JPS619798A - Automatic transmission type observer - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an automatic transmission type observation device used for telemetering.

Traditionally, this type of equipment has been installed in areas with concentrated heavy rainfall and in rivers where water levels change rapidly.

There are water level observation devices installed on dams. When transmitting event data from these devices, the rainfall observation device transmits the received rainfall data when a rainfall signal from the rain gauge is detected, that is, when the event changes, and the water level observation device transmits the received rainfall data using a timer circuit. Water level data was sent every time interval.

Therefore, in a device such as a rainfall observation device that transmits rainfall data only based on event changes, if no rainfall data is sent for a long period of time, it is difficult to determine whether the device is malfunctioning or whether no event change has occurred. The drawback is that it cannot be done.

Also, in devices such as water level observation devices that transmit water level data at fixed time intervals using a timer circuit.

If the activation time interval of the timer circuit is long, changes in the water level cannot be known when it should be known, so the activation interval of the timer circuit generally tends to be shortened, which increases the number of transmissions.

The disadvantage is that the power consumption of the device increases.

The present invention was made in order to eliminate the above-mentioned conventional drawbacks, and an object of the present invention is to provide a new automatic transmission type observation device that uses both the transmission of event data based on event changes and the transmission of event data based on the timer time of a timer circuit. It is something to do.

The present invention detects a change in an event while the timer is in the long time mode by using a timer cycle 'R1r in which the timer time is alternately switched between a long time mode in which the timer time is long and a short time mode in which the timer time is in the short time mode. Then, it immediately transmits the received event data and switches the timer time to short-time mode, and even if no change in the event is detected, it transmits the event data at that time by the activation signal from the timer circuit, and If the timer time is switched to short-time mode and a change in event is detected while the timer time is in short-time mode, the event data received each time the event changes is stored and activated by the activation signal from the timer circuit. , while transmitting the stored event data, the timer time is set to the short-time mode again, and if a change in the event is not detected, the event data is not transmitted and the timer time is switched to the long-time mode. In Figure 1, 1
2 is an event change detection circuit that detects an event change and event data from the input line IL; 2 is activated by a start signal from the event change detection circuit 1, and controls the transmission of received event data and switches the operation mode of the timer circuit 3. Main control circuit, 3
The system alternates between two startup intervals: a long mode in which the startup interval is long, such as 1 hour, 3 hours, or 6 hours, and a short time mode in which the startup interval is short, such as 5 minutes or 10 minutes. 4 is a transmitting circuit that transmits υ event data to the transmission line 0'L under the control of the main control circuit 2.

The operation of the automatic transmission type observation device configured in this way will be described below.

First, when the device is in its initial state, that is, when power is applied, the timer circuit 3 is set to a long-time mode.

(6) If the event change detection circuit 1 detects an event signal from the input line IL while the timer time of the timer circuit 3 is in the long-time mode, the received event data is immediately transmitted by the main control circuit 2. The signal is transmitted from the circuit 4 to the transmission line OL, and the main control circuit 2 also sends a timer switching signal to the timer circuit 3 to switch the timer time of the timer circuit 3 from the long time mode to the short time mode.

(b) If the event change detection circuit 1 does not detect an event signal from the human power line IL while the timer time of the timer circuit 3 is in the long-time mode, the timer circuit 3 sends a start signal to the main control circuit 2. is sent out, and the event data at that point is sent from the transmission circuit 4 to the transmission line OL, and at the same time, the main control circuit 2 sends a timer switching signal to the timer circuit 3.
The timer time of the timer circuit 3 is switched from the long time mode to the short time mode.

0) When the event change detection circuit 1 detects an event signal from the input line IL during the period when the timer time of the timer circuit 3 is in the short time mode, the received event data is sequentially stored in the main control circuit 2, This operation continues until the start signal is output from the timer circuit 3. When the start signal is given to the main control signal 2 from the timer circuit 3, the main control circuit 2
transmits the stored event data all at once from the transmitting circuit 4 to the transmission line OL.

However, in this case, the timer time is switched to the short time mode again.

(ii) If the event change detection circuit 1 does not detect an event signal from the input line IL during the period when the timer time of the timer circuit 3 is in the short-time mode, a start signal is given from the timer circuit 3 to the main control circuit 2. Even if the event occurs, the main control circuit 2 does not send event data. The timer circuit then switches from the short time mode to the long time mode.

As an automatic transmission type observation device, if a change in an event occurs, it can be detected directly and event data can be transmitted in a timely and appropriate manner.In addition, since this device is generally installed in an uninhabited area, maintenance management is required. It is hoped that it will be easy, and especially that it will consume less power.

As mentioned above, the automatic transmission type observation device of the present invention manages its operation with two timer times that are alternately switched between the long-time mode and the short-time mode. A distinction is made between cases according to
In particular, if event changes occur frequently during the short time mode, the event data during this period will be sent together.

Event data is sent in a timely and appropriate manner, and if there is no event change, event data is sent only by starting the timer in long-term mode, so the power consumption required to send event data is minimized. It can be pushed to the limit.

