JP2005311441A - Intercom master set and intercom system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an intercom master set and an intercom system suppressing power consumption in a standby state rather than conventional technology. <P>SOLUTION: This intercom master set is provided with a control unit for controlling operations and a power supply unit 118 for supplying driving power to the control unit, and establishes a call with a doorphone slave set. The intercom master set is provided with a power consumption reducing unit 21 for control unit in a standby state. The reducing unit 21 is provided between a power supply unit 118 and the control unit, receives the supply of pulse-like power from a power supply unit 118 while repeating an on-period in which power is supplied and an off-period in which the power is interrupted, accumulates electric charges in a capacitor during the on-period and supplies driving power to the control unit on the basis of the power to be supplied from the unit 118, and supplies the driving power to the control unit 118 during the off-period on the basis of the electric charges accumulated in the capacitor. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an intercom master device that reduces power consumption in a standby state. Then, the present invention relates to an interphone system using the interphone master unit.

  Conventionally, an intercom system is known as a device for a visitor to notify a resident in a dwelling unit of a visit. The intercom system includes a doorphone slave unit having at least a calling function for a visitor to call a resident in a dwelling unit and a call function for a visitor to make a call with the resident, and a visitor by a calling function of the doorphone slave unit An intercom master unit having at least a notification function for notifying a call and a call function for a resident to make a call with a visitor. In recent years, an intercom system with a camera capable of observing the appearance outside the dwelling unit is also known.

  FIG. 4 is a block diagram showing a configuration of an intercom system with a camera according to the background art. FIG. 5 is a diagram illustrating a configuration of a power supply unit according to the background art.

  In FIG. 4, an interphone system 101 with a camera is installed in an interphone master unit (hereinafter abbreviated as “master unit”) 102 installed in a room such as a living room or a dining room, and in an outdoor facility such as a gatepost or a front door. A door phone slave unit (hereinafter abbreviated as “slave unit”) 103 connected to the master unit 102 is provided.

  The slave unit 103 is a door phone slave unit with a camera, and includes a power reception unit 121, a video transmission processing unit 122, an imaging unit 123, a slave unit side demultiplexing unit 124, a call button 125, and a slave unit side audio process. Unit 126 and handset side voice input / output unit 127.

  The imaging unit 123 includes an imaging device that photoelectrically converts a subject light image and outputs a video signal, and an optical system that forms a subject light image on the imaging surface of the imaging device. The video signal of the imaging unit 123 is output to the video transmission processing unit 122. An imaging element is a photoelectric conversion element in which a plurality of light receiving elements that convert received light into electrical signals according to the light intensity are arranged in a matrix, for example, a CCD (Charge-Coupled Devices) or a CMOS (Complementary Metal- Oxide Semiconductor). The video transmission processing unit 122 is a circuit that modulates an input video signal to generate a video modulation signal, and outputs the video modulation signal to the slave-side demultiplexing unit 124.

  The call button 125 is a circuit for transmitting a call signal for ringing a ringing sound from the parent device side sound input / output unit 116 of the parent device 102 to the parent device 102, and is, for example, a push button switch. The call signal is output from the call button 124 to the handset side demultiplexing unit 124. The visitor operates the call button 124 to inform the resident in the dwelling that there is a visitor. The call signal is, for example, that a predetermined high level voltage drops to a predetermined low level voltage, more specifically, a voltage of about 12 V drops to a ground level voltage.

  The handset-side audio processing unit 126 demodulates and amplifies the sound signal from the handset-side demultiplexing unit 124, and then outputs the demodulated signal to the handset-side sound input / output unit 116. The amplified audio signal is amplified and output to the slave unit side demultiplexing unit 124. The handset side sound input / output unit 126 converts the sound signal input from the handset side sound processing unit 125 into sound and reproduces it, and mainly converts the voice of the visitor into a sound signal to convert the sound signal to the handset side. Output to the audio processing unit 125. The handset side sound input / output unit 126 includes a sound input unit that converts sound such as a microphone into a sound signal and a sound output unit that converts sound signal such as a speaker into sound. Alternatively, for example, it is constituted by a speaker that also serves as an audio input / output.

  Slave unit side demultiplexing unit 124 multiplexes the video modulation signal from video transmission processing unit 122, the call signal from call button 125, and the audio signal from slave unit side audio processing unit 126 and transmits the multiplexed signal to base unit 102. At the same time, the audio signal and the DC power supply multiplexed and received from the parent device 102 are separated, the audio signal is output to the child device-side audio processing unit 126, and the DC power supply is output to the power receiving unit 121. The power receiving unit 121 is connected to the video transmission processing unit 122, the imaging unit 123, the slave unit side audio processing unit 126, and the slave unit side audio input / output unit 127, respectively, as indicated by broken lines in the DC power supply from the slave unit side demultiplexing unit 124. Supply.

