JPH04155222A - Liquid quantity meter with pulse transmitter - Google Patents

Abstract

PURPOSE:To obtain a highly sensitive and highly reliable flowmeter with a longer life without supply of a power source by using an amorphous power source free magnetic sensor in a pulse oscillator. CONSTITUTION:A pulse oscillator 1 is fitted into the top surface of an upper case 5 of a flowmeter 2, amorphous power source free magnetic sensors 8 are mounted on a magnet 9 for oscillation such as multipolar ferrite magnet at a specified interval and a shield plate 10 is arranged covering the sensors 8. With such an arrangement, the magnetic sensors 8 detect a change in magnetic field caused by the magnet 9 for oscillation rotating to generate a pulse signal, which is outputted to a remote transmitter 3 to count and display. This detection is performed by an electromagnetic induction in a noncontact manner and requiring no external power source and a high electromotive force is obtained by a sensitive magnetic characteristic to be gained from an atomic irregular array in amorphous metal.

Description

[Detailed Description of the Invention] (Industrial Application Field) This invention detects the flow rate of a liquid such as hot water or tap water, and sends this as a pulse signal to a remote receiver located at a distant location. Relating to a liquid meter with a pulse transmitter.

(Prior art) A flow meter for water or hot water is installed in the middle of a pipe, and uses a gear mechanism to slow down the rotation of an impeller that receives flowing water, and displays this on a numeric wheel-type display. . In this case, the flow rate detection position is in a position that is difficult to see, as in the case of a water flow meter, for example, in a meter box installed on the ground, making it inconvenient to read. Therefore, a pulse transmitter is attached to the flow meter,
The pulse signal that will be emitted will be used to display the flow rate, such as the amount of water used, on a remote receiver installed at the entrance, etc., for easy reading.

Conventionally, a reed switch has been used as this pulse transmitter.

This reed switch is placed opposite a transmitting magnet rotated by an impeller, and is turned on and off each time its magnetic pole passes. The remote receiver applies voltage to the reed switch through a signal line, detects whether or not the reed switch is energized, counts the number of times it is turned on and off, and displays the integrated value of flow rate, etc. Meter readers can easily take readings using remote receivers mounted in easily visible locations.

(Problem M to be solved by the invention) The reed switch described above has the following problems.

First, the contact deteriorates due to the on/off operation of turning the edges, so it cannot be used for a long period of time.

Second, the glass case that makes up the reed switch,
Due to the difference in thermal expansion coefficient between the metal lead and the fixing resin, there is a risk of cracking or unstable operation due to large temperature changes, such as when used as a hot water meter that can reach temperatures as high as 130°C. I have anxiety about this.

Third, because the magnetic sensitivity is low, even if a high-magnetic transmitting magnet is used, it is necessary to place it close to each other, for example, at about 21 m.
There are restrictions on assembly.

Fourthly, it is necessary to supply current from the outside for detection, resulting in a complicated circuit and high power consumption.

Fifth, if a magnet is brought close from the outside, it cannot be turned on or off, so a magnetic shield is required, but even if a press-molded general soft iron plate is used for this magnetic shield, a good shielding effect can be obtained. was not obtained. In other words, it becomes magnetized by itself and interferes with the operation of the reed switch, and if it is thin, the shielding from external magnetism will be incomplete, and if it is thick, it will absorb the magnetic force of the internal transmitting magnet and will not be able to apply a sufficient magnetic field to the reed switch. become unable.

Therefore, an object of the present invention is to provide a liquid level meter having a pulse transmitter that solves these problems all at once.

(Means for Solving the Problems) This invention uses a pulse transmitter to detect the movement of a transmitting magnet rotated by an impeller that rotates in response to the flow of liquid in piping, and transmits the pulse output to a remote receiver. This pulse transmitter is composed of a rod-shaped amorphous metal wound with an extremely thin conductive wire, and an amorphous unpowered magnetic sensor placed opposite the above-mentioned transmitting magnet, and this amorphous To provide a liquid level meter with a pulse transmitter configured by an amorphous metal shield plate surrounding only an iI source-free magnetic sensor.

