JPH06319171A - Transmission controller and its random number generating system - Google Patents

Abstract

PURPOSE:To obtain the transmission controller in which a unit side transmission line and a system side transmission line are interrupted so as to protect the device when a fault of the unit side gives effect on the system side or a fault of the system side gives effect on the unit side. CONSTITUTION:When a fault caused in an indoor equipment and a remote controller gives effect on other normal devices connecting to a network such as remote controllers and system side transmission line 2, or when a fault caused in a system side transmission line 2 connecting to the network gives effect on other normal devices connecting to the local side transmission line 4 such as devices and remote controllers, a central processing means 12 controls a transmission line interrupt means 20 to interrupt the system side transmission line 2 and the local side transmission line 4 to interrupt the system side transmission line 2 and the local side transmission line 4.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plurality of data communication terminal devices, a plurality of remote controllers for operating these data communication terminal devices, and a remote centralized management of these data communication terminal devices and remote controllers. The present invention relates to a transmission control device in which a central control device is connected to a network.

[0002]

2. Description of the Related Art Conventionally, a plurality of data communication terminal devices, a plurality of remote controllers for operating these data communication terminal devices, and a central control unit for remotely centrally managing these data communication terminal devices and remote controllers. A transmission control device in which a network is connected is known, and as an example thereof, a plurality of air conditioning units as a plurality of data communication terminal devices, a plurality of remote controllers for operating these air conditioning units, and these air conditioning units and remote controllers. There is an air-conditioning system in which a central control unit for remote centralized management is connected to a network.

FIG. 9 is a block diagram showing the structure of a general air conditioning system.

As shown in FIG. 9, the air conditioning system has a plurality of outdoor units 1 as constituent elements of an air conditioning unit, and these outdoor units 1 are connected by a system side transmission line 2. At least one indoor unit 3 is connected to each outdoor unit 1 through a unit-side transmission path 4, and each indoor unit 3 operates an air conditioning unit including the outdoor unit 1 and the indoor unit 3. The remote controller 5 is connected. A central control device 6 for centralized remote control of the air conditioning unit and the remote controller 5 is connected to the system side transmission line 2.

FIG. 10 is a block diagram showing the configuration of the outdoor unit 1.

As shown in detail in FIG. 10, the outdoor unit 1 has a DC polarity discriminating means 7 for discriminating the polarity of the DC current superimposed on the system-side transmission line 2 connected to the network, and a DC on the unit-side transmission line 4. DC power supply 8 for supplying current
A low-pass filter 9 that cuts high-frequency components so that the signal superimposed on the unit-side transmission line 4 does not affect the DC power supply device 8; and an overcurrent detecting overcurrent outflow of the DC current supplied from the DC power supply device 8. Current detection means 10
And a transmission path signal connecting a plurality of indoor units 3 and a plurality of remote controllers 5 to the unit side is sent to the system side transmission path 2 network-connected to the central controller 6.
Alternatively, the signal transmitted to the polarity determined by the DC polarity determining means 7 and the bidirectional waveform shaping means 11 for transmitting the networked transmission path signal to the unit side transmission path 4 to which the outdoor unit, the indoor unit and the remote controller 5 are connected. Central processing means 12 for stopping power supply by matching polarities and judging an overcurrent outflow state detected by the overcurrent detection means 10.

Next, the operation will be described.

The DC polarity discriminating means 7 discriminates the polarity of the DC current superposed on the system side transmission line 2 network-connected to the central control unit 6 and outputs the discrimination result to the central processing means 12. Then, the central processing means 12 has a common control / operation information signal or unit side control / operation information sent from the central control device 6 to the unit side transmission path 4 based on the inputted discrimination result. A control signal for switching the signal transmission direction is output to the bidirectional waveform shaping means 11 so that the signal output to the unit side does not attenuate even if the signal collides with the signal transmitted to the unit side transmission line 4 or the system side transmission line 2. To do.

Further, the bidirectional waveform shaping means 11 switches the signal sending direction by this control signal. The bidirectional waveform shaping means 11 shapes the waveform so that the transmission distance is not shortened by deforming and attenuating both signals sent to the system side and the unit side by the transmission path. Further, the central processing means 12 uses the overcurrent detection means 10 to prevent the DC power supply device 8 which supplies a DC current to the unit side transmission line 4 from a failure due to an overcurrent outflow due to a short circuit of the unit side transmission line 4. When the current outflow state is detected and the overcurrent is detected, the power supply from the DC power supply device 8 is stopped.

FIG. 11 is a block diagram showing the configuration of a conventional simple random number generation system described in Japanese Patent Laid-Open No. 62-14233.

