JPH08161090A - Power supply circuit for slave device - Google Patents

Abstract

PURPOSE: To supply a required power to a slave device by providing a constant voltage circuit which generates the detected output in the case of a charging voltage higher than a prescribed value and controls opening/closing in accordance with the presence/absence of the detected output and is arranged on the output side of an open/close circuit and stabilizes the supply voltage supplied to the slave device. CONSTITUTION: Positive of negative voltages led out to first and second control sources 10C1 and 10C2 and a first signal line 10S1 of an interface 1 are always charged to a charging circuit 6. Only when the charging voltage of the charging circuit 6 is higher than the prescribed value, it is supplied as the supply voltage to a slave device 2. Therefore, voltages led out to first and second control sources 10C1 and 10C2 and the first signal line 10C1 of the interface 1 arranged in a host control device can be used as the supply voltage without using an AC adapter or a private battery even if the power consumption of the slave device 2 is relatively high like a bar code scanner.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply circuit of a slave device, and more particularly, to a slave such as a control line and a signal line of an interface provided in a host control device such as a personal computer (personal computer) and a bar code scanner. The present invention relates to a power supply circuit for a slave device that is connected to a power terminal of the device and that supplies a stable operating voltage to the power terminal of the slave device regardless of the voltage polarities derived to the control line and the signal line.

[0002]

2. Description of the Related Art RS generally used in personal computers
The 232C type interface has two control lines RT
Derivation pins of S and DTR and two signal lines TXD and RXD
Is provided with a derivation pin. The RS232C type interface outputs a high level (positive voltage) to the two control lines RTS and DTR when the line is open, and outputs the two control lines RTS and DTR when the line is closed.
A low level (negative voltage) is output to TR. When no signal is output, a low level (negative voltage) is output to the signal lines TXD and RXD, and when a signal is output, a high level (positive voltage) and a low level are output to the signal lines TXD and RXD according to the signal. The levels (negative voltage) are output alternately.

Conventionally, a serial mouse has been known as a slave device of a personal computer which operates by using a voltage obtained on a control line and a signal line of an RS232C type interface as a power source. When a positive voltage is obtained on the control line and signal line of the RS232C interface, the serial mouse uses this positive voltage as an operating power source and operates the serial mouse without separately providing an external power source. Is.

By the way, since the serial mouse is a minute power consumption device whose current consumed inside is 10 mA or less, it is possible to use the positive voltage obtained in the control line and signal line of the RS232C type interface. However, in the case of a barcode scanner, which is a slave device of the same personal computer, the current consumed internally is about 40 mA to 100 mA, so use the positive voltage obtained on the control line and signal line of the RS232C type interface. I can't. Therefore, when using a bar code scanner, an AC (alternating current) adapter is connected to the bar code scanner, a commercial AC voltage of 100 V is converted into a low voltage direct current by the AC adapter, and the bar code scanner is operated with this low voltage direct current. Was doing.

[0005]

When the bar code scanner is operated by the AC adapter, the wiring of the power source of the bar code scanner becomes complicated, and in some cases, the volume of the AC adapter becomes larger than that of the bar code scanner. Alternatively, the AC adapter becomes heavier than the bar code scanner, and there is a problem that the AC adapter is extremely obstructive in operating the bar code scanner.

Further, in a portable personal computer such as a notebook personal computer, the personal computer itself is operated by a battery, so that the commercial AC voltage of 100 V may not be used at all. In such a case, the commercial AC voltage of 100 V cannot be used as the power source of the bar code scanner through the AC adapter, so a separate battery must be prepared as the power source of the bar code scanner, which is difficult to use. There are also problems.

The present invention solves the above problems,
An object of the invention is to provide a power supply circuit for a slave device that can supply a required power from the interface of the host control device even to a slave device that consumes a relatively large amount of power.

[0008]

In order to achieve the above object, the present invention is provided between a control line and a signal line of an interface arranged in a host control device and a power supply terminal of a slave device, and the above-mentioned control is provided. Rectifying and adding circuit for rectifying and adding one polarity voltage or other polarity voltage derived from the line and the signal line to the same polarity, a charging circuit for charging the output of the rectifying and adding circuit, and a charging voltage for the charging circuit Then, a voltage detection circuit that generates a detection output when the charging voltage is equal to or higher than a predetermined value, and is connected in series to the output side of the charging circuit,
An opening / closing circuit whose opening / closing is controlled according to the presence / absence of a detection output of the voltage detecting circuit, and arranged on the output side of the opening / closing circuit,
And a constant voltage circuit for stabilizing the power supply voltage supplied to the slave device.

