JP2501834B2 - Telemetry device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention provides a remote measuring device capable of detecting reverse installation of a water meter, gas meter, etc., and in particular, enables a water faucet to be freely opened and closed even when reverse installation is detected. The present invention relates to a remote measuring device.

[Prior Art] FIG. 2 is a perspective view showing a partial block diagram of the configuration of a conventional remote measuring device. In the figure, (1) is a measuring instrument such as a water meter, and (2A) is this water meter (1). Water inlet,
(2B) is a water outlet of the water meter (1), (3) is a rotation measurement unit such as an impeller in the water meter (1), and (4A) is a reduction gear train (8) to this impeller (3). The first coupling magnet, (4B), which is connected with the water meter, is the water meter (1).
A second coupling magnet, which is disposed outside and above the first coupling magnet (4A) so as to face it, and (5) is the same shaft (no reference numeral) as the second coupling magnet (4B) is attached. Anti-reverse body attached to
(6) is a pulse generator, and an impeller (6A) integrally attached to the second coupling magnet (4B), and this impeller (6A) pass between the light emitting side and the light receiving side. It consists of a photo interrupter (6B) attached to the. Reference numeral (7) is a receiver electrically connected to the pulse generator (6), and a power supply circuit (7A) for supplying a voltage to each circuit in the photo interrupter (6B) and the receiver (7). , A resistor (7B) connected between the photo interrupter (6B) and the ground, a changeover switch (7C) in which an electric contact (unsigned) is connected to the non-grounded end of this resistor (7B), this changeover switch Counter circuit (7D) connected to fixed contact (A) of (7C), indicator (7E) connected to output side of this counter circuit (7D), and fixed contact (B) of changeover switch (7C) It has a reverse rotation detection circuit (7F) connected between the display and the display (7E). The conventional telemetry device is configured as described above, and when the water meter (1) is properly installed, water enters the water meter (1) through the water inlet (2A) and the water outlet ( 2B), during which the water flow acts on the impeller (3) to rotate the impeller (3) forward (counterclockwise) in proportion to the flow rate. 1st coupling magnet (4A)
Rotates together with the impeller (3). The second coupling magnet (4B) is the first coupling magnet (4B).
A) magnetically coupled to rotate. The reverse rotation prevention body (5) and the impeller (6A) are the second coupling magnet (4B).
Rotates together with. At this time, since the reverse rotation preventing body (5) is in the normal rotation state, it does not hinder the rotation of the impeller (6A) and the like. The impeller (6A) rotates between the light emitting side and the light receiving side of the photo interrupter (6B), and portions with blades and portions without blades pass alternately.

When a voltage is supplied from the power supply circuit (7A) of the receiver (7) to the photo interrupter (6B), a metering signal, for example, a pulse voltage shown in FIG. 3 is generated across the resistor (7B). The period of each pulse voltage is T ₁ , T ₂ , T ₃ , T ₄ ,
And T _5. At this time, if the changeover switch (7C) is set to the (A) side, the counter circuit (7D) counts the pulse voltage,
The count value is integrated and displayed on the display (7E).

When the water meter (1) is installed in reverse, water enters from the outlet (2B) and escapes to the inlet (2A), during which the water flow acts on the impeller (3) to drive the impeller (3). Rotate in reverse (rotate right) in proportion to the flow rate. The first coupling magnet (4A) rotates together with the impeller (3). The second coupling magnet (4B) is magnetically coupled to the first coupling magnet (4A), and the second coupling magnet (4B) of FIG.
It rotates in the reverse direction as shown in (b). Since the impeller (6A) also rotates integrally with the second coupling magnet (4B), the space between both ends of the resistor (7B) of the receiver (7) is shown in FIG.
The pulse voltage shown in (c) is generated.