The simple random number generation system has a microcomputer 13, a bidirectional bus driver 15 is connected to the microcomputer 13 via a data bus 14, and an I / O address is supplied via an address bus 16. The decoder 17 is connected. Further, the bidirectional bus driver 15 includes
A programmable interval timer 19 is connected via the data bus 18. Further, the read / write signal 100 from the microcomputer 13 is the bidirectional bus driver 1
5 direction terminals and the read / write terminals of the programmable interval timer 19.
The address signal from the microcomputer 13 is sent to the chip select control signal 101 by the I / O address decoder 17.
And is input to the chip select of the programmable interval timer 19.

Next, the operation will be described.

The address signal from the microcomputer 13 is always decoded by the I / O address decoder 17, and the chip select control signal 101 of the programmable interval timer 19 becomes valid only when the IN / OUT instruction to the programmable interval timer 19 is executed. The data on the data buses 14 and 18 is changed to the bidirectional bus driver 1 by the read / write signal 100 from the microcomputer 13.
5, the programmable interval timer 19 can be read and written correctly by the microcomputer 13. The count value of the programmable interval timer 19 set by the microcomputer 13, once set by the microcomputer 13, repeats cyclically counting values from the set value to 0. The count value is read by the microcomputer 13, and the read count value is passed to the random number generation processing unit inside the microcomputer 13 as a random number.

[0014]

Since the conventional transmission control device is constructed as described above, even one of the outdoor unit 1, the indoor unit 3 and the remote controller 5 is connected to the system side transmission line 2. When an abnormal condition that affects the transmission (for example, a transmission signal continues to be output to the transmission line due to a defect in the transmission circuit and cannot be transmitted by others) occurs, or the central control unit 6 connected to the system-side transmission line 2 has failed In this case, there is a problem in that even normal devices connected to the network cannot operate.

Further, the above-described conventional random number generation system generates random numbers by counting the count clock generated from the oscillator circuit of the programmable interval timer, but the error of the count clock generated from the oscillator circuit However, there was a problem that it converged to a constant value as a random number value. Further, since the random number generation circuit is composed of a plurality of parts, there is a problem that the circuit does not operate normally due to a defect such as a disconnection and lacks reliability.

The present invention has been made to solve the above problems, and when an abnormality occurring on the unit side affects the system side, or vice versa, an abnormality occurring on the system side occurs on the unit side. In the case of affecting the above, the purpose is to obtain a transmission control device capable of protecting the equipment by shutting off the unit side transmission line and the system side transmission line, and it is possible to simplify the circuit structure and to The purpose of the present invention is to obtain a random number generation system that can randomly generate random numbers using the clocking error of.

[0017]

According to a first aspect of the present invention, there is provided a transmission control device, a plurality of data communication terminal devices, a plurality of remote controllers for operating these data communication terminal devices, and these data communication terminal devices. In a transmission control device in a remote control system in which a device and a central controller for centralized remote control of a remote controller are network-connected, a direct current is applied to a local transmission line to which the plurality of data communication terminal devices and the remote controller are connected. The DC power supply device to be supplied, the disconnection means for disconnecting the system-side transmission path connected to the network and the local-side transmission path, and the abnormality that occurred in the data communication terminal device and the remote controller connected to the local-side transmission path Other normal data communication terminals connected to the network, remote When the controller and the system side transmission line are affected, or when the abnormality that occurred in the system side transmission line connected to the network affects the normal data communication terminal device and remote controller connected to the local side transmission line, the system side Central processing means for controlling the cutoff means so as to cut off the transmission path and the local transmission path.

According to a second aspect of the present invention, there is provided a transmission control device, wherein a plurality of data communication terminal devices, a plurality of remote controllers for operating these data communication terminal devices, and the data communication terminal device and the remote controller are remote. In a transmission control device in a remote control system in which a central control device for centralized management is network-connected, detection means for detecting the polarity of a DC current superimposed on the network-side system-side transmission path, and the plurality of data communication terminal devices And a DC power supply device that supplies a DC current to a local transmission line to which a remote controller is connected, a polarity reversing unit that reverses the polarity of the DC current supplied from the DC power supply device, and a DC power supply device that supplies the DC current. An overcurrent detecting means for detecting an outflow of direct current, and the network connection. The disconnecting means for disconnecting the system side transmission path and the local side transmission path, and the polarity of the direct current supplied from the direct current power supply when the detection means detects that the direct current is superposed on the system side transmission path. The polarity reversing means is controlled so as to invert, and the breaking means is short-circuited, or when it is detected by the detecting means that no direct current is superposed on the system side transmission line, the breaking means is short-circuited, Further, when the overcurrent detection means detects an overcurrent outflow of the direct current supplied from the direct current power supply device, the interruption means is opened to reverse the polarity of the direct current supplied from the direct current power supply device. Central processing means for controlling the means, short-circuiting the interruption means again, and making the system side transmission line superimposed DC current polarity the same as the local side transmission line superimposed DC current polarity, Characterized in that it comprises.