  On the other hand, base unit 102 includes display unit 111, video reception processing unit 112, operation unit 113, control unit 114, base unit side demultiplexing unit 115, base unit side audio input / output unit 116, and base unit. A side audio processing unit 117 and a power supply unit 118 are provided.

  The base-side demultiplexing unit 115 multiplexes the audio signal from the base-side audio processing unit 117 to the DC voltage from the power supply unit 118 and outputs the multiplexed signal to the handset 103 and is output from the handset 103 and multiplexed. The video modulation signal, paging signal, and audio signal are output to the video reception processing unit 112, the control unit 114, and the parent device side audio processing unit 117, respectively. The control unit 114 includes, for example, a microprocessor, a memory, and the like, and controls each unit of the parent device 102 based on the calling signal from the parent device side demultiplexing unit 115 and the operation signal from the operation unit 113.

  The video reception processing unit 112 is a circuit that demodulates the video modulation signal into a video signal under the control of the control unit 114 and outputs the video signal to the display unit 105. The display unit 111 displays an image of the video signal from the video reception processing unit 112. The display unit 111 is, for example, a CRT display, a liquid crystal display (LCD), an organic EL display, or the like. The operation unit 113 is a circuit that inputs instructions for operating the parent device 102 such as instructions for starting and ending a call between the parent device 102 and the child device 103. 114 is output.

  The base unit side sound processing unit 117 demodulates and amplifies the sound signal according to the control of the control unit 114 and outputs the demodulated signal to the base unit side sound input / output unit 116 and the sound input from the base unit side sound input / output unit 116. The signal is amplified and output to the parent device side demultiplexing unit 115. The base unit side sound input / output unit 116 converts the audio signal input from the base unit side audio processing unit 117 into sound and reproduces it, and mainly converts the resident's sound into an audio signal to convert the audio signal into the base unit side. The data is output to the audio processing unit 116.

  The power supply unit 118 is connected to an AC 100V commercial power supply, and as indicated by a broken line, the display unit 111, the video reception processing unit 112, the control unit 114, the parent device side demultiplexing unit 115, and the parent device side audio input / output unit 116. In addition, driving power is supplied to each unit of the base-side audio processing unit 117.

  When a visitor operates the call button 125 to call a resident, a call signal is transmitted from the child device 103 to the parent device 102, and the control unit 114 switches each part of the parent device 102 from the standby state to the operating state, A ringing tone is output from the base unit side voice input / output unit 116 via the base unit side voice processing unit 117. When switched to the operating state, the video captured by the imaging unit 123 is processed by the video transmission processing unit 122, the slave unit side demultiplexing unit 124, the base unit side demultiplexing unit 115, and the video reception processing unit 112, respectively, and the display unit 111. Then, the master unit 102 and the slave unit 103 are ready to talk. Such an interphone system with a television is disclosed in Patent Document 1, for example.

  The power supply unit 118 will be described in more detail. As shown in FIG. 5, for example, the power supply unit 118 includes an input terminal VCin, output terminals VCout1, VCout2, and VCout3, a diode bridge 201, a DC / DC converter 202, a power supply transformer. 203, a photocoupler 204, a diode D1, a shunt regulator SRG1, a coil L1, and resistors R1, R2, and R3.

  An input terminal VCin to which an AC voltage of about 100 V is input from a commercial power supply is connected to an AC input terminal of a diode bridge 201 that full-wave rectifies the AC voltage into a DC voltage. One DC output terminal of the diode bridge 201 is connected to one input terminal of the power transformer 203, and the other DC output terminal of the diode bridge 201 is grounded. The cathode of the diode D1 is connected to one input terminal of the power transformer 203, and the anode of the diode D1 is connected to the other input terminal of the power transformer 203. The output terminal of the DC / DC converter 202 is connected to the anode of the diode D1 and the other input terminal of the power transformer 203. Both input terminals of the DC / DC converter 202 are connected to both output terminals of the photocoupler 204, respectively. The ground terminal of the DC / DC converter 202 is grounded.

