JP3261644B2 - Field measuring instrument - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001] The present invention relates to the field instrument equipped with a microcomputer.

[0002]

2. Description of the Related Art A field measuring instrument having the possibility of being controlled by a microcomputer composed of a CPU, a main memory (RAM), and the like, stores a measurement result that changes every moment as a digital value in an internal main memory. are doing. And
These data can be transmitted and output to the outside by communication means as needed. In such a device, the data held in the main memory must be saved to a storage means for holding the data when the power is off, even if the power is not turned on. An electrically rewritable E ² PROM
and so on.

[0003] Therefore, the power supply is turned off, until the retraction of the data is completed, the circuit is energized state, it is necessary to perform the E ² PROM like retreat of data from main memory. Power during this period is usually supplied from a capacitor in front of the regulator of the power supply unit. This is also the case when the power supply is momentarily interrupted.For example, when power is supplied from commercial power supply, even if the power supply is stopped due to a power failure, the main memory is supplied by the power supply from the capacitor. The above data is saved.

[0004]

However, if the amount of data to be saved increases, the saving time naturally increases, and the power supply required for this also increases. Then, a large capacitor is used to compensate for this.
However, in the field measuring device as described above, it is necessary to reduce the size of the entire measuring device due to the problem of the installation environment. Therefore, the use of a large capacitor has a problem that the measuring device becomes large, and there is a problem that deterioration of the capacitor mounting portion due to the vibration becomes more remarkable. The use of a capacitor having a large capacity leads to an increase in cost.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and does not cause an increase in the size of the apparatus or a decrease in reliability, for example, by using a large capacitor.
The purpose is to allow more data to be saved.

[0006]

According to the power supply method of the present invention, a CPU for receiving a measurement result from a measurement unit ,
U, the measurement results received by the CPU are stored,
Main memory, capable of storing hand rewriting data by connecting to the CPU to continue to retain stored while the power is being supplied
A main circuit provided with a stage, are controlled by connecting to the CPU
A sub-circuit that sends a measurement result of CPU has received to other devices, and converts the power being supplied to a predetermined voltage Rights
Supplied to main and sub circuits as smoothed DC
Transformer, rectifier circuit, first capacitor,
A power supply comprising a regulator and a second capacitor; a monitoring circuit for monitoring a state of the power supplied from the power supply; and a voltage of the supplied power being a predetermined value or less.
When the monitoring circuit detects that the
A switch for disconnecting the power supply, and when the monitoring circuit detects that the voltage of the supplied power has dropped below a predetermined value , the power stored in the first and second capacitors is used as the main power. Supply only to the circuit , CPU is in the main memory
The stored data is saved in the storage means .

[0007]

The stored power is used for the operation of the CPU required when the supplied power is less than a predetermined amount.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a configuration diagram showing a configuration of a field measurement device according to an embodiment of the present invention. In the figure, 1 is a main circuit, 2 is a CPU, 3 is a main memory, 4 is E ² PRO
M, 5 are sub-circuits, 6 is a voltage monitoring circuit, 7 is a switch,
8 is a regulator, 9 is a rectifier circuit, 10 is a transformer, 11
Is a bus connecting the CPU 2, the main memory 3, and the like. In this field measurement device, the CPU 2 receives a measurement result from a measurement unit (not shown) via the bus 11,
This is stored in the main memory 3 as needed. Further, the measurement results are transmitted to other devices via the communication interface of the sub-circuit 5 or the like.

Normally, the main circuit 1 and the sub circuit 5
The power is reduced to a predetermined voltage by the transformer 10, and a smooth DC power is supplied by the rectifier circuit 9, the capacitors C 1 and C 2, and the regulator 8. Here, when the power supply is stopped, the voltage monitoring circuit 6 detects the drop in the voltage and notifies the bus 11 so as to enter the data saving mode.
Output to the top. CPU 2 that has received this data saving mode
Starts saving the data on the main memory 3 to the E ² PROM 4.

At the same time, when a data save mode signal flows on the bus 11, the switch 7 receiving this signal cuts off the supply of power to the sub-circuit 5. Thus, the power supplied from the capacitors C1 and C2 due to the stop of the power supply is supplied only to the main circuit 1. In other words, the capacitors C1 and C2 need only supply the power necessary for the data saving operation, so that even if the saving data is large, it is not necessary to use a large one.

[0011]

As described above, according to the present invention, when the monitoring circuit detects that the voltage of the supplied power drops below a predetermined value, the stored power is transferred to only the main circuit. It was made to supply. As a result, the stored power is used only for operations necessary when the power supply is stopped, such as saving data. As a result, there is an effect that more data can be saved even if the storage capacity is not so large.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing a configuration of a measuring instrument according to an embodiment of the present invention.

[Explanation of symbols]

1 ... main circuit, 2 ... CPU, 3 ... main memory, 4 ... E ² P
ROM, 5: sub circuit, 6: voltage monitoring circuit, 7: switch, 8: regulator, 9: rectifier circuit, 10: transformer section,
11 ... Bus.

Claims (1)

(57) [Claims] 1. A CP for receiving a measurement result from a measurement unit.
U , measurement connected to the CPU and received by the CPU
Results are stored, and a main circuit between the having a main memory, is capable of storing hand stage rewriting data by connecting to the CPU that continues to hold the stored power is supplied, the control and connected to the CPU Received by the CPU
A sub-circuit measurement results that sends to the other device has been smoothed by converting the power being supplied to a predetermined voltage
Supply to the main circuit and the sub-circuit as direct current
Transformer, rectifier circuit, first capacitor,
A power supply unit comprising a regulator and a second capacitor; a monitoring circuit for monitoring a state of the power supply supplied from the power supply unit; and a monitoring circuit for confirming that a voltage of the supplied power has dropped below a predetermined value.
Supply to the sub-circuit when the monitoring circuit detects
A switch for turning off the power supply , wherein when the monitoring circuit detects that the voltage of the supplied power supply falls below a predetermined value, the first and second capacitors are turned off.
Supplying power which has been accumulated in the capacitors only in the main circuit
The CPU stores the data stored in the main memory.
Field stored in the storage means
Measuring instrument .