According to a third aspect of the present invention, there is provided a transmission control device comprising a plurality of data communication terminal devices, a plurality of remote controllers for operating these data communication terminal devices, and a remote control of these data communication terminal devices and remote controllers. In a transmission control device in a remote control system in which a central control device for centralized management is network-connected, detection means for detecting the polarity of a DC current superimposed on the network-side system-side transmission path, and the plurality of data communication terminal devices And a DC power supply device that supplies a DC current to a local transmission line to which a remote controller is connected, a polarity reversing unit that reverses the polarity of the DC current supplied from the DC power supply device, and a DC power supply device that supplies the DC current. An overcurrent detecting means for detecting an outflow of direct current, and the network connection. The disconnecting means for disconnecting the system-side transmission path and the local-side transmission path, the random-number generating means for generating a random number, the clocking means for starting timing of a predetermined time by a clocking instruction, and the detecting means for direct-current transmission to the system-side transmission path When it is detected that the currents are superposed, the polarity reversing means is controlled so as to invert the polarity of the direct current supplied from the direct current power supply device, and the breaking means is short-circuited, or the detecting means causes the system side. When it is detected that DC current is not superimposed on the transmission path, a random number is generated by the random number generation means, the random number value is timed by the time counting means, and when the predetermined time is measured, the detection side again transmits the system side. If it is detected by the detection means that no DC current is superposed on the system-side transmission line, the interruption means is activated. And fault, if it is detected that the direct current is superimposed on the system side transmission line by the detecting means, controls the polarity inverting means to invert the polarity of the direct current supplied from the DC power supply device,
And when the breaking means is short-circuited, and when the overcurrent detection means detects an overcurrent outflow of the direct current supplied from the DC power supply device, the breaking means is opened and the DC current supplied from the DC power supply device The polarity reversing means is controlled to invert the polarity, and the random number generating means generates a random number,
When the random number is timed by the time measuring means and the predetermined time is measured, the detecting means detects whether or not the direct current is superposed on the system side transmission line, and the detecting means superimposes the direct current on the system side transmission line. When it is detected that there is no DC current, the breaking means is short-circuited, and when the detection means detects that a DC current is superimposed on the system side transmission line, the polarity of the DC current supplied from the DC power supply device is reversed. Controlling the polarity reversing means, and short-circuiting the breaking means,
The distributed power supply system is provided with a central processing unit that controls the polarity of the superimposed DC current with random numbers so as not to collide with each other.

According to a fourth aspect of the present invention, there is provided a random number generation system for a transmission control device, wherein a first microcomputer having a function of using the first system clock oscillator as a reference time for clocking, and a second system clock oscillator. And a second microcomputer having a function of using as a reference time for measuring, from the control signal output from the first microcomputer to the second microcomputer until the second microcomputer returns a response signal to the first microcomputer. Is timed by the first microcomputer and the counted value is output as a random number.

According to a fifth aspect of the present invention, there is provided a random number generation system for a transmission control device, which includes a microcomputer having a function of setting a system clock oscillator as a reference time, and a control from the microcomputer to start time measurement and end time measurement. And a timing circuit composed of an integration circuit that outputs a response later, outputting a timing start control signal from the microcomputer to the timing means, and measuring the time until the timing means outputs the response signal to the microcomputer by the microcomputer, and It is characterized in that the counted value measured is output as a random number.

[0022]

In the transmission control device according to the invention described in claim 1,
When an abnormality that occurs in the data communication terminal device or remote controller connected to the local transmission line affects other normal data communication terminal devices connected to the network, the remote controller or the system side transmission line, or the network If an abnormality that occurs in the connected system-side transmission path affects the normal data communication terminal device and remote controller connected to the local-side transmission path, the system side transmission path and the local-side transmission path should be cut off centrally. The processing means controls the cutoff means to cut off the system side transmission line and the local side transmission line.

In the transmission control device according to the second aspect of the present invention, when the detecting means detects that the direct current is superimposed on the system side transmission line, the polarity of the direct current supplied from the direct current power supply device by the central processing means. Controlling the polarity reversing means to invert, and short-circuiting the breaking means,
Alternatively, when the detection means detects that no DC current is superposed on the system-side transmission line, the cutoff means is short-circuited, and the overcurrent detection means detects an overcurrent outflow of the DC current supplied from the DC power supply device. Upon detection, the breaking means is opened, the polarity reversing means is controlled so as to reverse the polarity of the DC current supplied from the DC power supply device, the breaking means is short-circuited again, and the system side transmission line superimposed DC current polarity and local Make the side transmission line superimposed DC current polarity the same.