  An output terminal that outputs a DC voltage of about 22 V in the power transformer 203 is connected to the output terminal VCout1. An output terminal that outputs a DC voltage of about 12 V in the power transformer 203 is connected to the output terminal VCout2 via the coil L1. An output terminal that outputs a DC voltage of about 8 V in the power transformer 203 is connected to the output terminal VCout3. One terminal of the coil L1 connected to the power transformer 203 is grounded via the resistor R1 and the shunt regulator SRG1 so that the anode of the shunt regulator SRG1 is grounded, and the other terminal of the coil L1 connected to the output terminal VCout2 is connected. The terminal is grounded through a resistor R2 and a resistor R3. Both ends of the resistor R1 are connected to both input terminals of the photocoupler 204, respectively. A connection point between the resistor R2 and the resistor R3 is connected to a reference terminal of the shunt regulator SRG1.

  The voltage fluctuation in the DC voltage of about 12V of the power transformer 203 is detected by the coil L1, resistors R1, R2, R3 and the shunt regulator SRG1, and the photocoupler 204 which electrically cuts off the input side and the output side of the power transformer 203. Is transmitted to the input terminal of the DC / DC converter 202. The DC / DC converter 202 adjusts the input voltage of the power transformer 203 so as to compensate for this voltage fluctuation. By operating in this way, a stable DC voltage of about 12 V with little voltage fluctuation is output from the output terminal VCout2.

In order to reduce power consumption, such a power supply unit 118 operates only the control unit 114 of the base unit 102 in a standby state waiting for a visitor, and uses the base unit side demultiplexing unit 115 to operate the slave unit 103. In the operation state in which a low voltage is supplied to the mobile phone while a call is made between a visitor and a resident or an outdoor situation is observed, power is supplied to each part of the base unit 102 and the base side demultiplexing unit 115 is connected. A high voltage is supplied to the handset 103 through the power supply. For example, in the standby state, a DC voltage of about 8V is supplied from the output terminal VCout3 of the power supply unit 118 to the control unit 114 of the main unit 102, and a DC voltage of about 12V is output from the output terminal Vout2 of the power supply unit 118. To be supplied. On the other hand, in the operating state, a DC voltage of about 8 V from the output terminal VCout3 of the power supply unit 118 is the display unit 111, the video reception processing unit 112, the control unit 114, the base unit side audio input / output unit 116, and the base unit side. A DC voltage of about 22 V is supplied to the slave unit 103 from the output terminal VCout1 of the power supply unit 118.
JP 2001-245057 A

  Conventionally, in order to reduce power consumption, as described above, in the standby state, power is supplied only to the control unit of the base unit and a voltage lower than the operation state is supplied to the slave unit. There is a demand for further reduction of power consumption by promoting energy saving.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide an interphone master unit that can further suppress power consumption in a standby state as compared with the conventional one. An object of the present invention is to provide an intercom system using such an interphone master unit.

  In order to achieve the above-described object, according to one aspect of the present invention, a control unit that controls operations and a power supply unit that supplies driving power to the control unit are provided, and a call is established between the door phone slave unit. The interphone master unit to be obtained is interposed between the power supply unit and the control unit, and in a standby state waiting for a call from the door phone slave unit, an on period in which power is supplied and an off period in which power is cut off And the pulsed power is supplied from the power supply unit, and in the ON period, electric charge is accumulated in a capacitor and driving power is supplied to the control unit based on the power supplied from the power supply unit, A standby control unit power consumption reduction unit that supplies driving power to the control unit based on the electric charge accumulated in the capacitor in the off period is provided.

  In the interphone master unit described above, an on period in which power is supplied and an off period in which power is cut off are repeated in the standby state, interposed between the supply unit and the power supply unit. Pulsed power is supplied from the power supply unit, charges are accumulated in a capacitor during the on period, and driving power is supplied to the supply unit based on the power supplied from the power supply unit, and the capacitor is supplied during the off period. The apparatus further includes a standby slave unit power consumption reduction unit that supplies driving power to the supply unit based on the electric charge accumulated in the supply unit.

  Further, the above-described intercom master unit further includes a duty ratio setting unit that sets a duty ratio that is a ratio of the time of the on period and the time of the off period to be changeable.

  An interphone system including an interphone master and a door phone slave according to another aspect of the present invention is characterized in that the interphone master is any one of the interphone masters described above.

  The interphone master unit and interphone system configured as described above are configured such that the standby control unit power consumption reduction unit and the standby slave unit power consumption reduction unit are supplied with power from the power supply unit in a pulsed state in the standby state, Since driving power is supplied to the machine, power consumption is reduced.