In order to achieve the above-mentioned object, the present invention is provided between a control line and a signal line of an interface arranged in a host control device and a power supply terminal of a slave device, and the control line and the signal line are provided. A rectifying and adding circuit for rectifying and adding one-polarity electric power or the other-polarity electric power output from the same polarity, a secondary battery circuit for charging the output of the rectifying and adding circuit through a constant current circuit, and the constant current circuit A current value setting circuit for setting a constant current value, a charge / discharge detection circuit for detecting charging / discharging of the secondary battery circuit, a charging voltage of the secondary battery circuit is detected, and the charging voltage is a predetermined value or more. A voltage detection circuit that sometimes generates a detection output, and an opening / closing circuit that is connected in series between the output of the secondary battery circuit and the slave device and is controlled to open or close according to the presence or absence of the detection output of the voltage detection circuit. And The current value setting circuit, the constant current setting value by the detection output of the output and the voltage detection circuit of the charge-discharge detection circuit comprises a second means to be adjusted.

[0010]

According to the first means, first, the rectifying and adding circuit applies the one polarity voltage or the other polarity voltage derived to the control line and the signal line of the interface arranged in the host control equipment to the same polarity. Rectification and addition are performed to generate a DC voltage of one polarity. Next, the charging circuit charges the DC voltage obtained by the rectification addition. Then, the voltage detection circuit detects the charging voltage of the charging circuit and generates a detection output when the charging voltage is equal to or higher than a predetermined value. Further, the switching circuit is controlled so as to be closed when the detection output is output from the voltage detection circuit and opened at other times,
When closed, it supplies the charging voltage of the charging circuit to the next constant voltage circuit. Finally, the constant voltage circuit stabilizes the voltage supplied from the switching circuit and supplies it to the slave device as a power supply voltage.

As described above, according to the first means, the positive voltage or the negative voltage led to the control line and the signal line of the interface is always charged in the charging circuit.
Moreover, since the power is supplied to the slave device as the power supply voltage only when the charging voltage of the charging circuit is equal to or higher than a predetermined value, even if the power consumption of the slave device is relatively large like a bar code scanner, the AC adapter or It is possible to use the voltage derived to the control line and signal line of the interface arranged in the host control device as the power supply voltage without using a dedicated battery, which is a slave with excellent portability and easy connection. The power supply circuit of the device can be obtained.

According to the second means, first, the rectifying and adding circuit applies the one polarity voltage or the other polarity voltage derived to the control line and the signal line of the interface arranged in the host control equipment to the same polarity. Rectified and added to become 1
Generates a polar DC voltage. Then, the constant current circuit supplies the direct current obtained by the rectification and addition to the next secondary battery circuit in the form of a constant current under the control of the current value setting circuit. The secondary battery circuit is charged by the constant current supplied from the constant current circuit, while it is appropriately discharged when the slave device operates. In this case, the voltage detection circuit detects the charging voltage of the secondary charging circuit and generates a detection output when the charging voltage is equal to or higher than a predetermined value. Furthermore, the switching circuit is controlled so that it closes only when a detection output is obtained from the voltage detection circuit and opens when a detection output is not obtained.When closed, the charging voltage of the secondary charging circuit is supplied to the slave device as the power supply voltage. Supply as. The current value setting circuit adjusts its constant current setting value according to the output obtained from the charge / discharge detection circuit of the secondary battery circuit and the detection output obtained from the voltage detection circuit.

As described above, according to the second means, the positive voltage or the negative voltage derived on the control line and the signal line of the interface can be always charged in the secondary battery circuit, and the secondary battery circuit can be charged. Only when the charging voltage of the battery circuit is above a predetermined value, it is supplied to the slave device as the power supply voltage, and the charging speed of the secondary battery circuit is changed according to the charging state and charging voltage of the secondary battery circuit. Therefore, even if the power consumption of a slave device such as a bar code scanner is relatively high, the control line and signal line of the interface arranged in the host control device can be used without using an AC adapter or a dedicated battery. It is possible to use the voltage derived to the power supply voltage as a power supply voltage, and it is possible to obtain a power supply circuit for a slave device that is excellent in portability and is easy to connect.

[0014]

Embodiments of the present invention will now be described in detail with reference to the drawings.

