JP2002267510A - Telemeter - Google Patents

Abstract

(57) [Problem] To provide a telemeter that has a simple configuration, a long life, does not require frequent maintenance, and does not require external power supply. SOLUTION: A power generation means 5 converts a part of kinetic energy of a flow of a fluid 1 such as gas or water flowing through a pipe 2 into electric energy, and using the electric energy, a transmitting / receiving means 7 The data of the integrated flow rate of the fluid measured by the flow meter 4 is transmitted to an external base station via the antenna 8. Further, by installing the secondary battery, the electric energy converted by the power generation means is stored, and the stored electric energy is used to receive external command information requesting transmission of the integrated flow rate data. .

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a telemeter for transmitting metered information to an external base station, and more particularly to measuring the usage of non-compressed fluid such as gas or water and transmitting the information to the external base station. Telemeter.

[0002]

2. Description of the Related Art Conventionally, a water meter, a gas meter, and the like are constituted only by means for measuring an integrated flow rate, and a meter reader periodically checks a meter installed in each home or the like to measure the meter usage, thereby reducing the amount of usage. Investigate and be charged based on this usage. In order to improve the efficiency of the meter reading operation, a telemeter that wirelessly transmits the measured information to an external base station has been proposed.

[0003]

The conventional telemeter is:
Either external power supply is required for operation, or a primary battery for power supply is provided inside the telemeter.
Therefore, there are problems such as the necessity of complicated wiring for power supply from the outside, the necessity of charging the electricity used for the telemeter, and the limited use period due to the life of the primary battery. Was.

In order to solve the above-mentioned problems, the present invention provides an integrated flow rate data of an uncompressed fluid which has a simple structure, a long life, does not require frequent maintenance, and does not require external power supply. To provide a telemeter for transmitting to In the present specification, an incompressible fluid is a fluid whose density change is negligible when considering the balance and motion of a fluid, or slower than the speed of sound, in accordance with the definition of the Iwanami Physical and Chemical Dictionary, 4th Edition (issued by Iwanami Shoten). It is a moving gas.

[0005]

To achieve the above object, a telemeter according to the present invention is a telemeter for transmitting data of an integrated flow rate of an incompressible fluid passing through a pipe to an external base station. Power generating means for converting a part of kinetic energy of the flow of the non-compressed fluid passing therethrough into electric energy, measuring means for measuring an integrated flow rate of the non-compressed fluid, and using the electric energy, Transmitting means for transmitting data to the external base station. With this configuration, it is possible to generate electric power by converting a part of the kinetic energy of the incompressible fluid passing through the pipe into electric power, eliminating the need to provide wiring for supplying power to the telemeter from the outside, and performing maintenance more frequently. It is no longer necessary to perform.

Further, the telemeter of the present invention is configured such that the power generating means includes a rotating means which rotates by passing the non-compressed fluid, and a power generating motor which generates electric power from the rotating motion of the rotating means. I have. With this configuration, it is possible to simplify the configuration of the power generation means,
The loss of kinetic energy of the incompressible fluid passing through the pipe can be reduced.

Further, the telemeter of the present invention is configured to further include a power storage means for storing the electric energy. With this configuration, it is possible to accumulate the electric power converted by the power generation means, and a backup battery is not required.

Further, the telemeter of the present invention is configured to further include a receiving means for receiving command information from the outside requesting transmission of the integrated flow rate data using the electric energy. With this configuration, there is no need to provide wiring for receiving command information from outside and / or transmitting integrated flow rate data to the outside, and it is possible to transmit and receive information to and from a telemeter installed at a remote location. Become.

In the telemeter according to the present invention, the transmission means transmits the integrated flow rate data and / or the receiving means receives the command information by wireless communication. With this configuration, it is possible to simplify the configuration of the power generation means, and it is possible to reduce the loss of the kinetic energy of the incompressible fluid passing through the inside of the pipe.

[0010] The telemeter of the present invention is configured to charge for the volume of the non-compressed fluid used. With this configuration, even if the kinetic energy of the non-compressed fluid decreases, the volume does not change, so that it is possible to prevent the power generation by the non-compressed fluid from affecting the charge for the integrated flow rate of the non-compressed fluid. .

Further, the telemeter of the present invention is configured such that the non-compressed fluid is gas or clean water. With this configuration, the telemeter of the present invention can be applied to a gas meter or a water meter.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a telemeter according to the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing one embodiment of the entire system relating to the telemeter of the present invention. The entire system shown in FIG. 1 uses, for example, a stainless steel pipe having an inner diameter of about 20 mm, and is opened by a pipe 2 for passing a fluid (non-compressed fluid) 1 such as gas or water supply, a water supply company or the like. A stopcock 3 to be plugged or closed, a flow meter 4 for measuring an integrated flow rate, a power generation means 5, a charging block 6 for rectifying and storing the AC power 31 generated by the power generation means 5, a transmission / reception means 7, and an antenna 8 Be composed.