Embodiments according to the present invention will be described below with reference to the drawings. In addition, the structure which attached | subjected the same code | symbol in each figure shows that it is the same structure, The description is abbreviate | omitted.
(Configuration of the embodiment)
In FIG. 1, an interphone system 1 with a camera according to the present embodiment includes an interphone master unit (hereinafter abbreviated as “master unit”) 2 installed in a room such as a living room or a dining room, a gate pillar, a front door, and the like. A door phone slave unit (hereinafter abbreviated as “slave unit”) 3 installed in an outdoor facility and connected to the master unit 2 is configured. Base unit 2 includes display unit 111, video reception processing unit 112, operation unit 113, control unit 11, base unit side demultiplexing unit 115, base unit side audio input / output unit 116, and base unit side audio. A processing unit 117 and a power supply unit 12 with a reduction function are provided. The subunit | mobile_unit 3 is a door phone subunit | mobile_unit with a camera, The power receiving part 121, the image transmission process part 122, the imaging part 123, the subunit | mobile_unit side demultiplexing part 124, the call button 125, and the subunit | mobile_unit side audio processing part 126 and a handset-side voice input / output unit 127.

  That is, the base unit 2 according to the present embodiment, except that the control unit 11 and the power supply unit 12 with a reduction function are used instead of the control unit 114 and the power source unit 118 of the base unit 102 described with reference to FIG. Since it is the same as the master unit 102 and the door phone slave unit 103 described with reference to FIG. 4, the description of the common configuration is omitted.

  In addition to the function of the control unit 114 described with reference to FIG. 4, the control unit 11 outputs a pulse signal in which a high level and a low level are repeated to the power supply unit 12 in the standby state. Hereinafter, the configuration of the power supply unit 12 with a reduction function, which is a feature of the present embodiment, will be described.

  FIG. 2 is a block diagram illustrating a configuration of a power supply unit with a reduction function according to the embodiment. FIG. 3 is a circuit diagram showing a circuit of the standby control unit power consumption reduction unit and a circuit of the standby slave unit power consumption reduction unit. 3A shows a circuit of the standby control unit power consumption reduction unit, and FIG. 3B shows a circuit of the standby slave unit power consumption reduction unit.

  In FIG. 2, the power supply unit 12 with the reduction function includes an input terminal Vin, output terminals Vout1, Vout2, Vout3-1, Vout3-2, pulse signal input terminals Cin1, Cin2, and a standby control unit power consumption reduction unit 21. And a standby handset power consumption reduction unit 22. That is, the power supply unit 12 with a reduction function includes a standby control unit power consumption reduction unit 21 and a standby slave unit power consumption reduction unit 22 in addition to the power supply unit 118 according to the background art. In the standby state, the power supply unit 118 according to the background art supplies a direct current voltage of about 8V from the power transformer 203 to the control unit 114 as drive power for the control unit 114, and from the power transformer 203 as drive power for the slave unit 103. Although the DC voltage of about 12V is directly supplied to the base-side demultiplexing unit 115, the power supply unit 12 with a reduction function according to the present embodiment is in the standby state from the power supply unit 118 as the driving power of the control unit 11 in the standby state. A DC voltage is supplied to the control unit 11 via the control unit power consumption reduction unit 21, and the base unit side demultiplexing is performed from the power supply unit 118 via the standby slave unit power consumption reduction unit 22 as the operating voltage of the slave unit 103. A DC voltage is supplied to the unit 115.

  In the standby state, the standby control unit power consumption reduction unit 21 is supplied with pulsed power from the power supply unit 118 by repeating an on period in which power is supplied and an off period in which power is cut off. During the period, electric charge is accumulated in the capacitor and driving power is supplied to the control unit 11 based on the electric power supplied from the power supply unit 118. During the off period, driving electric power is supplied to the control unit 11 based on the electric charge accumulated in the capacitor. Supply.

  For example, as shown in FIG. 3A, the standby control unit power consumption reduction unit 21 includes an input terminal VAin connected to the output terminal VCout3 of the power supply unit 118 and an output terminal VAout1 connected to the output terminal Vout3-1. An output terminal VAout2 connected to the output terminal Vout3-2, a pulse signal input terminal CAin connected to the pulse signal input terminal Cin2, regulators RG11 and RG12, transistors Tr11 and Tr12, resistors R11 and R12, R13, R14, R15 and a capacitor C11 are provided.

  The input terminal VAin is connected to the emitter terminal of the pnp transistor Tr11, one terminal of the resistor R13, and the input terminal of the regulator RG11. The regulator RG11 is a circuit that outputs a DC voltage having a stable predetermined voltage value, and is, for example, a three-terminal regulator, a series regulator, a switching regulator, or the like. The predetermined voltage value is a drive voltage value in the circuit to be supplied, and in the present embodiment, a DC voltage of about 5 V is output. The same applies to a regulator RG21 described later.

