04B 1/02-1/04

Claims (1)

(57) [Claims] 1. A DC power supply for supplying a voltage to a final stage of a transmitter, wherein a switching current flows an intermittent current to a primary side of an insulating transformer, and an induced voltage generated on a secondary side of the insulating transformer is generated. An inverter circuit that obtains a DC voltage by rectification by a rectifier circuit is connected in series so that the output voltage (Vo) of the inverter circuit is added to the voltage (Vb) of the battery for driving the inverter circuit. A transmitter output switching method characterized in that a voltage (Vb) is supplied when the circuit is stopped, and a voltage (Vb + Vo) is supplied to the final stage of the transmitter when the inverter circuit is operating, thereby switching the transmitter output.