Next, when the second coupling magnet (4B) is in the state shown in FIG. 4 (c), the action of the reverse rotation preventing body (5) causes the second coupling magnet (4B) and the impeller (6A) to move. Rotation is blocked. At this time, a constant voltage is generated across the resistor (7B) as shown in FIGS. 5 (c) to 5 (e), and no pulse is generated. Next, when the first coupling magnet (4A) is rotated to the state shown in FIG. 4 (e), the first coupling magnet (4A) and the second coupling magnet (4B) are shown in FIG. 4 (e). Rotate at high speed. Since the impeller (6A) also rotates at high speed integrally with the second coupling magnet (4B), the high frequency pulse voltage shown in Fig. 5 (e) to (f) is applied between both ends of the resistor (7B). Occurs. From the state shown in FIG. 4 (f), the same operation as in the state shown in FIG.

In order to detect the reverse rotation state of the impeller (3) in a conventional telemetry device, first switch the selector switch (7C) of the receiver (7) to the (B) side, and place between both ends of the resistor (7B). The pulse voltage generated at is input to the reverse rotation detection circuit (7F). The reverse rotation detection circuit (7F) reads the pulse intervals T _{1 to} T ₇ shown in FIGS. 3 and 5.

When a constant flow rate of water is continuously supplied to the water meter (1), the impeller (3) normally rotates in the state where the water meter (1) is properly installed, and the third rotation to the reverse rotation detection circuit (7F). The pulse voltage shown in the figure is input.

Since a constant flow rate is flowing to the water meter (1), T ₁ =
T ₂ = T ₃ = T ₄ = T ₅ . Therefore, in the reverse rotation detection circuit (7F), the impeller (3) is rotating normally, and by extension the water meter (1).
Is judged to have been installed correctly and this is displayed on the display (7E).

When the water meter (1) is installed reversely, the impeller (3) rotates in the reverse direction, and the pulse voltage shown in FIG. 5 is input to the reverse rotation detection circuit (7F).

In this case, a constant flow rate of water is being supplied to the water meter (1), but T ₆ << T ₇ . Therefore, the reverse rotation detection circuit (7
F) judges that the impeller (3) is rotating in the reverse direction and the water meter (1) is installed in reverse, and the indicator (7)
Display this in E).

[Problems to be Solved by the Invention] In the conventional telemetry device, in order to detect the reverse installation of the water meter (1), the changeover switch (7C) is switched, and the water meter (1) has a constant flow rate of water. Since it is necessary to continuously run the water, the opening and closing of the water faucet (not shown) connected to the water meter (1) is restricted, and during this time the water faucet cannot be opened and closed freely. There was a point.

The present invention has been made to solve the above-mentioned problems, and can detect reverse installation of a water meter in a normal use state without restricting opening / closing of a water faucet connected to the water meter. The purpose is to obtain a telemetry device.

[Means for Solving Problems] A telemetry device according to the present invention has a rotation measuring unit that rotates in proportion to a flow rate, and the first coupling magnet is connected to the rotation measuring unit via a reduction gear train. It is connected to the equipped measuring instrument through a second coupling magnet that faces the first coupling magnet, and is connected to a reverse rotation preventing body that prevents the second coupling magnet from rotating in the reverse direction, and is connected to the reverse rotation preventing body. , A pulse generator that generates a weighing signal for each predetermined measurement amount, and a pulse in the weighing signal generated by the pulse generator when the rotation measuring unit is normally rotating when the measuring device is properly installed It is equipped with a receiver that displays the total number, and when the measuring device is installed in reverse and the rotation measuring part is rotating in the reverse direction, the high level in the weighing signal generated by the pulse generator regardless of the water flow rate. A high-frequency pulse discriminating circuit including a band-pass filter for identifying and receiving that a predetermined number of frequency pulses have been continuously input and notifying that the measuring instrument is installed in reverse is provided.

[Operation] In the present invention, the reverse rotation detection of the impeller can be performed while the normal use state is continued without keeping the opening of the faucet connected to the water meter constant during the test.

[Embodiment] FIG. 1 is a perspective view showing a partial block diagram of the configuration of an embodiment of a remote measuring device of the present invention.
(7) is the same as the conventional example. (7G) is a bandpass filter used in the present invention, and is connected between the photo interrupter (6B) and the reverse rotation detection circuit (7F).