  The collector terminal of the transistor Tr11 is grounded via the capacitor C11. A resistor R11 is connected between the emitter terminal and the base terminal of the transistor Tr11. The base terminal of the transistor Tr11 is connected to the collector terminal of the transistor Tr12 via the resistor R12. The emitter terminal of the npn transistor Tr12 is grounded. A resistor R14 is connected between the collector terminal and the base terminal of the transistor Tr12. The base terminal of the transistor Tr12 is connected to the pulse signal input terminal CAin via the resistor R15.

  The other terminal of the resistor R13 is connected to the pulse signal input terminal CAin. That is, the other terminal of the resistor R13 is connected to the base terminal of the transistor Tr12 through the resistor R15. The output terminal of the regulator RG11 is connected to the output terminal VAout1. The input terminal of the regulator GR12 is connected to the connection point between the collector terminal of the transistor Tr11 and the capacitor C11, and the output terminal of the regulator GR12 is connected to the output terminal VAout2.

  The standby slave unit power consumption reduction unit 22 is supplied with pulsed power from the power supply unit 118 in the standby state, accumulates charges in the capacitor during the ON period, and is based on the power supplied from the power supply unit 118. The driving power is supplied to the base-side demultiplexing unit 115, and the driving power is supplied to the base-side demultiplexing unit 115 based on the charge accumulated in the capacitor during the off period. The base-side demultiplexing unit 115 is an embodiment of the supply unit of the claims.

  For example, as shown in FIG. 3B, the standby slave power consumption reduction unit 22 has an input terminal VBin1 connected to the output terminal VCout3 of the power supply unit 118 and an input connected to the output terminal VCout2 of the power supply unit 118. A terminal VBin2, an output terminal VBout connected to the output terminal Vout2, a pulse signal input terminal CBin connected to the pulse signal input terminal Cin1, regulators RG21, RG22, transistors Tr21, Tr22, resistors R21, R22, R23, R24, R25 and a capacitor C21 are provided.

  The input terminal VBin1 is connected to the pulse input input terminal CBin via the resistor R23. The emitter terminal of the pnp transistor Tr21 is connected to the input terminal VBin2.

  The collector terminal of the transistor Tr21 is grounded via the capacitor C21. A resistor R21 is connected between the emitter terminal and the base terminal of the transistor Tr21. The base terminal of the transistor Tr21 is connected to the collector terminal of the transistor Tr22 via the resistor R22. The emitter terminal of the npn transistor Tr22 is grounded. A resistor R24 is connected between the collector terminal and the base terminal of the transistor Tr22. The base terminal of the transistor Tr22 is connected to the pulse signal input terminal CBin via the resistor R25. A connection point between the collector terminal of the transistor Tr21 and the capacitor C21 is connected to the output terminal VBout.

  These transistors Tr11, Tr12, Tr21, and Tr22 are examples of switching elements, and are not limited thereto, and may be other switching elements such as FETs.

  Returning to FIG. 2, an AC voltage of about 100 V is input from the commercial power supply to the input terminal Vin, and is connected to the input terminal VCin of the power supply unit 118. The output terminal Vout1 is connected to the output terminal VCout1 of the power supply unit 118, the output terminal Vout2 is connected to the output terminal VBout of the standby slave unit power consumption reduction unit 22, and the output terminal Vout3-1 is consumed by the standby control unit The output terminal VAout1 of the power reduction unit 21 is connected, and the output terminal Vout3-2 is connected to the output terminal VAout2 of the standby control unit power consumption reduction unit 21. The pulse signal input terminal Cin1 is connected to the pulse signal input terminal CBin of the standby slave unit power consumption reduction unit 22, and the pulse signal input terminal Cin2 is the pulse signal input terminal CAin of the standby control unit power consumption reduction unit 21. Connected to.

  Returning to FIG. 1, the output terminal Vout1 is connected to the parent device side demultiplexing unit 115, and the output terminal Vout2 is connected to the parent device side demultiplexing unit 115, the display unit 111, the parent device side audio input / output unit 116, and Connected to the parent device side audio processing unit 117, the output terminal Vout 3-1 is connected to the video reception processing unit 112 and the parent device side sound processing unit 117, and the output terminal Vout 3-2 is connected to the control unit 11. The pulse signal input terminals Cin1 and Cin2 are connected to the control unit 11 and input with a pulse signal.