In the transmission control device according to the third aspect of the present invention, when the detection means detects that the direct current is superposed on the system side transmission line, the polarity of the direct current supplied from the direct current power supply device by the central processing means. Controlling the polarity reversing means to invert, and short-circuiting the breaking means,
Alternatively, when the detection means detects that the DC current is not superimposed on the system-side transmission path, a random number is generated by the random number generation means, the random number value is timed by the time counting means, and the predetermined time is measured again, The detection means detects the presence or absence of DC current superposition on the system side transmission line, and when the detection means detects that no DC current is superposed on the system side transmission line, the breaking means is short-circuited and the detection side means system side. When detecting that the direct current is superimposed on the transmission line, the polarity reversing means is controlled so as to reverse the polarity of the direct current supplied from the direct current power supply device, and the breaking means is short-circuited, and the overcurrent When the detecting means detects an overcurrent outflow of the direct current supplied from the direct current power supply device, the shutoff means is opened to supply the direct current supplied from the direct current power supply device. The polarity reversing means is controlled so as to invert the polarity, a random number is generated by the random number generating means, the random number value is timed by the time measuring means, and when a predetermined time is measured, a direct current is sent to the system side transmission line by the detecting means. When the detection means detects that the DC current is not superimposed on the system side transmission line, the breaking means is short-circuited and the detection means superimposes the DC current on the system side transmission line. When this is detected, the polarity reversing means is controlled so as to invert the polarity of the DC current supplied from the DC power supply device, and the breaking means is short-circuited, and the polarity of the superimposed DC current collides with random numbers in the distributed power supply system. Control not to let.

In the random number generation system of the transmission control device according to the present invention, the control signal output from the first microcomputer to the second microcomputer until the second microcomputer returns a response signal to the first microcomputer. Is counted by the first microcomputer, and the counted value thus counted is used as a random number.

According to a fifth aspect of the present invention, in the random number generation system of the transmission control device, the microcomputer measures the time until the time measurement start control signal is output from the microcomputer to the time measurement means and the time measurement means outputs the response signal to the microcomputer. Then, the counted value counted is used as a random number.

[0027]

【Example】

Example 1. An embodiment of the present invention will be described below with reference to the drawings.

FIG. 9 is a block diagram showing the configuration of a general transmission control device.

As shown in FIG. 9, the transmission control device has a plurality of outdoor units 1 as constituent elements of an air conditioning unit, and these outdoor units 1 are connected by a system side transmission line 2. At least one indoor unit 3 is connected to each outdoor unit 1 through a unit-side transmission path 4, and each indoor unit 3 operates an air conditioning unit including the outdoor unit 1 and the indoor unit 3. The remote controller 5 is connected. A central control device 6 for centralized remote control of the air conditioning unit and the remote controller 5 is connected to the system side transmission line 2.

FIG. 1 is a block diagram showing the construction of an outdoor unit 1 according to the invention described in claims 1 to 3.

The outdoor unit 1 is, as shown in detail in FIG.
Blocking means 20 for blocking the system side transmission path and the local side transmission path, a random number generating means 21 for generating a random number, and a DC polarity determining means 7 for determining the polarity of the DC current superimposed on the system side transmission path 2 connected to the network. A direct current power supply device 8 for supplying a direct current to the unit side transmission line 4, a low pass filter 9 for cutting high frequency components so that a signal superimposed on the unit side transmission line 4 is not affected by the direct current power supply device 8, The polarity reversing means 22 for inverting the polarity of the direct current supplied from the power supply device 8, the overcurrent detecting means 10 for detecting the outflow of the direct current supplied from the direct current power supply device 8, and the direct current polarity determining means 7. The discrimination result, the random number generated by the random number generation means 21, and the overcurrent detection means 1
Based on the overcurrent outflow state detected by 0, the breaking means 2
0 and the central processing means 12 for controlling the polarity reversing means 22.

Next, the operation of this embodiment will be described with reference to the flowchart of FIG.

When the outdoor unit 1 is powered on and the central processing means 12 is system reset, both of the transmission lines of the system side transmission line 2 and the unit side transmission line 4 are prevented from being attenuated by a collision. It is necessary to match the polarities of the signals sent to 2 and 4. The signal polarity is determined by the polarity of the DC current superimposed on the transmission lines 2 and 4. For example, if it is determined in advance that the first start bit is sent to the plus side of the DC power supply device 8, signal collision can be avoided.

First, since it is not known whether or not a direct current is superposed on the system side transmission line 2, the transmission line interruption means 2
The relay of 0 is short-circuited to disconnect the system side transmission line 2 and the unit side transmission line 4 (step 1). Then, the DC polarity discriminating means 7 discriminates the polarity of the DC current superposed on the system-side transmission line 2 network-connected to the central control unit 6 (step 2), and the discrimination result (the polarity is forward or reverse). Or a direct current is not superimposed) is output to the central processing means 12.