FIG. 2 shows a block diagram when the automatic transmission type observation device according to the present invention shown in FIG. 1 is implemented in a rainfall observation device. It has the same configuration as FIG. 1 except that the detection circuit IA is used, and the same parts as in FIG. 1 are given the same reference numerals and detailed explanations will be omitted.

FIG. 3 is a timing chart showing the operation of the rainfall observation device shown in FIG. 2, and the operation of the rainfall observation device will be explained below based on FIG.

(1) At time A, power is applied to the device, and the timer circuit 3 is set to a long-time mode in which the activation interval T2 is, for example, 6 hours.

(2) When a rainfall signal is input to the rainfall detection circuit IA from a rain gauge (not shown) via the input line IL at time B, the main control circuit 2 is activated by the activation signal of the rainfall detection circuit IAj5, and this activation signal The main control circuit 2, which has received the rainfall data subsequent to the above, transmits the rainfall data received from the transmitting circuit 4 to the transmission line OL.

In this case, when the main control circuit 2 transmits the rainfall amount data, it sends a switching signal to the timer circuit 3 to change the time from time B to time C''.
! , for example, to a short-time mode having an activation interval T1 of 10 minutes.

(3) Switch to short-time mode at time B, then time T
Since the rainfall signal is not input to the rainfall detection circuit IA by time point C after time 1, even though the timer circuit 3 sends a start signal to the main control circuit 2 at time point 1 C, the main control circuit 2 does not send the rainfall amount data. Switch the timer circuit 3 to long-term mode.

(4) When a rainfall signal and rainfall amount data are input at a certain point during the long-time mode, the device performs the same operation as at time B, and the timer circuit 3 switches to the short-time mode. Points E and F during this short time mode
A rainfall signal is input at , and the rainfall amount data from the rainfall detection circuit IA is stored in the main control circuit 2 . At time G after time T1, a start signal is sent from the timer circuit 3 to the main control wholesale circuit 2, and as a result, the main control circuit 2 transmits the rainfall amount data, which is the sum of the increases in rainfall at time points E and F, to the transmission circuit. 4 to transmission port i0L. in this case.

The device transmits rainfall data at time G.

Therefore, the activation interval of the timer circuit 3 continues in the short time mode.

(5) Next, since the rainfall signal is not input to the rainfall change detection circuit 1 during the time T1 from time G to time H, the operation of the timer circuit 3 at time 2 H is as short as the operation at time 2 C. Switches from time mode to long time mode.

(6) When a rainfall signal is not detected during the long-term mode of time T2 from time H to time ■, a start signal is sent from the timer circuit 3 to the main control circuit 2, and the main control circuit 2 transmits the accumulated rainfall data to the circuit 4.
At the same time, the timer circuit 3 is switched from the long-time mode to the short-time mode.

(7) If no rainfall signal is input to the device during time T1 at time -i after time ■, the operation of the device at time 1 will switch to long-term mode operation, but at time 2. A rainfall signal is detected by the rainfall detection circuit IA at time J between J and J.
Since it is input to , the operation of the device at time 2 is at time G.
The timer circuit 3 resumes operation in the short-time mode while transmitting the rainfall amount data at time J as in the case of FIG.

Thereafter, since the rain signal is not input to the rain detection circuit IA during the time period T1 at time L'd, the device operates in the same manner as at time H and enters the standby state at two time points.

As explained above, the rainfall observation device sets the activation interval of the timer circuit 3 to the long-time mode to the extent that a failure determination of the device is allowed when there is no rain, that is, unless a rainfall signal is input, and when there is rain.

The activation interval of the timer circuit 3 is switched to a short time mode so that rainfall amount data is transmitted immediately.

If there is a large amount of rainfall during this short-time mode,
Since these accumulated rainfall data are transmitted all at once, event changes due to rainfall are transmitted from time to time, and even if there is no rain, the accumulated rainfall data is transmitted by the timer in long-term mode. Therefore, the occurrence of an event and the normal operation of the device can be known in a timely and appropriate manner.

FIG. 4 shows a block diagram when the automatic transmission type observation device according to the present invention shown in FIG. The configuration is the same as that in FIG. 1 except that the water level change detection circuit IB is used, and the same parts as in FIG. 1 are given the same reference numerals and detailed explanations will be omitted.

FIG. 5 is a timing chart showing the operation of the water level observation device shown in FIG. 4, which will be explained below based on FIG.

(1) Power is applied to the device at time M, and the startup interval T
2 is sent to the long-term mode, for example after 3 hours.

(2) When the water level rises above the reference water level at time N, a water level signal is input from a water level meter (not shown) to the water level change detection circuit IB via the input line IL, and the main control circuit is activated by a start signal from the water level change detection circuit IB. 2 is activated, and the main control circuit 2 that receives the water level data following this activation signal transmits the transmission circuit 4.
The received water level data is transmitted to the transmission line OL.