Next, the operation of this embodiment will be described.
(Operation of the embodiment)
When the intercom system 1 with a camera is installed in a dwelling unit or the like and the input terminal Vin is connected to a commercial power supply, a DC voltage of about 8 V is input from the output terminal VCout3 of the power supply unit 118 to the standby control unit power consumption reduction unit 21. The terminal VAin is output to the input terminal VBin1 of the standby slave unit power consumption reduction unit 22, and a DC voltage of about 12V is output from the output terminal VCout2 of the power supply unit 118 to the input terminal VBin2 of the standby slave unit power consumption reduction unit 22. Is output.

  In the standby control unit power consumption reduction unit 21, when a DC voltage of about 8V is input to the input terminal VAin, the DC voltage of about 8V is applied to the base terminal of the transistor Tr12 via the resistor R13 and the resistor R15. The transistor Tr12 is switched on. When the transistor Tr12 is turned on, the base current of the transistor Tr11 is pulled and the transistor Tr11 is turned on. When the transistor Tr11 is turned on, the capacitor C11 is charged, and a DC voltage of about 8V is input to the regulator RG12. The DC voltage of about 8V is stepped down to about 5V by the regulator RG12 and output from the output terminal VAout2. The DC voltage of about 5V output from the output terminal VAout2 is output to the control unit 11 as drive power.

  When the driving power is supplied, the control unit 11 is activated and outputs a pulse signal having a predetermined duty ratio to the input terminal CAin. The predetermined duty ratio is, for example, a duty ratio of 0.5 in which the ratio of the time between the high level and the time between the low level is 1: 1.

  When a pulse signal is input to the input terminal CAin, the transistor Tr12 is turned on and off according to the high level signal and the low level signal of the pulse signal. The transistor Tr11 is turned on and off in response to the transistor Tr12 being turned on and off.

  When the transistor Tr11 is turned on and off, while the transistor Tr11 is turned off (off period), the power supply of about 8V DC voltage is stopped from the output terminal VCout2 of the power supply unit 118, and the power consumption is reduced. For example, by setting the duty ratio to 0.5, the power consumption of the DC voltage of about 8V in the standby state can be reduced to about half of the conventional one. While the transistor Tr11 is on (on period), the capacitor C11 is charged, a DC voltage of about 8V is input to the regulator RG12, and the DC voltage stepped down to about 5V by the regulator R12 is output via the output terminal VAout2. While supplied to the control unit 11, during the off period, the capacitor C11 outputs a DC voltage to the regulator RG12 by the charged charge, and the DC voltage stepped down to about 5V by the regulator R12 is controlled via the output terminal VAout2. Is output to the unit 11. In the capacitor C11, the voltage output to the regulator RG12 gradually drops from about 8V due to the discharge of electric charge. However, before exceeding the allowable range of the fluctuation range of the input voltage in the regulator RG12, the transistor Tr11 is turned on by the pulse signal, and the capacitor C11 Voltage is restored.

  Thus, since the capacity of the capacitor C11 is provided to ensure the power supplied to the regulator RG12 during the low level of the pulse signal, the time between the low level in the duty ratio of the pulse signal and the regulator When it is determined according to the allowable range of the fluctuation range of the input voltage in the RG 12 and a relatively large capacity is required, an electrolytic capacitor is employed.

  In the standby control unit power consumption reduction unit 21, the DC voltage of about 8V input to the input terminal VAin is stepped down to about 5V by the regulator RG11 and output from the output terminal VAout1. The DC voltage of about 5V output from the output terminal VAout1 is output as drive power to the video reception processing unit 112 and the parent device side audio processing unit 117 via the output terminal Vout3-1. Since the operation of the unit 112 and the base-side audio processing unit 117 is stopped according to the control of the control unit 11, power is not consumed.

  Here, since the transistor Tr11 and the transistor Tr12 operate in response to the pulse signal as described above, the on-period time during which power is supplied from the output terminal VCout3 of the power supply unit 118 to the standby control unit power consumption reduction unit 21; The duty ratio, which is the ratio of the off period during which power is cut off, approximately corresponds to the duty ratio of the pulse signal, which is the ratio of the time between the high level of the pulse signal and the time between the low level. become.

  On the other hand, in the standby slave power consumption reduction unit 22, when a DC voltage of about 8V is input to the input terminal VBin1 and a DC voltage of about 12V is input to the input terminal VBin2, a DC voltage of about 8V from the input terminal VBin1. The voltage is applied to the base terminal of the transistor Tr22 via the resistor R23 and the resistor R25, and the transistor Tr22 is switched on.