In order to make this pulse transmitter particularly compact, the amorphous metal shield plate is shaped like a cylinder with openings at both ends, and an opening that penetrates in the axial direction is formed on the side facing the transmitting magnet. The present invention also provides a structure in which the rod-shaped amorphous IIT source magnetic sensor is arranged along its axis.

(Function) In the above configuration, the amorphous unpowered magnetic sensor:
It detects changes in the magnetic field caused by the rotating transmitter magnet, generates a pulse signal, and outputs it to a remote receiver. This detection is performed by electromagnetic induction without contact and without the need for an external power source, and a high electromotive force can be obtained due to the sensitive magnetic properties obtained from the irregular arrangement of atoms in the amorphous metal.

In addition, the amorphous metal shield plate that covers only this amorphous non-power magnetic sensor prevents external magnetic fields from reaching the amorphous non-power magnetic sensor due to its characteristic of not incorporating surrounding magnetic flux into the amorphous non-power magnetic sensor.
To link an amorphous powerless magnetic sensor without reducing the magnetic field generated by a transmitting magnet.

Furthermore, reliability is increased due to the extremely low coercive force.

Note that the performance of these amorphous power-free magnetic sensors and amorphous metal shield plates is not affected at all, both electrically and mechanically, at a temperature comparable to that of heated water (for example, at a maximum of 130° C.).

In addition, as an amorphous metal shield plate, it is possible to prevent external magnetic fields from acting on the amorphous unpowered magnetic sensor.
Since we have provided a small-sized device that allows the magnetic field of the transmitting magnet to act effectively, the pulse transmitter can be miniaturized and can be easily attached or incorporated into the meter.

(Embodiment) Fig. 1 shows the internal configuration of an embodiment of the pulse transmitter (1) of the present invention, and Fig. 2 shows the internal configuration of an embodiment of the pulse transmitter (1) of the present invention.
1 is a diagram showing an overall configuration in which a pulse transmitter (1) is attached to a remote controller, and a pulse signal generated by the pulse transmitter is inputted to a remote receiver (3) attached at a front door or the like through a remote cable line (4).

In FIG. 2, the pulse transmitter (1) is connected to the flow meter (
2) It is fitted and held onto the upper surface of the upper case (5) and covered with its lid (6).・This flow meter (2) uses a gear mechanism to slow down the rotation of an impeller that is placed in the flow path of the flow meter body (2a) and receives the fluid flow. It is displayed by the number wheel-style designation m oval (7) provided below. The pulse transmitter (1) should be attached to the upper case (5) in a position that does not hide the number wheel. Note that the lid (6) may have the same structure as the conventional one except that a hole (6a) for passing the remote cable line (4) is provided.

The remote receiver (3) cumulatively counts the pulse signals received from the pulse transmitter (]) and displays them on its display section (3a).

A pulse oscillator (1), which is a feature of the present invention, has an internal structure as shown in FIG.

That is, an amorphous powerless magnetic sensor (8).

However, when transmitting magnets such as multipolar ferrite magnets (
9) at a predetermined interval, and an amorphous metal shield plate (lO) is arranged so as to cover this amorphous non-power source magnetic sensor (8). These amorphous non-power magnetic sensor (8) and amorphous metal shield plate (10) are arranged so as to maintain their positional relationship.
It is assembled inside a plastic case (11).

This case (11) is manufactured in a shape that fits into a recess on the upper surface of the upper case (5) and occupies a predetermined position, thereby maintaining a constant opposing relationship with the transmitting magnet (9).

The transmitting magnet (9) is attached to the end of the branching gear mechanism that receives the rotation of the impeller in the flow meter body (2a) via the deceleration gear. If there is sufficient internal space, it can be attached directly to the impeller.

The above-mentioned amorphous powerless magnetic sensor (8) is constructed by winding an ultra-fine coil around an amorphous metal core, and the amorphous metal generates an electromotive force due to its sensitivity to magnetism caused by the irregular arrangement of internal atoms. The sensor is very large and has good sensitivity. In addition, even when this amorphous powerless magnetic sensor (8) is installed in a hot water flow meter, the operating temperature is about 80 to 13
At 0°C, the characteristics are not affected and it can be used without any problems.