Then, the central processing means 12 generates a random number by the random number generating means 21 (step 4) when the polarity of the inputted discrimination result is in the reverse direction or the direct current is not superposed (step 3), and the random number is generated. The random number obtained by the generating means 21 is input to the central processing means 12, and it is judged whether or not the random number generating time has elapsed (step 5). When the random number generation time has elapsed, the DC polarity discriminating means 7 discriminates again the polarity of the DC current superimposed on the system side transmission line 2 network-connected to the central controller 6 (step 6), and the discrimination result ( The polarity is forward, reverse, or DC current is not superposed) to the central processing means 12. At this time, when a plurality of outdoor units 1 are connected to the system-side transmission line 2, when a DC current is supplied to the system side while the random number generation time elapses, or a DC current is supplied to the system-side transmission line 2. This is a countermeasure when the power supply device that supplies power is delayed.

Further, if the inputted discrimination result is that the polarity is opposite or the direct current is not superposed (step 7), the central processing means 12 judges that the power feeding is not started by anyone other than itself, and the transmission is performed. Open the relay of the wire breaking means 20,
A direct current is supplied from the direct current power supply device 8 (step 8). Then, the overcurrent detection means 10 determines whether or not an overcurrent is generated, that is, whether or not the polarity of the DC current supplied matches the polarity of the DC current supplied to the system-side transmission line 2 ( Step 9) If there is an overcurrent, that is, if the polarity of the supplied DC current does not match the polarity of the DC current supplied to the system side transmission line 2, open the relay of the transmission line interruption means 20. The system side transmission line 2 and the unit side transmission line 4 are cut off (step 10). Note that such a situation may occur when a plurality of outdoor units 1 simultaneously start supplying direct current.

Then, the central processing means 12 reverses the polarity of the direct current supplied to the transmission line by the polarity reversing means 22 (step 11). Further, the random number generating means 21 generates a random number (step 12), the random number obtained by the random number generating means 21 is input to the central processing means 12, and it is determined whether or not the random number generating time has elapsed (step 13). When the random number generation time has elapsed, the DC polarity discriminating unit 7 discriminates again the polarity of the DC current superimposed on the system side transmission line 2 network-connected to the central controller 6 (step 1).
4) The judgment result (polarity is forward, reverse or DC current is not superimposed) is output to the central processing means 12. Further, when the input determination result indicates that the polarity is reverse or the DC current is not superimposed (step 15), the central processing means 12 determines that power supply other than the self has not started, and the transmission line interruption means 20. Then, the relay is opened and the DC current is supplied from the DC power supply 8 (step 16).

Then, the outdoor unit 1 processes the operation and control from the unit side transmission line 4 or the system side transmission line 2 having the central control unit 6 (step 17). Whether or not an unrecoverable abnormality has occurred in the system side in which the plurality of indoor units 3 connected to the unit-side transmission path 4, the remote controller 5, or the central controller 6 and the plurality of outdoor units 1 are connected (Step 18), and if an unrecoverable abnormality occurs, the relay of the transmission line blocking means 20 is short-circuited (step 19), and only part of the system is down and danger is dispersed. If no unrecoverable abnormality occurs, the air conditioner control process (step 17) is repeated.

If the polarity is determined to be forward in steps 3, 7, and 15, the DC current is being supplied to the system-side transmission line 2, so the central processing means 12 reverses the polarity. The polarity of the direct current supplied to the transmission line is inverted by the means 22 (step 2
0), the relay of the transmission line interruption means 20 is opened, the direct current is supplied from the direct current power supply device 8 (step 21), and then the processing operation of step 17 is performed.

Example 2. FIG. 3 is a block diagram showing a configuration of a random number generation system of a transmission control device according to the invention of claim 4. The random number generating system is used as the random number generating means 21 in the first embodiment.

The random number generation system includes a first microcomputer 24 having a function of using the first system clock oscillator 23 as a reference time for clocking, and a second system clock oscillator 2
The second microcomputer 26 has a second microcomputer 26 having a function of setting 5 as a reference time for timing, and the second microcomputer 26 outputs the first microcomputer 24 from the control signal 102 output from the first microcomputer 24 to the second microcomputer 26. The first microcomputer 24 measures the time until the response signal 103 is returned to the microcomputer 24, and the software has the counted value as a random number.

Next, the operation of this embodiment will be described with reference to the flow charts of FIGS.

First microcomputer 24 and second microcomputer 2
When the power of 6 is turned on, the program is initially started by system reset. Then, the first microcomputer 24 sets the system clock generated by the first system clock oscillator 23 so as to be the count clock for timekeeping (step 21). then,
Control signal 102 for causing the second microcomputer 26 to start timing
Is output (step 22).

Further, the counting of the clock count clock is started to clock the time of the clock end response signal 103 from the second microcomputer 26 (step 23). Then, it is judged whether or not there is the response signal 103 from the second microcomputer 26 (step 24), and when there is the response signal 103, the value of the time count is read (step 25) and the read value is set as a random number value. Yes (Step 2
6).