  When the transistor Tr22 is turned on, the base current of the transistor Tr21 is pulled and the transistor Tr21 is turned on. When the transistor Tr21 is turned on, the capacitor C21 is charged, and a DC voltage of about 12V input to the input terminal VBin2 is output from the output terminal VBout. A DC voltage of about 12 V output from the output terminal VBout is output to the parent device side demultiplexing unit 115. Then, according to the control of the control unit 11, the base unit side demultiplexing unit 115 outputs the DC voltage of about 12V to the power receiving unit 121 via the slave unit side demultiplexing 124, and the power receiving unit 121 The DC voltage is output as drive power to the video transmission processing unit 122, the imaging unit 123, the call button 125, the slave unit side voice input / output unit 126, and the slave unit side voice processing unit 127.

  During this time, the control unit 11 is activated and outputs a pulse signal having a predetermined duty ratio to the input terminal CBin. The predetermined duty ratio is, for example, a duty ratio of 0.5 in which the ratio of the time in the high level period to the time in the low level period is 1: 1.

  When a pulse signal is input to the input terminal CBin, the transistor Tr22 is turned on and off in response to a high level signal and a low level signal of the pulse signal. Then, the transistor Tr21 is turned on and off according to the on and off of the transistor Tr22.

  When the transistor Tr21 is turned on and off, the supply of a DC voltage of about 12 V from the output terminal VCout2 of the power supply unit 118 is stopped while the transistor Tr21 is off (off period), so that power consumption is reduced. While the transistor Tr21 is on (on period), the capacitor C21 is charged, and a DC voltage of about 12V from the input terminal VBin2 is supplied to the parent device side demultiplexing unit 115 via the output terminal VBout. During the off period of the transistor Tr21, a DC voltage is supplied to the parent device side demultiplexing unit 115 by the capacitor C21 through the output terminal VBout by the charged electric charge. Capacitor C21 causes the transistor Tr21 to be turned off by a pulse signal before the voltage output to base unit demultiplexing unit 115 gradually drops from about 12V due to electric charge discharge, but before the allowable range of fluctuation of input voltage in handset 3 is exceeded. It turns on and the voltage of the capacitor C21 is recovered.

  As described above, the capacity of the capacitor C21 is provided to secure the power supplied to the parent device side demultiplexing unit 115 during the low level of the pulse signal. Since it is provided to ensure the DC voltage to be supplied, it is determined according to the time between the low level in the duty ratio of the pulse signal and the allowable range of the fluctuation range of the input voltage in the slave unit 3, etc. When a large capacity is required, an electrolytic capacitor is used.

  In a test example in which the duty ratio of the pulse signal input to the input terminal CBin is set to 0.5, the power consumption at a DC voltage of about 12 V supplied from the output terminal VCout2 of the power supply unit 118 is reduced by about 15%. It was done.

  Here, since the transistor Tr21 and the transistor Tr22 operate according to the pulse signal as described above, the on period time during which power is supplied from the output terminal VCout2 of the power supply unit 118 to the standby slave unit power consumption reduction unit 22 and The duty ratio, which is the ratio of the off period during which power is cut off, approximately corresponds to the duty ratio of the pulse signal, which is the ratio of the time between the high level of the pulse signal and the time between the low level. become.

  In such a standby state, when a visitor operates the call button 125 of the child device 3 to call a resident, the child device 3 transmits a call signal to the parent device 2. When detecting the calling signal, the control unit 11 of the base unit 2 constantly changes the pulse signal to a high level signal and outputs it to the input terminal CAin and the input terminal CBin. In response to the constantly high level signal, the standby control unit power consumption reduction unit 21 always turns on the transistor Tr12 and the transistor Tr11 and outputs a DC voltage of about 5 V from the output terminal VAout2. Then, by this constantly high level signal, in the standby slave unit power consumption reduction unit 22, the transistor Tr22 and the transistor Tr21 are always turned on, and a DC voltage of about 12 V is stably output from the output terminal VBout.