The power generation means 5 and the charging block 6, the charging block 6 and the transmission / reception means 7, the flow meter 4 and the transmission / reception means 7 are connected to each other. The power supply 32 for operating the transmission / reception means 7 is supplied from the block 6 to the transmission / reception means 7, and the integrated flow rate data 33 from the flow meter 4 is supplied from the flow meter 4 to the transmission / reception means 7.
Further, command information 34 from the outside is received from the antenna 8, and a data request signal 40 of the integrated flow rate is output to the flow meter 4, so that the integrated flow rate data 33 is obtained from the flow meter 4 and the measurement information is obtained. 35 is transmitted.

First, the power generation means 5 and the charging block 6 will be described with reference to FIG. FIG. 2 is a detailed block diagram relating to the power generation means and the charging block of FIG. The power generating means 5 is installed in the pipe 2, and forms a rotating means together with the rotating wings 51, which rotates with the movement of the fluid 1, and a rotating shaft 52 which transmits a rotating motion to the power generating motor 53, for example, It is composed of a power generation motor 53 using a permanent magnet having high volume efficiency.

The rotary wing 51 receives a flow of fluid in the axial direction in the pipe 2, and generates a plurality of fins that can rotate around the rotary shaft 52 in a plane substantially perpendicular to the rotary shaft 52 by the stress. It is preferable that a member having high strength and high chemical stability be used. In particular, when the fluid 1 is clean water, it is preferable to use a polyacetal resin or the like that is highly safe for the human body as a material of the rotary wing 51. Further, it is preferable that the surface of the rotary blade 51 is further coated with fluorine so as to reduce friction.

The charging block 6 converts AC power 31 such as a diode bridge into DC (pulsating) power 37.
And a secondary battery (power storage means) 62 for storing electric energy (electric power). As the secondary battery 62, a sealed type having a small leakage current is suitable, and an alkaline battery, a nickel-cadmium battery, a capacitor that stores electricity in the form of electric energy, or the like can also be used. The backflow from the secondary battery 62 to the rectifier 61 can be prevented by using a diode clamp or the like. The electric power charged in the secondary battery 62 is used as electric power 32 supplied to the transmitting / receiving means 7.

The kinetic energy taken in by the rotating means is converted into electric energy (AC power 31) by the electric motor 53 and sent to the charging block 6. For example, a fluid 1 having a mass m before passing through a rotating means constituted by a rotating blade 51 and a rotating shaft 52 and a motor 53 for power generation.
The velocity of the fluid 1 having the mass m after passing
Then, kinetic energy of m × (v ² −v ′ ² ) / 2 is taken in by the rotating means and the motor 53 for power generation. The fluid 1 such as gas or clean water is an incompressible fluid, and gas and clean water are often charged according to the volume used. Therefore, even if the kinetic energy of the fluid is taken in by the rotating means and the power generation motor 53, it does not affect the charging of the fluid 1 such as gas or clean water. The electric energy converted by the power generation motor 53 is a value obtained by multiplying the kinetic energy taken in by the power generation motor 53 by the power conversion efficiency of the power generation motor 53.

Next, referring to FIG.
Will be described. FIG. 3 is a detailed block diagram relating to the transmission / reception means of FIG. The transmission / reception means 7 includes a transmission / reception block 71, a control block 72, a data block 7
3. It is composed of a regulator block 74. For example, when command information 34 from an external facility such as a base station is input to the transmission / reception block 71 via the antenna 8, the transmission / reception block 71 requests the integrated flow rate of gas or water (use amount). The content of 34 is transmitted to the control block 72 as a command signal 38. The control block 72 transmits a data control signal 39 for controlling the data block 73 to the data block 73 according to the command signal 38.

The data block 73 receives the data control signal 39, transmits a data request signal 40 of the integrated flow rate to the flow meter 4, and is transmitted from the flow meter 4 in response to the data request signal 40 of the integrated flow rate. Integrated flow data 3
3 is received. Then, the data block 73 adds necessary data such as the identification number of the transmission / reception means 7 to the integrated flow rate data 33, and transmits it as the measurement data 41 to the control block 72. The control block 72 adds data such as a date and a device number to the measurement data 41, performs coding corresponding to the transmission form, and transmits the data to the transmission / reception block 71 as transmission data 42. The transmission / reception block 71 transmits the measurement information 35 via the antenna 8 to an external facility such as a base station.

In the operation of each of the above means, the supply power 32 supplied from the charging block 6 is reduced by the regulator block 74.
The AC voltage 43 converted into a required voltage by the above is used. Further, the transmitting / receiving means 7 is set to a standby state so that the command information 34 can always be received, and the command information 3
4 is preferably divided into a part that operates during a period from when the measurement information 35 is received to when the measurement information 35 is transmitted to the base station,
This makes it possible to reduce power consumption. In order to further reduce power consumption, it is preferable to use a semiconductor such as a C-MOS with low power consumption as a circuit element.

