KR0128163Y1 - Flux sensing device for approach sensor - Google Patents

Abstract

It is a flow rate sensing device using a proximity sensor to calculate the flow rate by detecting the pulse wave detected by the magnetic force sensing sensor for the rotating number of the rotating plate rotated by the magnetic force and the rotating impeller according to the flow of the fluid.

Description

Flow sensing device using proximity sensor

1 is an exploded perspective view of the flow rate detection apparatus according to the present invention.

Figure 2 is a cross-sectional view showing the assembled state of the flow rate sensor according to the present invention.

3 is a flow rate detection pulse wave, (a) is a pulse wave diagram generated by the proximity sensor in the flow rate sensor according to the present invention, (b) is a pulse wave diagram generated by a conventional induction coil.

* Explanation of symbols for main parts of the drawings

1: housing 2: impeller

3: moving magnet 4: blocking plate

5: rotating plate 6: interlocking magnet

7: detection magnet 8: cover

9: proximity sensor 10: wire

11 pulse signal 12 pipe

The present invention relates to a flow rate sensing device for detecting a flow rate of a fluid, and in particular, by attaching a sensing magnet to a rotating plate that rotates when the fluid flows, the number of revolutions of the sensing magnet can be counted by a proximity sensor to measure the flow rate The present invention relates to a flow rate sensing device.

Typically, the flow meter measures the flow rate by counting the number of revolutions of the impeller that rotates with the flow of fluid to know the flow of the fluid.

Conventional flow meter or flow sensing device is a method for counting the number of revolutions of the impeller by combining the gears to determine the flow rate by the guide scale of the mechanically configured flow meter or by using the generator principle to the impeller that rotates according to the flow of fluid. A method of using electromotive force generated by a magnet driven by rotation of an impeller is known by attaching and installing a magnet and mounting an induction coil in an adjacent portion of the magnet.

However, such a conventional flow detection device has been pointed out the following problems as a disadvantage. In the case of the mechanical type as in the former, the wear time is longer and the measured value becomes inaccurate and the structure is recovered and the manufacturing cost is increased. In the latter case, as shown in (b) of FIG. Since the device had to be provided to take additional measures such as detecting the generated pulse wave, there was a problem in that the structure and the detection process were complicated, thereby increasing the manufacturing cost.

The present invention is to provide a flow rate sensing device for improving such a conventional problem.

The present invention allows the magnet to be placed on the rotating plate rotating with the impeller according to the flow of the fluid, so that the magnetic field generated by the magnet can be detected by the proximity sensor for detecting the magnetic force, and the flow rate is calculated using the pulse wave obtained by the proximity sensor. It is an object of the present invention to provide a flow sensing device that enables to.

Another object of the present invention is to provide a flow rate sensing device that can simplify the structure and detection process to reduce the manufacturing cost and to accurately measure the flow rate.

The above and other objects of the present invention, the inner part of the housing (1) formed integrally with the pipe 12 on both sides to be sealed by the blocking plate 4 and the impeller (2) on the upper and lower sides of the blocking plate (4) And rotatably set the rotating plate (5) to the center of the upper surface of the impeller (2) and the bottom surface of the rotating plate (5) so as to face the movable magnet (3) and the interlocking magnet (6) facing the upper surface of the rotating plate (5) The sensing magnet 7 is fixed to the outer side, and the upper end of the housing 1 is achieved by a flow rate sensing device using a proximity sensor with a cover 8 fixed to the edge of the inner bottom. .

Since the present invention is as described above, when the fluid is passed through the pipe 12, the impeller 2 rotates, and when the impeller 2 rotates, the rotating plate is formed by the magnetic force between the moving magnet 3 and the interlocking magnet 6. 5) is also rotated, each time the rotating plate 5 is rotated one time, the sensing magnet (7) passes through the proximity sensor (9) and the proximity sensor (9) when the sensing magnet (7) passes through Each time the signal is turned on, the pulse signal is output to a predetermined device so that the flow rate can be calculated.

The above and other objects and features of the present invention can be more clearly understood by the following detailed description based on the accompanying drawings.

1 and 2 is an exemplary view showing a specific embodiment according to the present invention, that is, a flow rate sensing device using a proximity sensor, Figure 1 is an exploded perspective view, Figure 2 is a combined cross-sectional view.

Pipes 12 are integrally formed on both sides of the housing 1, and a pipe (not specifically shown) for conveying fluid is sealed and inserted into the pipe 12.