FIG. 1 is a block diagram showing a first embodiment of a power supply circuit for a slave device according to the present invention, in which a host controller is a personal computer and an interface arranged in the host controller is an RS232C type interface. Each of them is used, and an example in which a barcode scanner is used as a slave device is shown.

As shown in FIG. 1, RS232C type a
Interface 1 is in a personal computer (host controller).
Arranged from a plurality of pins (not shown) each first
Control line 10_C1, The second control line 10_C2, The first signal line 10
_S1, The second signal line 10_S2Is derived. Barcode scan
Jana (slave device) 2 has multiple pins (not shown)
Power line 11 and first control line 10 respectively_C1, The first signal
Line 10_S1, The second signal line 10_S2Are connected. Power supply
The device 3 includes a rectifying circuit unit 4, a polarity reversing circuit 5, and a buffer.
Diode 5a for power supply and an electric double layer capacitor, etc.
Large-capacity capacitor (charging circuit) 6 and voltage detection circuit 7
A switching circuit (switching circuit) 8 and a constant voltage circuit 9
Composed of and. Among them, the rectifier circuit unit 4 includes the first to
Third diode, preferably first to third shots
Key barrier diode 4₁ Through 4 ₃The first set consisting of
Current circuit 4a and fourth to sixth diodes, preferably
Fourth to sixth Schottky barrier diodes 4_Four Through
4₆And a second set of rectifying circuit 4b
Circuit part 4, polarity reversing circuit 5, and buffer diode
The card 5a constitutes a rectifying and adding circuit.

Then, in the first set of rectifying circuits 4a,
The anode of the first diode 4 ₁ is the first control line 10 _C1.
In addition, the anode of the second diode 4 ₂ is connected to the second control line 1
0 _C2 , the anode of the _third diode 4 ₃ is connected to the first signal line 10 _S1 , the cathodes of the _{first to} third diodes 4 _{1 to} 4 ₃ are commonly connected, and the summing point M
(One end of the large-capacity capacitor 6). In the second set of rectifier circuits 4b, the cathode of the _fourth diode 4 ₄ is on the first control line 10 _C1 , the cathode of the _fifth diode 4 ₅ is on the second control line 10 _C2 , and the sixth diode 4 is ₆
The cathodes of are connected to the first signal line 10 _S1 , respectively,
The anodes of the fourth to _sixth diodes 4 _{4 to} 4 ₆ are commonly connected and connected to the input of the polarity inverting circuit 5. The polarity inverting circuit 5 has a buffer diode 5a in series with the output.
Is connected to the anode, and the cathode is connected to the addition point M (one end of the large-capacity capacitor 6). The large-capacity capacitor 6 is shunt-connected to the addition point M, and has one end connected to the addition point M and the other end connected to the ground point. The input of the voltage detection circuit 7 is the addition point M (large-capacity capacitor 6
The output is connected to the control terminal of the switching circuit 8, respectively. The switching circuit 8 has an input connected to the addition point M (one end of the large-capacity capacitor 6) and an output connected to the input of the constant voltage circuit 9. The output of the constant voltage circuit 9 is connected to the power supply line 11.

The power supply circuit 3 of the slave device of the first embodiment having the above structure operates as follows.