If there is no response signal 103 in step 24, the time counting is continued.

On the other hand, the operation of the second microcomputer 26 is as shown in FIG.
As shown in the flow chart, when receiving the time counting start signal 102 from the first microcomputer 24, initial processing is performed (step 27), and the time counting end response signal 103 is output to the first microcomputer 24 (step 28).

Example 3. FIG. 6 is a block diagram showing the configuration of a random number generation system of a transmission control device according to the invention of claim 5. The random number generating system is used as the random number generating means 21 in the first embodiment.

The random number generation system includes a microcomputer 24 having a function of using the system clock oscillator 23 as a reference time for measuring time, and an integrator circuit for starting time measurement under the control of the microcomputer 24 and outputting a response 104 after the time measurement ends. And a time counting circuit 27,
Further, the microcomputer 24 has software for counting the time until the time counting means 27 outputs the response signal 104 to the microcomputer 24 by outputting the time counting start control signal 102 and using the counted value as a random number. In addition, the clock circuit 27
Is a PNP transistor 28, a resistor 29, a capacitor 3
It is composed of 0s.

Next, the operation of this embodiment will be described with reference to the flowchart of FIG.

When the microcomputer 24 is powered on, the program is initialized by system reset.
Then, the microcomputer 24 uses the system clock oscillator 23.
Based on the system clock generated by, the setting is made to make it the count clock for timekeeping (step 31).

Then, the control signal 102 for starting the time counting is output to the time counting circuit 27 (step 32), and the count of the time counting clock is started to count the time of the time counting end response signal 104 from the time counting circuit 27. (Step 33). Then, the response signal 1 from the timing circuit 26
It is judged whether or not there is 04 (step 34), and the response signal 1
If there is 04, the value of the time count is read (step 35), and the read value is set as a random number value (step 36).

If there is no response signal 104 in step 24, the time counting is continued.

Further, when the clocking start signal 102 from the microcomputer 24 has the output waveform shown in FIG. 7A, when the clocking start output 102 becomes 0V,
The PNP transistor 28 is turned on, and a voltage is applied to the resistor 29 and the capacitor 30. When the voltage is applied to the time measuring means 27 in which the integrating circuit output A constituted by the resistor 29 and the capacitor 30 is the response signal 104 to the microcomputer 24 of the time measuring means 27, the integration circuit output A point voltage is set to VA. , Where A is the voltage value of the voltage, VA is represented by the relational expression VA = V (1-ε).

FIG. 7B shows the relationship between this voltage VA and time.
Shown in.

As described above, when the clocking means 27 receives the clocking start signal 102, it outputs the response signal 104 as shown in FIG.
Since the waveform shown in is output, the microcomputer 24 measures the time T1 from turning on the timing start signal 102 until the input of the response signal 104 changes from “L” to “H”, and generates the measured value as a random number. To do.

[0056]

As described above, according to the first aspect of the present invention, the abnormality that occurs in the data communication terminal device and the remote controller connected to the local transmission line is the other normal data connected to the network. Communication terminal,
When the remote controller and the transmission path on the system side are affected, or when an error occurred on the transmission path on the system side connected to the network affects the normal data communication terminal device and remote controller connected to the local transmission path. Since the central processing means controls the shut-off means to shut off the system-side transmission path and the local-side transmission path and shuts off the system-side transmission path and the local-side transmission path, the system-side is shut off by the shut-off means. Even if an abnormality that cannot be recovered occurs in the transmission path or the local transmission path, the system operation or the data communication operation can be performed without affecting other normal devices.

According to the second aspect of the invention, when the detecting means detects that the direct current is superimposed on the system side transmission line, the central processing means inverts the polarity of the direct current supplied from the direct current power supply device. The polarity reversing means is controlled so that the circuit breaks, and the interruption means is short-circuited, or when the detection means detects that no DC current is superposed on the system side transmission line, the interruption means is short-circuited and When the overcurrent outflow of the direct current supplied from the direct current power supply is detected by the current detection means, the interruption means is opened and the polarity reversing means is controlled so as to invert the polarity of the direct current supplied from the direct current power supply. , The disconnecting means is short-circuited again, and the system side transmission line superimposed DC current polarity and the local side transmission line superimposed DC current polarity are configured to be the same. To match the polarity of the sending passage and delivery signal of the system side transmission path, signal attenuation can be prevented caused by signal collision.