Further, the amorphous metal shield plate (lO) may be of any shape as long as it covers only the amorphous powerless magnetic sensor (9).

The shield m (10) in the illustrated example has a cylindrical shape with openings at both ends in order to obtain a good magnetic shielding effect while reducing the size, and has an opening penetrating in the axial direction on the side facing the transmitting magnet (9). (10a), and an amorphous magnetic sensor (8) is formed in the center along the axial direction of the magnetic sensor (10a).
are placed.

The dimensions of this shield plate (lO) are as follows:
9) and the spacing between them, but according to experimental data, its length L should be at least three times the total length 1 of the source magnetic sensor (8) without amorphous material 1, and the diameter should be The size of the opening (10a) is about 3 to 4 times the diameter d of the amorphous non-power magnetic sensor (8).
The radius B is preferably about 1/2 of the diameter of the shield plate (lO). Shielding by this amorphous metal shield plate (lO) is performed well due to the irregular arrangement of atoms in the amorphous metal, which does not allow external magnetic fields to pass inside and does not attract the magnetic field of the transmitting magnet (9). . This shielding effect can be obtained even if the shield plate (lO) is made quite thin, for example, 0.4
1 had sufficient effect. Further, the shield plate (lO) may have a cylindrical shape, but since the illustrated example is cylindrical, the lower edge is bent so as to bite into the opening (10a). Due to its shape, it is less susceptible to external magnetic fields, increasing its effectiveness.

The magnetic properties of the amorphous metal have not been completely elucidated theoretically at present, but have been confirmed experimentally.

In addition, in the above embodiment, the pulse transmitter (1) is used after being attached to the flow meter (2), but the amorphous non-power magnetic sensor (
8) and an amorphous metal shield plate (10), it is possible to connect the remote cable 11 from the flow meter to the amorphous metal shield plate (10).
! It is also possible to have a structure in which (4) is directly extracted.

(Effects of the Invention) According to the present invention, by using an amorphous powerless magnetic sensor as a pulse transmitter, it is possible to detect the flow rate with high sensitivity and output a pulse signal without supplying [1] from the outside. Moreover, since it is non-contact, it has a long life and can be used with high reliability. Furthermore, since it is electrically and mechanically stable even at high temperatures, it is easy to manufacture liquid level meters for hot water.

In addition, since an amorphous metal shield plate is used, magnetic shielding from external magnetic fields can be achieved without affecting the internal magnetic field.In particular, since it covers only the amorphous non-power magnetic sensor, It is possible to provide a pulse transmitter that is miniaturized and can be easily installed, for example, by fitting it into the lid of a flow meter.

[Brief explanation of drawings]

FIG. 1 is a perspective view showing the configuration of a main part of a preferred embodiment of a pulse transmitter used in a liquid level meter according to the present invention. FIG. 2 is a perspective view showing the overall structure of an embodiment of the liquid meter of the present invention. (1)...pulse transmitter, (2)...flow meter,
(3)...Remote receiver, (4)...Remote cable line, (6)...Lid, (8)...Amorphous unpowered magnetic sensor, (9)...
...Sending magnet, (10)...Amorphous metal shield plate.

Claims (2)

[Claims] (1) A pulse transmitter detects the movement of a transmitting magnet rotated by an impeller that rotates in response to the flow of liquid in the piping, and a remote receiver receives the pulse output and counts and displays it. This pulse transmitter is composed of a rod-shaped amorphous metal wound with an ultra-thin conductive wire, and includes an amorphous non-power magnetic sensor placed opposite to the above-mentioned transmitting magnet, and an amorphous metal surrounding only this amorphous non-power magnetic sensor. A liquid level meter with a pulse transmitter, characterized in that it is configured by a shield plate and a shield plate. (2) In the liquid level meter with a pulse transmitter according to claim 1, the amorphous metal shield plate has a cylindrical shape with both ends open, and an opening that penetrates in the axial direction on the side facing the transmitting magnet. 1. A liquid level meter with a pulse transmitter, characterized in that the rod-shaped amorphous non-power magnetic sensor is arranged along its axis.