In this case, when the main control circuit 2 transmits the water level data, it sends a switching signal to the timer circuit 3 to switch the long-time mode to the start interval TI'(r
Switch to short-time mode.

(3) Since the water level start signal is not output from the water level change detection circuit IB between the time N when switching to the short time mode and the time O, the start signal from the timer circuit 3 is sent to the main control circuit 2 at time 0. However, the main control circuit 2 switches the timer circuit 3 to the long-term mode without transmitting water level data.

(4) If water level data exceeding the reference water level is input at time P during this long-term mode, the device performs the same operation as at time N, and the timer circuit 3 switches to short-time mode. .

When water level data exceeding the reference water level is input at times Q and R during this short-time mode, these water level data are stored in the main control circuit 2. At time S after time TI, a start signal is sent from the timer circuit 3 to the main control circuit 2, and as a result, the main control circuit 2 is activated at time 1 Q.

Alternatively, the larger water level data in R is transmitted from the transmitting circuit 4 to the transmission line OL. In this case, since the device transmitted the water level data at time S, the timer circuit 3 connects the short time mode.

(5) Next, since the water level does not rise above the reference water level during the time T10 from time S to time T, the water level start signal is not input to the main control circuit 2, and at time T, the timer circuit 3
Similar to the operation at time O, the short time mode is switched to the long time mode, but water level data is not transmitted.

(6) When the water level activation signal is not output during the long-term mode period from time T to time T2 at time Ut, the activation signal is sent from the timer circuit 3 to the main control circuit 2 at time U, and the main control circuit 2 transmits the current water level data from the transmission circuit 4 to the transmission line OL, and also switches the timer circuit 3 from the long-time mode to the short-time mode.

(7) The water level rises above the reference water level at time point ■ between time point U and time T at time point w-1, and the water level start signal is output from the water level change detection circuit IB. The operation of the device is to transmit the water level data at time V as at time S, and the timer circuit 3 resumes operation in the short time mode.

Thereafter, since the water level does not exceed the reference water level during the time TI up to point X, at point 2 X, the device performs the same operation as at point T and enters the standby state.

In this way, when the water level is below the standard water level, it operates in long-term mode, and when the water level rises above the standard water level, it immediately sends water level data, and while operating in short-time mode for -1, the water level reaches the standard. If the water level rises and falls frequently, the system transmits the maximum value of the water level amount data during the short-time mode and continues the alarm mode to monitor changes in the water level, so the water level can be adjusted in a timely and appropriate manner. Changes can be sent automatically and the power consumption of the device can be kept to a minimum.

As described above, according to the present invention, when a change occurs in an event, the event data is immediately transmitted.

If a change in an event is unlikely to occur, the regularly accumulated event data can be automatically transmitted, so changes in the event can be observed and transmitted in a timely and appropriate manner, thereby preventing equipment failure. It is easy to judge, and -! The power consumption can also be reduced, which has the effect of configuring a telemeter system that is easy to maintain and operate and is highly economical.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing an embodiment of the present invention. Figures 2 and 3 are block diagrams and timing charts of the case where the automatic transmission type observation device according to the present invention is implemented in a rainfall observation device, and Figures 4 and 5 are the automatic transmission type observation device according to the present invention. They are a block diagram and a timing chart when the device is implemented in a water level observation device. ■...Event change detection circuit IA...Rainfall detection circuit 1B...Water level change detection circuit

Claims (1)

[Claims] An event change detection circuit; a main control circuit that is activated by an event change signal detected by the event change detection circuit and controls the transmission of received event data; and a main control circuit that controls the transmission of received event data; The main control unit controls the transmission circuit that transmits the event data to the line, and the long-time mode in which the timer time is long and the short-time mode in which the timer time that defines the control timing for transmitting the event data to the transmission circuit is a long time. and a timer circuit that is alternately switched by a switching signal from the circuit; The received event change data is transmitted by the main control circuit to the transmission line via the transmission circuit, and the timer time of the timer circuit is switched from the long-time mode to the short-time mode by a switching signal from the main control circuit. (b) If the event change detection circuit does not detect an event change while the timer time of the timer circuit is in the long-term mode, the activation signal from the timer circuit detects the event at that time. While data is transmitted to the transmission line via the transmission circuit, the timer time of the timer circuit is switched from the long-time mode to the short-time mode by a switching signal from the main control circuit; (c) the timer circuit If the event change detection circuit detects an event change while the timer time is in the short time mode, the event change data detected by the event change detection circuit is stored in the main control circuit, and the timer circuit The event change data stored in the main control circuit is transmitted to the transmission line via the transmitting circuit in response to the activation signal from above, but the timer time of the timer circuit is set to the angle short time mode, and (d) the above-mentioned If the event change detection circuit does not detect an event change while the timer time of the timer circuit is in the short time mode, the main control circuit receives a start signal from the timer circuit, but the main control circuit An automatic transmission type observation device characterized in that the timer time of the timer circuit is switched from a short time mode to a long time mode at the same time as stopping the transmission of event data.