In the transmission control device according to the third aspect of the invention, when the detecting means detects that the direct current is superposed on the system side transmission path, the polarity of the direct current supplied from the direct current power supply device by the central processing means. Controlling the polarity reversing means to invert, and short-circuiting the breaking means,
Alternatively, when the detection means detects that the DC current is not superimposed on the system-side transmission path, a random number is generated by the random number generation means, the random number value is timed by the time counting means, and the predetermined time is measured again, When the detection means detects the presence or absence of DC current superposition on the system-side transmission line, and when the detection means detects that no DC current is superposed on the system-side transmission line, the breaking means is short-circuited and the detection means detects the system side. When detecting that the direct current is superimposed on the transmission line, the polarity reversing means is controlled so as to reverse the polarity of the direct current supplied from the direct current power supply device, and the breaking means is short-circuited, and the overcurrent When the detecting means detects an overcurrent outflow of the direct current supplied from the direct current power supply device, the shutoff means is opened to supply the direct current supplied from the direct current power supply device. The polarity reversing means is controlled so as to invert the polarity, a random number is generated by the random number generating means, the random number value is timed by the time measuring means, and when a predetermined time is measured, a direct current is sent to the system side transmission line by the detecting means. Detects the presence or absence of superimposition, and when the detecting means detects that the direct current is not superposed on the system side transmission line, the interruption means is short-circuited and the direct current is superposed on the system side transmission line by the detecting means. When this is detected, the polarity reversing means is controlled so as to invert the polarity of the DC current supplied from the DC power supply device, and the breaking means is short-circuited, and the polarity of the superimposed DC current collides with random numbers in the distributed power supply system. Since it is configured to control so that it will not be reset, even if an abnormality that cannot be recovered to the system side transmission line or the local side transmission line occurs due to the blocking means, it will be corrected. There is an effect that system operation or data communication operation can be performed without affecting other devices, and the polarities of the transmission signals of the local side transmission line and the system side transmission line are matched, and the signal is attenuated by a signal collision. Can be prevented.

According to the invention described in claim 4, the time from the control signal output from the first microcomputer to the second microcomputer until the second microcomputer returns the response signal to the first microcomputer is set to the first time. Since it is configured to count with a microcomputer and to use the counted value as a random number, it is possible to generate a random number with high randomness, and also to simplify the circuit to reduce the probability of problems such as disconnection, The reliability can be improved.

According to a fifth aspect of the present invention, in the random number generating system of the transmission control device, the microcomputer measures the time until the time counting start control signal is output to the time measuring means and the time measuring means outputs the response signal to the microcomputer. However, since the counted value is configured to be a random number, a random number with high randomness can be generated, and the circuit can be simplified to reduce the probability of problems such as disconnection and improve reliability. Can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an outdoor unit 1 according to the invention described in claims 1 to 3. FIG.

FIG. 2 is a flowchart showing the operation of the invention described in claims 1 to 3.

FIG. 3 is a block diagram showing a configuration of a random number generation system of a transmission control device according to a fourth aspect of the invention.

FIG. 4 is a flowchart showing an operation of the invention described in claim 4.

FIG. 5 is a flow chart showing an operation of the invention described in claim 4.

FIG. 6 is a block diagram showing a configuration of a random number generation system of a transmission control device according to a fifth aspect of the invention.

FIG. 7 is a time chart showing the operation of the time counting means of the random number generation system of the transmission control device according to the fifth aspect of the present invention.

FIG. 8 is a flowchart showing an operation of the random number generation system of the transmission control device according to the fifth aspect of the present invention.

FIG. 9 is a block diagram showing a configuration of a general air conditioner system.

FIG. 10 is a block diagram showing a configuration of a conventional outdoor unit.

FIG. 11 is a block diagram showing a configuration of a conventional simple random number generation system.

[Explanation of symbols]

 1 outdoor unit 2 system side transmission line 3 indoor unit 4 unit side transmission line 5 remote control 6 central control unit 7 DC polarity determination means 8 DC power supply unit 10 overcurrent detection unit 12 central processing unit 20 transmission line interruption unit 21 random number generation unit 22 polarity inversion means 23, 25 system clock oscillator 24, 26 microcomputer 27 clocking means 28 transistor 29 resistance 30 capacitor

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Internal reference number FI Technical display location F24F 11/02 103 C G06F 7/58 A 9188-5B H04L 12/28 29/14

Claims (5)

