KR200416868Y1 - Apparatus Fluid Volume Detecting - Google Patents

Abstract

The present invention relates to a flow rate measuring device, the configuration of which includes a cam for receiving the fluid received from the inlet, and the cam housing that the cam is accommodated, the cam can discharge the fluid through the eccentric motion inside the cam housing A measuring unit main body to make it; A sensing unit main body for receiving and transmitting an eccentric motion of the cam; And a display unit which displays the movement amount of the fluid by the rotation force applied from the sensor unit, and a housing which receives the measurement unit body, the sensor unit body, and the display unit and is coupled to the outside to obtain and discharge the fluid. do.

The present invention has the effect of minimizing errors in measuring the amount of fluid movement and at the same time controlling the amount of movement.

Measuring unit main body, sensing unit main body, display unit, magnetic unit, magnetic sensing unit, flow measuring device

Description

Flow measuring device {Apparatus Fluid Volume Detecting}

1 is a perspective view showing a flow measuring device of the present invention.

FIG. 2 is an exploded perspective view showing the flow measuring device shown in FIG. 1. FIG.

Figure 3a to 3c is a schematic diagram showing the operating state of the flow measuring device of the present invention.

4 to 6 is a schematic view showing a control means according to the flow rate measuring apparatus of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: flow measurement device 12: housing

14 flange 16 mesh filter

20: measuring unit main body 30: detection unit main body

40: display unit 210: first magnetic unit

211: Cam 215: Magnet

220: cam housing 224: information board

310: magnetic load housing 330: second magnetic part

430: control means 440: magnetic detection unit

The present invention relates to a flow rate measuring device, and more particularly to a flow rate measuring device to minimize the error in the measurement of the fluid movement amount and to control the movement amount.

In general, the flow rate measuring device is to measure the amount of movement of the fluid moving along the pipe by separately provided between the pipe and the pipe to move the fluid between the interconnection, and having a plurality or one rotating body therein, The amount of fluid movement is measured and displayed by applying the rotational force of the rotating body to the measuring device.

However, such a general flow measurement device has a problem that the measurement error occurs according to the gear reduction ratio, such that the rotational force of the shaft is measured using the gear ratio.

In addition, when the flow rate measuring device is small, the flow rate is small and the reduction ratio is also formed relatively small and does not occupy much volume. However, when the flow rate is large, the flow rate is relatively large and occupies a lot of space.

And there is a problem that the axis connecting each wear due to the fast rotational force, the transmission of the rotational force is not kept constant, the error of the measured amount occurs.

The present invention has been made to solve the above problems, an object of the present invention is to provide a flow measuring device that can control the movement amount while minimizing the error in the measurement of the fluid movement amount.

The present invention has the following configuration to achieve the above object.

The flow rate measuring apparatus of the present invention includes a cam for receiving fluid received from an inlet, and a cam housing in which the cam is accommodated, and a measuring unit body for allowing the cam to discharge the fluid through an eccentric motion inside the cam housing. Wow; A sensing unit main body for receiving and transmitting an eccentric motion of the cam; And a display unit which displays the movement amount of the fluid by the rotation force applied from the sensor unit, and a housing which receives the measurement unit body, the sensor unit body, and the display unit and is coupled to the outside to obtain and discharge the fluid. do.

In the flow rate measuring apparatus of the present invention, the measuring unit body is coupled to the cam housing reference axis in various sizes so as to be rotatable and the guide shaft provided in the lower cam portion rotates along the outer peripheral surface of the guide roller And a first magnetic part that enables the eccentric motion of the cam and is positioned above the cam to apply the eccentric motion by rotational force by a magnetic force, and is provided on one side of the cam to isolate the inlet and the outlet. And a guide plate that allows the cam to rotate while forming a predetermined trajectory, wherein the sensing unit body is coupled adjacent to the measuring unit body and adjacent to the first magnetic unit of the measuring unit body. And a second magnetic part configured to apply the rotational force of the first intelligence part to the display part by a magnetic force. Preferably, the first magnetic portion and the second magnetic portion are arranged eccentrically with respect to each other.