Inside the housing 2, an impeller 2, a blocking plate 4, and a rotating plate 5 are sequentially built in. The blocking plate 4 is fixed to the housing 1 in a sealed state so that fluid is applied to the housing 1. Do not leak when passing. On the upper side of the blocking plate 4, the impeller 2 and the rotating plate 5 are installed in a mandrel to be rotatable. In order to minimize rotational friction during rotation, the rotating shaft is formed in a sharp triangular cone shape and an impeller ( The movable magnet 3 and the interlocking magnet 6 were fixed to the upper surface of the upper surface and the bottom of the rotating plate 5 so as to face each other. In particular, the sensing magnet 1 was fixed to the upper edge of the rotating plate 5.

In addition, the cover (8) is put on the upper end of the housing (1), the proximity sensor (9) is fixed to the inner edge of the cover (8). Although not shown in detail, the proximity sensor 9 is connected to a device that receives the pulse 11 and calculates a passage amount of the fluid through the wire 10.

The operation relationship will be described below.

When the fluid passes through the housing 1 through the pipe 1 on one side, the impeller 2 is rotated by the fluid.

When the impeller 2 rotates, the starting magnet 3 rotates, and the interlocking magnet 6 rotates by the magnetic force of the starting magnet 3, so that the rotating plate 5 integrated with the interlocking magnet 6 also rotates. Done.

When the fluid rotates the impeller 2 while passing through the housing 1, the blocking plate 4 flows into the upper side of the blocking plate 4, that is, the upper side of the housing 1 in which the rotating plate 5 is rotated. Since the fluid is passed through the housing 1, the rotating plate 5 is not subjected to the interference of the fluid and also no external interference is caused by the cover 8, so that the rotating plate 5 is the impeller 2. It will rotate without error while maintaining the rotational force of.

When the rotating plate 5 rotates together with the impeller 2 as described above, the sensing magnet 7 revolves and the proximity sensor 9 passes through the lower side of the proximity sensor 9 on which the sensing magnet 7 is fixed. ) Is turned on so that a pulse is output. That is, each time the sensing magnet 7 rotates one revolution (or idle period), the proximity sensor 9 is turned on so that the pulse 11 is periodically and intermittently outputted as shown in FIG. give.

When the pulse 11 is output by the proximity sensor 9, any device (not specifically shown) receives the output pulse 11 and calculates the passage amount of the fluid.

In the above embodiment of the present invention, when the amount of passage of the fluid increases (that is, the speed of the fluid increases), the impeller 2 rotates at a high speed to shorten (short) the revolving period of the sensing magnet 7. Since the proximity sensor 9 is turned on and off more frequently, the generation period of the pulse 11 becomes shorter. On the other hand, when the fluid flow rate is slow (when the flow rate of the fluid is low), the rotation speed of the impeller is also slowed down and the revolving period of the sensing magnet 7 is also long, so that the proximity sensor 9 is turned on / off intermittently and pulsed. The occurrence period of (11) becomes long.

In addition, in the present invention, the sensing magnet 7 installed on the rotating plate 5 may be a single type, as shown in FIGS. 1 and 2, and a plurality of sensing magnets 7 are not specifically illustrated. If the sensing magnet 7 is installed alone, one pulse 11 is generated every one cycle of the sensing magnet 5, for example. When two sensing magnets 7 are attached, two pulses 11 are generated every one cycle of the sensing magnets 5.

As described above, when a plurality of the sensing magnets 5 are installed, the flow rate of the fluid can be calculated more precisely.

As described above, according to the present invention, the amount of fluid is calculated by sensing pulses generated every cycle of the sensing magnet, so that the flow rate can be more precisely calculated, and the structure can be simplified and the detection process can be simplified. Even long-term use, there is no fear of error.

Claims (1)

The inside of the housing 1 in which the pipes 12 are integrally formed on both sides is partitioned to be sealed by the blocking plate 4, and the impeller 2 and the rotating plate 5 are rotatable on the upper and lower sides of the blocking plate 4. While seated in the center of the upper surface of the impeller (2) and the bottom of the rotary plate (5), the movable magnet (3) and the interlocking magnet (6) is opposed to each other and the sensing magnet (7) on the outer side of the upper surface of the rotary plate (5) And a proximity sensor (9) at the top of the housing (1), and a cover (8) fixed at the edge of the inner bottom of the housing (1).