In particular, when the fluid 1 is clean water, it is installed in a water pipe (pipe 2), so that all the blocks in the above embodiment are often provided underground. Therefore, it is preferable to select, as the frequency of the radio wave used for transmission and reception by the antenna 8, an electric field signal strength that enables transmission and reception of a radio wave from the ground, or to arrange the antenna 8 near the ground surface. In addition, transmission and reception with the outside can be performed using a transmission medium such as a conductive cable or an optical fiber without using the antenna 8.

Also, for example, a meter reading of a normal water meter is as follows.
Often every two months. On the other hand, if the kinetic energy obtained from the flow of the tap water used for two months is converted into electric energy and the stored power is used, the power used for the standby state of the transmission / reception means 7 and the information transfer about three times (command The processing from the reception of the information 34 to the completion of the transmission of the measurement information 35) can be performed. Therefore, if the power generated by the power generation means of the telemeter of the present invention is used,
It is sufficiently possible to actually measure the usage and transmit the measurement information 35 to the base station.

Further, an impeller type flow meter may be used as the flow meter 4 in some cases. In this case, the rotor 5 of the power generation means 5
Power generation can be performed using the impeller of the flow meter 4 instead of 1. However, since a part of the rotational energy of the impeller is converted into electric energy, it may be impossible to measure the integrated flow rate accurately. Therefore, it is necessary to provide a means for correcting the integrated flow rate or to change the setting of the relationship between the rotation of the impeller and the integrated flow rate.

In the above embodiment, when no gas or water is used, the rotating blades 51 of the power generation means 5 do not rotate, and it becomes impossible to store power in the secondary battery 62. Therefore, as a source for supplying auxiliary power,
Furthermore, it is also possible to provide a primary battery or supply power from the outside.

In the above embodiment, the secondary battery 62
The measurement information 35 is transmitted to an external facility such as a base station using the electric power accumulated in the base station, and it is possible to read the meter easily and in a short time as compared with the conventional meter reading. In the meter, it is also possible to use the power generated by the fluid 1 to display the amount of use of the meter meter on a liquid crystal display or to turn on a backlight so that the meter reader can easily perform meter reading.

[0026]

As described above, the telemeter of the present invention comprises a power generating means for converting a part of the kinetic energy of a flow of an incompressible fluid passing through a pipe into electric energy, and an integrated flow rate of the incompressible fluid. By a configuration having a measuring means for measuring and a transmitting means for transmitting data of the integrated flow rate to an external base station using electric energy, a part of the kinetic energy of the incompressible fluid passing through the pipe is converted into electric power. Power generation from the outside, eliminating the need to provide wiring for supplying power to the telemeter from the outside, and eliminating the need for frequent maintenance.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of an entire system relating to a telemeter of the present invention.

FIG. 2 is a detailed block diagram of a power generation unit and a charging block of FIG. 1;

FIG. 3 is a detailed block diagram relating to a part of the transmitting / receiving means of FIG. 1;

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Fluid (non-compressed fluid) 2 Pipe 3 Stopcock 4 Flow meter 5 Power generation means 6 Charging block 7 Transmission / reception means 8 Antenna 31 AC power 32 Supply power 33 Accumulated flow data 34 Command information 35 Measurement information 37 DC power 38 Command signal 39 Data control signal 40 Data request signal of integrated flow rate 41 Measurement data 42 Transmission data 43 AC voltage 51 Rotor blade 52 Rotary shaft 53 Power generation motor 61 Rectifying means 62 Secondary battery (power storage means) 71 Transmission / reception block 72 Control block 73 Data block 74 Regulator block

Continued on the front page F term (reference) 2F030 CC02 CC13 CE06 CE09 CE22 CE25 2F031 AE09 AF04 2F073 AA04 AA07 AA08 AB02 BB01 BB04 BB06 BC02 CC07 CC09 CC12 DE11 EE11 EE13 EF09 FF01 FG01 FG02 GG01 5K048 HA36 DB01

Claims (7)

[Claims] 1. A telemeter for transmitting data of an integrated flow rate of a non-compressed fluid passing through a pipe to an external base station, wherein a part of kinetic energy of the flow of the non-compressed fluid passing through the pipe is electrically converted. Power generation means for converting the energy into energy, measuring means for measuring the integrated flow rate of the non-compressed fluid, and transmission means for transmitting the integrated flow rate data to the external base station using the electric energy. Telemeter. 2. The power generation device according to claim 1, wherein the power generation device includes a rotation device that rotates by passing the incompressible fluid, and a power generation motor that generates electric power from a rotational motion of the rotation device. Telemeter. 3. The telemeter according to claim 1, further comprising a power storage means for storing the electric energy. 4. The apparatus according to claim 1, further comprising a receiving unit that receives command information from the outside requesting transmission of the integrated flow rate data using the electric energy. The telemeter according to. 5. The transmission of the integrated flow rate data by the transmission unit and / or the reception of the command information by the reception unit is performed by wireless communication. A telemeter according to one. 6. The telemeter according to claim 1, wherein billing is performed according to the volume of the non-compressed fluid used. 7. The telemeter according to claim 1, wherein the non-compressed fluid is gas or tap water.