[Claims] 1. A network comprising a plurality of data communication terminal devices, a plurality of remote controllers for operating these data communication terminal devices, and a central control device for remotely centrally managing these data communication terminal devices and remote controllers. In a transmission control device in a connected remote control system, a direct current power supply device for supplying a direct current to a local transmission line to which the plurality of data communication terminal devices and remote controllers are connected, a system side transmission line connected to a network, and Shut-off means for shutting off the local transmission line, and another normal data communication terminal device, remote controller and system in which an abnormality occurred in the data communication terminal device and remote controller connected to the local transmission line is network-connected When it affects the side transmission line, Or, if an error that occurs in the system-side transmission line connected to the network affects the normal data communication terminal device and remote controller connected to the local-side transmission line, disconnect the system-side transmission line and the local-side transmission line. A central processing means for controlling the cutoff means, and a transmission control device. 2. A network comprising a plurality of data communication terminal devices, a plurality of remote controllers for operating these data communication terminal devices, and a central control device for remotely centrally managing these data communication terminal devices and remote controllers. In a transmission control device in a connected remote control system, detection means for detecting the polarity of a DC current superimposed on a network-side system-side transmission line, and a local-side transmission line to which the plurality of data communication terminal devices and remote controllers are connected A direct current power supply device for supplying a direct current to the device, a polarity reversing means for reversing the polarity of the direct current current supplied from the direct current power supply device, and an overcurrent detecting an overcurrent outflow of the direct current supplied from the direct current power supply device. Detecting means, the network-side system-side transmission line and the local-side transmission line. And a polarity reversing means for reversing the polarity of the direct current supplied from the direct current power supply when detecting that the direct current is superposed on the system side transmission path by the disconnecting means for disconnecting the path and the detecting means. When controlling and short-circuiting the breaking means, or when detecting that the direct current is not superposed on the system side transmission line by the detecting means, the breaking means is short-circuited, and the direct current power source by the overcurrent detecting means. When an overcurrent outflow of the direct current supplied from the device is detected, the interruption means is opened, the polarity reversing means is controlled so as to invert the polarity of the direct current supplied from the direct current power supply device, and the interruption means is turned on again. Centralized processing means for short-circuiting and making the system side transmission line superimposed DC current polarity the same as the local side transmission line superimposed DC current polarity. . 3. A network comprising a plurality of data communication terminal devices, a plurality of remote controllers for operating these data communication terminal devices, and a central control device for remotely centrally managing these data communication terminal devices and remote controllers. In a transmission control device in a connected remote control system, detection means for detecting the polarity of a DC current superimposed on a network-side system-side transmission line, and a local-side transmission line to which the plurality of data communication terminal devices and remote controllers are connected A direct current power supply device for supplying a direct current to the device, a polarity reversing means for reversing the polarity of the direct current current supplied from the direct current power supply device, and an overcurrent detecting an overcurrent outflow of the direct current supplied from the direct current power supply device. Detecting means, the network-side system-side transmission line and the local-side transmission line. A shutoff means for shutting off the path, a random number generation means for generating a random number, a timing means for starting timing of a predetermined time by a timing instruction, and the detection means for detecting that a DC current is superposed on the system side transmission path. In such a case, the polarity reversing means is controlled so as to invert the polarity of the direct current supplied from the direct current power supply device, and the breaking means is short-circuited, or the direct current is superimposed on the system side transmission line by the detecting means. If it detects that there is no DC current, the random number generation means generates a random number, the random number value is timed by the time measurement means, and if a predetermined time is measured, the detection means checks again whether the DC current is superimposed on the system side transmission line. If the detection means detects that the direct current is not superposed on the system side transmission line, the breaking means is short-circuited and the detection means transmits the system side transmission. When it is detected that a direct current is superimposed on the path, the polarity reversing means is controlled so as to reverse the polarity of the direct current supplied from the direct current power supply device, and the breaking means is short-circuited, and the overcurrent When the detection means detects the overcurrent outflow of the direct current supplied from the direct current power supply device, the interruption means is opened, and the polarity reversing means is controlled so as to invert the polarity of the direct current supplied from the direct current power supply device. When a random number is generated by the random number generating means, the random number value is timed by the time measuring means, and a predetermined time is measured, the detecting means detects whether or not a direct current is superposed on the system side transmission line, and the detecting means detects the system. When it is detected that the DC current is not superposed on the side transmission line, the breaking means is short-circuited, and the detection means detects that the DC current is superposed on the system side transmission line. In this case, the polarity reversing means is controlled so as to invert the polarity of the DC current supplied from the DC power supply device, and the breaking means is short-circuited so that the polarity of the superimposed DC current does not collide with random numbers in the distributed power supply system. A central processing unit that controls the transmission control device. 4. A first microcomputer having a function of using a first system clock oscillator as a reference time for measuring, and a second microcomputer having a function of using a second system clock oscillator as a reference time for measuring. The time from the control signal output from the first microcomputer to the second microcomputer until the second microcomputer returns a response signal to the first microcomputer is measured by the first microcomputer, and the counted time is counted. A random number generation system for a transmission control device, which outputs a value as a random number. 5. A microcomputer having a function of using a system clock oscillator as a reference time for measuring time, and a time measuring circuit comprising an integrating circuit for starting time measurement under the control of the microcomputer and outputting a response after the time measurement ends. , A transmission characterized by outputting a timing start control signal from the microcomputer to the timing means, timing the time until the timing means outputs a response signal to the microcomputer, and outputting the counted value as a random number Random number generation system for control devices.