RS232C now installed in a personal computer
When a positive voltage is derived to the first control line 10 _C1 of the mold interface 1, this positive voltage is added as a positive voltage via the first diode 4 ₁ of the rectifier circuit 4a of the first set to the addition point M and the large capacity. The large capacity capacitor 6 is supplied to the capacitor 6.
Is charged with a positive voltage. On the other hand, when a negative voltage is derived on the first control line 10 _C1 , this negative voltage is supplied to the polarity reversing circuit 5 via the fourth diode 4 ₄ of the rectifier circuit 4b of the second set, and the negative voltage is The polarity is inverted to become a positive voltage, and this positive voltage is supplied to the addition point M and the large-capacity capacitor 6 via the buffer diode 5a, and similarly, the large-capacity capacitor 6 is charged with the positive voltage. Also, RS2
If a positive voltage is derived in the second control line 10 _C2 of 32C-type interface 1, the positive voltage summing point M and large a positive voltage through a second diode 4 ₂ of the first set of rectifier circuits 4a It is supplied to the capacitor 6 and the capacitor 6 is charged with this positive voltage. On the other hand, when a negative voltage is derived on the second control line 10 _C2 , this negative voltage is supplied to the polarity reversing circuit 5 via the fifth diode 4 ₅ of the rectifying circuit 4b of the second set, and the voltage of the voltage is inverted there. The polarity is inverted to become a positive voltage, and this positive voltage is supplied to the addition point M and the large-capacity capacitor 6 via the buffer diode 5a, and similarly, the large-capacity capacitor 6 is charged with the positive voltage. Further, when a signal is led to the first signal line 10 _S1 of the RS232C type interface 1 and the polarity of the signal is positive, this positive voltage is the third voltage of the rectifier circuit 4a of the first set.
It is supplied as a positive voltage to the addition point M and the large-capacity capacitor 6 through the diode 4 ₃ of the above, and the large-capacity capacitor 6 is charged with this positive voltage. On the other hand, when a signal is led to the first signal line 10 _S1 and the polarity of the signal is negative, this negative voltage is inverted in polarity via the sixth diode 4 ₆ of the rectifier circuit 4b of the second set. It is supplied to the circuit 5, where the polarity of the voltage is inverted to become a positive voltage, and this positive voltage is supplied to the addition point M and the large-capacity capacitor 6 via the buffer diode 5a. 6 is charged with a positive voltage. In this way, no matter which polarity voltage or signal is derived to the first and second control lines 10 _C1 , 10 _C2 and the first signal line 10 _S1 , it corresponds to the magnitude of the voltage or the signal amplitude. The positive voltage is supplied to the large-capacity capacitor 6, and the large-capacity capacitor 6 is charged with this positive voltage. At this time, when the bar code scanner 2 is not operating and the discharge current is not taken out from the large-capacity capacitor 6, the large-capacity capacitor 6 has the maximum voltage of the first and second control lines 10 _C1 and 10 _C2. A positive voltage of a value or a value corresponding to the maximum value of the signal amplitude of the first signal line 10 _S1 is charged.

The positive voltage charged in the large-capacity capacitor 6 is supplied to the voltage detection circuit 7 and the switching circuit 8, respectively. In this case, the voltage detection circuit 7 generates a detection output when the value of the positive voltage exceeds the operable voltage of the barcode scanner 2, and this detection output is supplied to the control terminal of the switching circuit 8. . When the detection output is supplied to the control terminal, the switching circuit 8 closes the circuit and supplies the positive voltage of the large capacity capacitor 6 to the constant voltage circuit 9. The constant voltage circuit 9 stabilizes the voltage value of the supplied positive voltage and supplies the stabilized positive voltage to the barcode scanner 2 as a power supply voltage via the power supply line 11. At this time, if the bar code scanner 2 is in an operating state, the positive voltage discharged from the large-capacity capacitor 6 is larger than the positive voltage charged in the large-capacity capacitor 6, and the large-capacity capacitor 6 is discharged. The value of the positive voltage gradually decreases. Then, when the voltage detection circuit 7 detects that the value of the positive voltage of the large-capacity capacitor 6 has become lower than the operable voltage of the bar code scanner 2, it stops generating the detection output that has been output until then. The detection output is no longer supplied to the control terminal of the switching circuit 8 and the switching circuit 8 is opened. Therefore, the positive voltage of the large-capacity capacitor 6 is blocked by the switching circuit 8 and is not supplied to the barcode scanner 2, and the operation of the barcode scanner 2 is stopped, so that the barcode scanner 2 consumes power. There is no. In such a state, when the large-capacity capacitor 6 continues to be charged and the positive voltage value of the large-capacity capacitor 6 exceeds the operable voltage of the barcode scanner 2 again, switching is performed by the detection output output from the voltage detection circuit 7. Since the circuit 8 is closed, the power supply voltage is supplied to the barcode scanner 2 and the barcode scanner 2 becomes operable. In this case, since the barcode scanner 2 operates intermittently, charging and discharging of the large capacity capacitor 6 are alternately repeated.

On the other hand, when the power of the personal computer is turned off, RS
The voltage derived from the first control line 10 _C1 and the second control line 10 _C2 of the 232C type interface 1 is the ground voltage (0 V), and the signal amplitude derived from the first signal line 10 _S1 is also the ground voltage. (0V). At this time, the value of the positive voltage of the large-capacity capacitor 6 gradually decreases due to current consumption in the bar code scanner 2, but when the value becomes lower than the operable voltage of the bar code scanner 2, the voltage detection circuit. Since the generation of the detection output output from 7 is stopped and the switching circuit 8 is opened, the power supply voltage is not supplied to the barcode scanner 2. Therefore, the positive voltage value of the large-capacity capacitor 6 is kept at a voltage slightly lower than the operable voltage of the bar code scanner 2, and the voltage detection circuit 7 is
Since it is configured to operate with a very small current, for example, several μA, when the power supply of the personal computer is turned on next time, the large-capacitance capacitor 6 can operate the voltage of the bar code scanner 2 within an extremely short time. The power supply circuit 3 of the slave device can be normally operated.