In the telemetry device configured as described above,
When the water meter (1) is properly attached, the pulse voltage shown in FIG. 3 is generated across the resistor (7B) of the receiver (7) as in the conventional example. The pulse voltage is counted by the counter circuit (7D) and the count value is displayed on the display (7E).

Even if the water meter (1) is installed backwards,
Similar to the conventional example, the voltage shown in FIG. 5 is generated across the resistor (7B) of the receiver (7). The band pass filter (7G) can pass the frequency of the high frequency pulse shown in FIGS. 5 (e) to (f), but does not pass the frequency of the pulse shown in FIG. When the pulse passes through the band pass filter (7G), the reverse rotation detection circuit (7F)
Detecting this, the water meter (1) for the display (7E)
Indicates that the is installed in reverse.

As a measuring instrument to be detected, a measuring instrument such as a gas meter or a power meter having a rotation measuring section may be used.

[Advantages of the Invention] As described above in detail, the present invention has the rotation measuring unit that rotates in proportion to the flow rate, and the rotation measuring unit is equipped with the first coupling magnet via the reduction gear train. A reverse rotation preventing body that is connected to the measuring instrument via a second coupling magnet that faces the first coupling magnet and prevents the second coupling magnet from rotating in the reverse direction, and is connected to the reverse rotation preventing body, The pulse generator that generates the weighing signal for each measured quantity and the pulse in the weighing signal generated by the pulse generator when the measuring instrument is properly attached and the rotation measuring section is rotating forward, and the number of them is calculated. The meter is equipped with a meter that displays the total, and the high-frequency pulse in the weighing signal generated by the pulse generator regardless of the amount of water flow is continuously generated when the meter is installed in reverse and the rotation measuring section is rotating in the reverse direction. Since a high-frequency pulse discrimination circuit made up of a bandpass filter for identifying and receiving the fact that a predetermined number of inputs have been subsequently received and notifying that the measuring instrument is installed in reverse is provided,
It is not necessary to attach a changeover switch, and with a simple configuration,
In the normal use state, that is, even if the water flow rate changes, the reverse installation of the water meter can be detected reliably without malfunction.

[Brief description of drawings]

FIG. 1 is a perspective view showing a part of a block diagram of an embodiment of the present invention, and FIG. 2 is a perspective view showing a part of a conventional telemetry device. FIG. 3 is a waveform diagram showing a weighing signal generated when the water meter is properly attached, and FIG. 4 is a perspective view showing an operating state of the coupling magnet when the water meter is attached reversely, and FIG. [Fig. 3] is a waveform diagram showing a metering signal generated when the water meter is installed reversely. In the figure, (1) is a water meter, (3) is an impeller, and (4
(A) is a first coupling magnet, (4B) is a second coupling magnet, (6) is a pulse generator, (7) is a receiver, (7D) is a counter circuit, (7E) is an indicator, ( 7
F) is a reverse rotation detection circuit, and (7G) is a bandpass filter. In the drawings, the same reference numerals indicate the same or corresponding parts.

Claims (1)

(57) [Claims] 1. A measuring instrument having a rotation measuring section that rotates in proportion to a flow rate and equipped with a first coupling magnet through a reduction gear train, facing the first coupling magnet. A reverse rotation preventing body that is connected via a second coupling magnet to prevent the second coupling magnet from rotating in the reverse direction, and is connected to the reverse rotation preventing body to generate a weighing signal for each predetermined measurement amount. A pulse generator, and a measuring instrument that receives the pulses in the weighing signal generated by the pulse generator when the rotation measuring unit is normally rotating with the measurement device normally attached and displays the total number of the pulses. The high-frequency pulse in the metering signal generated by the pulse generator regardless of the water flow rate is continuous when the measuring device is installed in reverse and the rotation measuring unit is rotating in reverse. Telemetry apparatus characterized in that a high-frequency pulse discriminating circuit comprising a band-pass filter that informs that the instrument to identify received that it has been predetermined number of input is attached to the opposite Te.