In addition, the first magnetic portion and the second magnetic portion is positioned so that at least one or more magnets having mutually staggered polarity are mutually corresponded, and the display unit is a magnetic sensing unit for measuring the rotational force applied from the main body of the sensing unit, the magnetic Control means for displaying the flow rate using the rotational force sensed by the sex sensing unit, the wire and wireless communication with the outside; and the control means is a control module for controlling the rotational force to switch to the flow rate, and the flow rate And a button for selecting a display form of the display window and selecting communication with the outside. The display window is preferably one selected from an analog or digital display.

The housing further includes a mesh filter positioned on the inlet and outlet of the fluid.

Hereinafter, with reference to the accompanying drawings will be described a flow rate measuring apparatus of the present invention.

1 to 2, the flow measurement device 10 is accommodated in the housing 12, the measurement unit body 20, the sensing unit body 30 and coupled by the flange 14 and And a display unit 40.

The housing 12 has a mesh filter 16 which is located between the tubes (not shown) for moving the fluid and is hermetically coupled to filter the foreign matter contained in the fluid on the inlet and outlet sides of the fluid movement. Equipped.

The measuring unit body 20 includes a first magnetic part 210, a cam 211, a cam housing 220, and a cam housing cover 230.

Here, the first magnetic part 210 is provided with a plurality of magnets having a magnetic force in the upper portion of the plate (not shown), a pair of grooves 213b in the lower portion corresponding to the magnetic auxiliary shaft groove 216. The cam 211 forms a predetermined space therein, and a cam shaft 213a coupled to the groove 213b of the first magnetic part 210 protrudes from the upper center of the cam 211, and has a lower center portion. Guide shaft 214 is coupled to the guide groove 221 to be described later is formed to protrude. In addition, one side of the cam 211 is cut in the center direction to have a curved shape. The cam housing 220 has a space so that the inside can be combined with the cam 211, the circular guide groove 221 is formed in the inner center, and the reference axis 222 in the center of the guide groove 221 ) To protrude. In addition, the guide shaft 222 is rotatably coupled, and has a guide roller 223 to enable various changes in the size of the outer peripheral surface. The guide plate 224 connecting the inner wall of the cam housing 220 and the outer wall of the guide groove 221 is coupled to each other.

The cam housing cover 230 is hermetically coupled to an upper portion of the cam housing 220 in a state in which the first magnetic part 210 and the cam 211 are accommodated in the cam housing 220. One side of the cover 230 opens the inlet 233 through which the fluid can be introduced and the discharge port 234 through which the fluid can be introduced so as to communicate with the cam 211. In addition, a second magnetic part insertion groove 232 to which the coupling protrusion 311 to be described later is coupled to the upper part of the cam housing is formed at the center thereof. In addition, a magnetic shaft 215 coupled to the magnetic shaft shaft groove 216 of the first magnetic portion 210 is protruded from a lower portion of the cam housing cover 230.

The sensing unit body 30 includes a magnetic housing 310, a magnetic cover 320, and a second magnetic part 330.

The magnetic housing 310 is inserted into the upper portion of the housing 12, the coupling protrusion 311 and the coupling protrusion 311 which is seated in the second magnetic portion insertion groove 232 positioned in the measurement unit body 20. The magnetic part insertion hole 312 formed by recessing the inside is comprised. In addition, the lower coupling groove 313 is formed on the bottom of the magnetic insertion hole 312 so that the lower coupling shaft 333 of the second lower magnetic part 331 to be described later is rotatably coupled.

The second magnetic part 330 is provided with a second upper magnetic part 332 at the upper portion of the reference rotation shaft 335, and the second lower magnetic part 331 is coupled to the lower portion, and the second upper magnetic part And the second lower magnetic part 331 is provided with a plurality of magnets having a staggered polarity to receive a magnetic force applied from the first magnetic portion 210.