As described above, according to the first embodiment, the first and second control lines 10 _C1 and 10 _C2 of the interface 1 are used.
The positive voltage is constantly charged in the large-capacity capacitor 6 due to the voltage derived in (1) and the signal derived in the first signal line 10 _S1. Since the positive voltage is supplied to the bar code scanner 2 as a power supply voltage only when the code scanner 2 is at an operable voltage, even if the bar code scanner 2 consumes a relatively large amount of power, an AC adapter is required. Without using a dedicated battery or a dedicated battery, the voltage derived from the first and second control lines 10 _C1 and 10 _C2 of the RS232C type interface 1 arranged in the personal computer and the signal line derived from the first signal line 10 _S1 are derived. The signal can be used as the power supply voltage, and the power supply circuit of the slave device having excellent portability and easy connection can be obtained.

Next, FIG. 2 is a block diagram showing a second embodiment of a power supply circuit for a slave device according to the present invention. As in the first embodiment, a host controller is a personal computer, R on the interface of the host controller
This shows an example in which S232C type interfaces are used and a barcode scanner is used as a slave device.

The difference in configuration between the second embodiment and the first embodiment is that in the first embodiment, a large-capacity capacitor 6 is provided between the addition point M and the input of the switching circuit 8.
In the second embodiment, the constant current circuit 12, the secondary battery 13, and the current value setting circuit 14 are connected between the addition point M and the input of the switching circuit 8.
And a point where the charge / discharge detection circuit 15 is connected, and
In the first embodiment, the output of the switching circuit 8 and the power supply line 1
While the constant voltage circuit 9 is connected between the output of the switching circuit 8 and the power supply line 11,
There is no difference in structure between the second embodiment and the first embodiment except that they are directly connected to each other.

In the second embodiment, the constant current circuit 12
Has an input connected to the addition point M and an output connected to the secondary battery 13, and the secondary battery 13 is connected to the input of the voltage detection circuit 7 and the input of the switching circuit 8, respectively. The current value setting circuit 14 sets the value of the constant current flowing through the constant current circuit 12, the input of which is connected to the output of the voltage detection circuit 7 and the output of the charge / discharge detection circuit 15, and the output of which is the constant current circuit 1.
Connected to 2. The input of the charge / discharge detection circuit 15 is connected to the secondary battery 13. In this case, as the secondary battery 13, for example, a nickel-cadmium (nickel cadmium) battery,
A nickel hydrogen battery is used.

The power supply circuit 3 of the slave device of the second embodiment having the above structure operates as follows. However,
The operation until the positive voltage is derived at the addition point M is the same as the operation of the first embodiment already described, so the description of the operation at this point is omitted.

The positive voltage derived at the addition point M is supplied to the secondary battery 13 via the constant current circuit 12 and sequentially charges the secondary battery 13. In this case, the magnitude of the constant current flowing through the constant current circuit 12 is set by the current value setting circuit 14 as described later. Next, the voltage detection circuit 7 generates a detection output when the value of the positive voltage of the secondary battery 13 exceeds the operable voltage of the barcode scanner 2, and the detection output is supplied to the control terminal of the switching circuit 8. To be done. When the detection output is supplied to the control terminal, the switching circuit 8 closes the circuit and directly supplies the positive voltage of the secondary battery 13 to the barcode scanner 2 as a power supply voltage. If the barcode scanner 2 is in the operating state, the positive voltage discharged from the secondary battery 13 is larger than the positive voltage charged in the secondary battery 13, and the positive voltage of the secondary battery 13 is increased. The voltage value gradually decreases. When the voltage detection circuit 7 detects that the value of the positive voltage of the secondary battery 13 is lower than the operable voltage of the barcode scanner 2, that is, when the overdischarge of the secondary battery 13 is detected, until then. Since the generation of the detection output being output is stopped, the detection output is not supplied to the control terminal of the switching circuit 8 and the switching circuit 8 is opened. Therefore, the positive voltage of the secondary battery 13 is blocked by the switching circuit 8 and is not supplied to the barcode scanner 2, and the operation of the barcode scanner 2 is stopped, so that the barcode scanner 2 does not consume power. The secondary battery 13 will not be discharged any more. In such a state, when the secondary battery 13 continues to be charged and the value of the positive voltage of the secondary battery 13 exceeds the operable voltage of the barcode scanner 2 again, that is, the over-discharged state of the secondary battery 13 is avoided. Then, since the switching circuit 8 is closed by the detection output output from the voltage detection circuit 7, the power supply voltage is supplied to the bar code scanner 2 and the bar code scanner 2
Is ready for operation. The barcode scanner 2
Normally operates intermittently, so charging and discharging of the secondary battery 13 are alternately repeated.