  The control unit 11 operates based on a DC voltage of about 5 V output from the output terminal VAout2, that is, from the output terminal Vout3-2. The control unit 11 then outputs a DC voltage of about 12V output from the output terminal VBout, that is, the output terminal Vout2, and a DC voltage of about 5V output from the output terminal VAout1, that is, the output terminal Vout3-1. The video reception processing unit 112 and the base unit side audio processing unit 117 are operated based on the above, and the display unit 111 and the base unit side audio input / output unit 116 are operated based on the DC voltage of about 12 V output from the output terminal Vout2. Respectively. Also, the control unit 11 causes the parent device side demultiplexing unit 115 to output a DC voltage of about 22 V output from the output terminal VCout1, that is, from the output terminal Vout1. The slave unit side demultiplexing unit 124 outputs the DC voltage of about 22 V output from the base unit side demultiplexing unit 115 to the power receiving unit 121, and the power receiving unit 121 transmits the drive power to the video transmission processing unit 122 and the imaging unit 123. The call button 125, the handset side voice input / output unit 126, and the handset side voice processing unit 127 are supplied. In this way, the control unit 11 switches each unit of the parent device 2 and each unit of the child device 3 from the standby state to the operating state.

  When each unit of the base unit 2 or each unit of the handset 3 is switched from the standby state to the operating state, a ringing tone is output from the base unit side voice input / output unit 116 via the base unit side voice processing unit 117. When the operation state is switched, the video captured by the imaging unit 123 is processed by the video transmission processing unit 122, the slave-side demultiplexing unit 124, the master-side demultiplexing unit 115, and the video reception processing unit 112, respectively, and the display unit 111 Is displayed. And the main | base station 2 and the subunit | mobile_unit 3 will be in the state which can call.

  Then, an operation for turning off the operation of the master unit 2 is input from the operation unit 113, or no voice is input to the master unit side voice input / output unit 116 or the slave unit side voice input / output unit 127 for a predetermined time. Then, the control part 11 switches from an operation state to a standby state.

  By operating in this way, the base unit 2 according to the present embodiment can reduce the power consumption in the standby state as compared with the prior art. This saves on electricity bills.

  In the above-described embodiment, the setting unit 13 that sets the duty ratio of the pulse signal indicated by the alternate long and short dash line in FIG. 1 is further provided, and the duty ratio of the pulse signal output from the control unit 11 is changed to perform standby control. The duty ratio that is the ratio of the on period time to the off period time in the unit power consumption reduction unit 21 and the standby slave unit power consumption reduction unit 22 may be changed. By providing the setting unit 13, the amount of reduction in power consumption can be adjusted, and the power consumption can be further reduced by reducing the duty ratio and shortening the time between the high levels of the pulse signal (increasing the off period). Can be reduced.

It is a block diagram which shows the structure of the intercom system with a camera which concerns on embodiment. It is a circuit diagram which shows the structure of the power supply part with a reduction function which concerns on embodiment. It is a circuit diagram which shows the circuit of an operation power supply reduction part, and the circuit of a subunit | mobile_unit operation power supply reduction part. It is a block diagram which shows the structure of the intercom system with a camera which concerns on background art. It is a figure which shows the structure of the power supply part which concerns on background art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,101 Interphone system with camera 2,102 Interphone master unit 3,103 Door phone slave unit 11,114 Control unit 12,118 Power supply unit 13 Setting unit 21 Standby control unit Power consumption reduction unit 22 Standby slave unit power consumption reduction Part

Claims (4)

A control unit that controls the operation, a supply unit that supplies driving power to the door phone slave unit, and a power source unit that supplies driving power to the control unit and the supply unit, and can establish a call with the door phone slave unit In the intercom base unit,
In the standby state that is interposed between the power supply unit and the control unit and waits for a call from the door phone slave unit, an on period in which power is supplied and an off period in which power is cut off are repeated, Pulsed power is supplied from the power supply unit, charges are accumulated in the capacitor during the ON period, and driving power is supplied to the control unit based on the power supplied from the power supply unit, and the capacitor is supplied to the capacitor during the OFF period. An intercom master unit comprising: a standby control unit that consumes driving power to the control unit based on the accumulated charge. When the power supply unit is interposed between the supply unit and the power supply unit, an on period in which power is supplied and an off period in which the power is cut off are repeated to generate pulsed power from the power supply unit. In the ON period, electric charge is accumulated in a capacitor and driving power is supplied to the supply unit based on electric power supplied from the power supply unit. In the OFF period, electric charge is accumulated in the capacitor. The intercom master unit according to claim 1, further comprising a standby slave unit power consumption reduction unit that supplies driving power to the supply unit. The interphone master unit according to claim 1 or 2, further comprising a duty ratio setting unit that sets a duty ratio that is a ratio between the time of the on period and the time of the off period to be changeable. In an intercom system comprising an interphone master unit and a door phone slave unit,
The intercom base unit according to any one of claims 1 to 3, wherein the intercom base unit is the interphone base unit.

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