In the second embodiment, the charge / discharge detection circuit 1
Reference numeral 5 detects whether the secondary battery 13 is in a charged state or a discharged state, and supplies the charge detection output or the discharge detection output to the current value setting circuit 14. At the same time, the voltage detection circuit 7 also supplies the detection output to the current value setting circuit 14. When the secondary battery 13 is in the charging state and the value of the positive voltage exceeds the operable voltage of the barcode scanner 2, the current value setting circuit 14 detects the charge from the charge / discharge detection circuit 15. When the output is supplied and the detection output is supplied from the voltage detection circuit 7, the secondary battery 1
In order to avoid overcharging of No. 3, the value of the constant current flowing through the constant current circuit 12 is set to be small. In addition, the current value setting circuit 14 detects the charge detection from the charge / discharge detection circuit 15 when the positive voltage value is equal to or lower than the operable voltage of the barcode scanner 2 even when the secondary battery 13 is in the charged state. When the output is supplied and the detection output is not supplied from the voltage detection circuit 7, the value of the constant current flowing through the constant current circuit 12 is set to be large in order to charge the secondary battery 13 in a short time. Furthermore, when the secondary battery 13 is in a discharged state, the current value setting circuit 14 is irrespective of whether or not the value of the positive voltage thereof exceeds the operable voltage of the barcode scanner 2, that is, the charge / discharge detection circuit. When the discharge detection output is supplied from 15, the value of the constant current flowing through the constant current circuit 12 is set to be large in order to suppress the power consumption of the secondary battery 13.

Also in this second embodiment, when the power of the personal computer is turned off, the RS232C type interface 1
The voltage derived from the first control line 10 _C1 and the second control line 10 _C2 becomes the ground voltage (0V), and the first signal line 1
The signal amplitude derived from 0 _S1 also becomes the ground voltage (0 V). At this time, the value of the positive voltage of the secondary battery 13 gradually decreases due to current consumption in the bar code scanner 2, but when the value becomes lower than the operable voltage of the bar code scanner 2, the voltage detection circuit. Since the generation of the detection output output from 7 is stopped and the switching circuit 8 is opened, the power supply voltage is not supplied to the barcode scanner 2. Therefore, the value of the positive voltage of the secondary battery 13 is kept at a voltage slightly lower than the operable voltage of the barcode scanner 2, and the occurrence of an over-discharged state in the secondary battery 13 can be avoided. it can. Further, when the power of the personal computer is turned on next time, the secondary battery 13 is charged to the operable voltage of the bar code scanner 2 within an extremely short time, as in the first embodiment. The power supply circuit 3 of the device can be operated normally.

As described above, according to the second embodiment, the first and second control lines 10 _C1 and 10 _C2 of the interface 1 are provided.
The positive voltage is constantly charged in the secondary battery 13 due to the voltage derived in step _S1 and the signal derived in the first signal line 10 _S1. Since the positive voltage is supplied to the bar code scanner 2 as a power supply voltage only when the code scanner 2 is at an operable voltage, even if the bar code scanner 2 consumes a relatively large amount of power, an AC adapter is required. RS232C installed in a personal computer without using a dedicated battery
First and second control lines 1 of the mold interface 1
0 _C1 , the voltage derived to 10 _C2 and the first signal line 10 _S1
It is possible to use the signal derived in step 1 as the power supply voltage, and it is possible to obtain a power supply circuit for a slave device that has excellent portability and is easy to connect.

Further, according to the second embodiment, the secondary battery 1
The charging speed of 3 depends on whether the secondary battery 13 is in a charging state or a discharging state, or whether the value of the positive voltage of the secondary battery 13 exceeds the operable voltage of the barcode scanner 2. It depends on the value of the positive voltage of the secondary battery 13 when the secondary battery 13 is discharged and / or the value of the positive voltage of the secondary battery 13.
When the voltage is less than the operable voltage of the slave, the charging speed increases, and in other cases, the charging speed decreases. Therefore, it is possible to prevent the secondary battery 13 from over-discharging or overcharging. A power supply circuit for the device is obtained.

Next, FIGS. 3A and 3B are a circuit configuration diagram and an operation waveform diagram showing an example of the configuration of the polarity reversing circuit 5 used in the first and second embodiments. (A)
Is a circuit configuration diagram, and FIG. 3B is an operation waveform diagram.

As shown in FIG. 3A, the input terminal 22
Is connected to the negative power supply terminal of the oscillator circuit 16 and each negative power supply terminal of the buffer 17a and the inverter (logic circuit) 17b. The output of the oscillation circuit 16 is connected to the input terminal of the buffer 17a and the input terminal of the inverter 17b. The output of the buffer 17a is connected to the anode of the series connection diode 19a and the cathode of the shunt connection diode 20a via the coupling capacitor 18a, and the output of the inverter 17b is connected to the anode of the series connection diode 19b and the shunt connection via the coupling capacitor 18b. It is connected to the cathode of the diode 20b. The cathode of the series connection diode 19a and the cathode of the series connection diode 19b are commonly connected to the output terminal 23 and one end of the smoothing capacitor 21, and the anode of the shunt connection diode 20a, the anode of the shunt connection diode 20b, the smoothing capacitor 21 The ends are commonly connected to ground. The input terminal 21 is the second
It is connected to the output side of the pair of rectifier circuits 4b, and the output terminal 23 is connected to the anode of the buffer diode 5a.

In the above configuration, the second set of rectifier circuits 4b
When a negative DC voltage -V is supplied from the input terminal 21 to the input terminal 21, the power supply voltage is supplied to the oscillation circuit 16, the buffer 17a, and the inverter 17b, respectively, and the oscillation circuit 16, the buffer 17a, and the inverter 17b are activated. At this time, the oscillating circuit 16 is in an oscillating state, and a square wave signal is output from the oscillating circuit 16, and this square wave signal is output to the buffer 1
7a and the inverter 17b. Next, the buffer 17a non-inverts and amplifies the square wave signal, and the point a is shown in FIG.
The square wave signal of the first polarity shown in (b) is output, while the inverter 17b inverts and amplifies the square wave signal, and the square wave signal of the second polarity shown in FIG. Output. Subsequently, the square wave signal of the first polarity is supplied to the series connection diode 19a and the shunt connection diode 20a via the coupling capacitor 18a, and at the same time, the square wave signal of the second polarity is also connected to the series connection diode 19a via the coupling capacitor 18b. 19b and shunt connection diode 20b,
As a result, the positive DC voltage + V shown in FIG.
Is obtained. This DC positive voltage + V is applied to the smoothing capacitor 2
While being charged to 1, it is supplied from the output terminal 23 to the subsequent buffer diode 5a.

In this case, in the polarity reversing circuit 5 of this example, even if the current drawn from the output terminal 23 increases, the absolute level of the direct current positive voltage + V simply decreases, and the voltage within the positive DC voltage + V is reduced. The ripple fluctuation does not increase.

In the first and second embodiments,
Although the host control device is a personal computer, the interface arranged on the host control device is an RS232C type interface, and the slave device is a bar code scanner, the host control device and the interface according to the present invention are described. It goes without saying that the slave device and the slave device are not limited to those, and can be similarly applied to other similar devices.

[0037]

As described above in detail, according to the first and second aspects of the invention, the first interface 1 is provided.
And the second control lines 10 _C1 , 10 _C2 and the first signal line 10
_The positive voltage or negative voltage derived to _S1 is constantly charged in the charging circuit 6, and is supplied as the power supply voltage to the slave device 2 only when the charging voltage of the charging circuit 6 is equal to or higher than a predetermined value. , Even if the power consumption of the slave device 2 is relatively large like a bar code scanner,
The voltage derived from the first and second control lines 10 _C1 , 10 _C2 and the first signal line 10 _S1 of the interface 1 arranged in the host control device is supplied with power without using a C adapter or a dedicated battery. Since it can be used as a voltage, it is possible to obtain a power supply circuit of a slave device which is excellent in portability and easy to connect.

According to the inventions described in claims 3 to 4, the first and second control lines 10 _C1 and 10 _C of the interface 1 are connected.
_The positive voltage or negative voltage derived from _C2 and the first signal line 10 _S1 is constantly charged in the secondary battery circuit 13,
Moreover, only when the charging voltage of the secondary battery circuit 13 is equal to or higher than a predetermined value, the power is supplied to the slave device 2 as a power supply voltage, and the charging speed of the secondary battery circuit 13 is further increased.
Since it is changed according to the charging state and charging voltage of the slave device, even if the power consumption of the slave device 2 is relatively large like a bar code scanner, the host control can be performed without using an AC adapter or a dedicated battery. The first and second control lines 10 _C1 , 10 of the interface 1 arranged on the device
_The voltage derived to _C2 and the first signal line 10 _S1 can be used as a power supply voltage, and it is possible to obtain the power supply circuit of the slave device 2 which has excellent portability and is easy to connect. is there.

[Brief description of drawings]

FIG. 1 is a block diagram showing a first embodiment of a power supply circuit for a slave device according to the present invention.

FIG. 2 is a block diagram showing a second embodiment of the power supply circuit of the slave device according to the present invention.

FIG. 3 is a circuit configuration diagram showing an example of a polarity inverting circuit used in each of the embodiments shown in FIGS. 1 and 2.

[Explanation of symbols]

1 RS232C type interface (interface) 2 Bar code scanner (slave device) 3 Power supply circuit of slave device 4 Rectifier circuit section 4a 1st set of rectifier circuit 4b 2nd set of rectifier circuit 4 _{1 to} 4 ₆ 1st to 6th Diode 5 polarity inversion circuit 5a buffer diode 6 large-capacity capacitor (charging circuit) 7 voltage detection circuit 8 switching circuit (switching circuit) 9 constant voltage circuit 10 _C1 first control line 10 _C2 second control line 10 _S1 Signal line 1 1 Power line 12 Constant current circuit 13 Secondary battery (secondary battery circuit) 14 Current value setting circuit 15 Charge / discharge detection circuit 16 Oscillation circuit 17a Buffer 17b Inverter (logic circuit) 18a, 18b Coupling capacitors 19a, 19b Series connection diode 20a, 20b Shunt connection diode 21 Smoothing capacitor Sensor 22 input terminal 23 output terminal

Claims (5)

[Claims] 1. A voltage of one polarity or another polarity derived from the control line and the signal line, which is provided between the control line and the signal line of the interface arranged in the host control device and the power supply terminal of the slave device. A rectifying and adding circuit that rectifies and adds voltages to the same polarity, a charging circuit that charges the output of the rectifying and adding circuit, and a charging voltage of the charging circuit is detected, and a detection output is generated when the charging voltage is equal to or higher than a predetermined value. And a voltage detection circuit to be connected in series to the output side of the charging circuit,
An opening / closing circuit whose opening / closing is controlled according to the presence / absence of a detection output of the voltage detecting circuit, and arranged on the output side of the opening / closing circuit,
A power supply circuit for a slave device, comprising: a constant voltage circuit for stabilizing a power supply voltage supplied to the slave device. 2. The power supply circuit for a slave device according to claim 1, wherein the charging circuit is a large-capacity capacitor. 3. An electric power of one polarity or another polarity output from the control line and the signal line, which is provided between the control line and the signal line of the interface arranged in the host control device and the power supply terminal of the slave device. A rectifying and adding circuit that rectifies and adds electric power to the same polarity, a secondary battery circuit that charges the output of the rectifying and adding circuit through a constant current circuit, and a current value setting circuit that sets a constant current value of the constant current circuit. A charging / discharging detection circuit for detecting charging / discharging of the secondary battery circuit, a voltage detection circuit for detecting a charging voltage of the secondary battery circuit, and generating a detection output when the charging voltage is equal to or higher than a predetermined value, An output circuit that is connected in series between the output of the secondary battery circuit and the slave device and is controlled to open and close according to the presence or absence of the detection output of the voltage detection circuit, the current value setting circuit, Charge / discharge detection times A power supply circuit for a slave device, wherein the constant current set value is adjusted by the output of the circuit and the detection output of the voltage detection circuit. 4. The power supply circuit for a slave device according to claim 3, wherein the secondary battery circuit is one of a nickel-cadmium battery and a nickel-hydrogen battery. 5. The rectifying and adding circuit includes two sets of rectifying circuits connected so as to have opposite polarities, and a polarity inverting circuit connected in series to one of the rectifying circuits. A power supply circuit for a slave device according to claim 1.