The magnetic cover 320 is coupled to the magnetic housing 310, the upper coupling groove 321 to be coupled to the upper coupling shaft 334 of the second upper magnetic portion 332 in the center thereof. The second magnetic part 330 is coupled to the lower coupling groove 313 and the upper coupling groove 321 so as to be rotated by applying a magnetic force of the first magnetic part.

The display unit 40 is coupled to the sensor unit body 30 by a protective cap 41, and includes a control unit housing 410, a cover 420, and a control unit 430.

The control unit housing 410 is configured to accommodate the control means 420 therein, the cover 420 is a control means in a state in which the control means 420 is accommodated in the control unit housing 410 420 provides protection.

The control means 430 includes a display window 431, a selection button 432, and an initialization button 433. The control means 430 connects with the control module 434 provided in the control means 430 to connect the second magnetic part. The magnetic sensing unit 440 for measuring the rotational force is provided.

The display window 431 allows the measured flow rate to be displayed as either analog or digital. The selection button 432 connects with the control module 434 to change the flow rate display unit of the display window 431 in various ways or to select a wired communication module or a wireless communication module when communicating with the outside. In addition, the reset button 433 initializes the measurement flow rate displayed on the display window 431 so that the flow rate measuring device can be installed again in a separate position.

The magnetic sensing unit 440 is provided adjacent to the second upper magnetic part 332 of the second magnetic part 330 so that the magnet of the second upper magnetic part 332 counts the magnetic sensing part 440. By applying the rotational force of the second upper magnetic part 332 to the control module 434 of the control means 430 to allow the control module 434 to measure the flow rate.

Below. With reference to the accompanying drawings will be described the operating state of the flow rate measuring device of the present invention.

First, referring to FIGS. 3A to 3C, the fluid introduced through the inlet side of the housing flows into the cam 211 eccentrically toward the inlet 233 side of the cam housing 220. At this time, the cam shaft 213a located above the cam 211 is positioned on the right side of the reference shaft 222 formed in the cam housing 210, and the cam 211 is the reference shaft 222 according to the fluid inflow amount. Rotate around, the cam 211 is sealed in a state that accommodates a certain amount of fluid. When the rotation is about the reference axis 222 again, the inlet 233 is sealed, the outlet 234 is opened, and the fluid is discharged to the outside of the housing. On the other hand, as shown in Figure 4, the first magnetic portion 210 provided on the upper portion of the cam receives a rotational force of the cam, the second magnetic portion 330 adjacent to the first magnetic portion 210 The rotation force is applied. In this case, the first magnetic part is coupled to the cam in an eccentric state, and the fluid moves by allowing the first magnetic part to rotate constantly along the groove formed in the cam housing of the cam and the guide groove provided in the cam housing. Can be made constant.

In addition, the second magnetic unit 330 applies a rotational force applied from the first magnetic unit to the magnetic sensing unit 440, the magnetic sensing unit 440 is a rotational force to the control means 430 shown in FIG. Is applied to allow the control means 430 to convert the rotational force into an electrical signal. As shown in FIG. 6, the control means 430 may be controlled using the control module 434, the selection button 432, the initialization button 433, the display window 431, and the transmitter / receiver 435. To make it work. For example, the rotational force applied to the control module 434 is converted into an electrical signal by a closed circuit (not shown) configured in the control module 434 and moved by counting the converted signal through the display window 431. The flow rate may be measured, and the display of the measured flow rate may be variously initialized using the control button 434 and the selection button and the reset button connected to the control module 434 so as to be initialized and reinstalled in a separate position.

In addition, the flow rate measuring device 10 and the measured data by storing the flow rate measured using the transmitter and receiver 435 in the external regulator 60 or by controlling the control module 434 using the regulator 60. Can be managed efficiently.

In addition, the first and second magnetic parts rotated by the moving fluid rotate by mutual magnetic forces, thereby minimizing wear due to rotation, thereby minimizing flow rate measurement error.

The present invention is not limited to the embodiments described above, and various modifications and changes can be made by those skilled in the art, which are included in the spirit and scope of the present invention defined in the appended claims.

The present invention has the following effects by the above configuration.

The present invention has the effect of minimizing errors in measuring the amount of fluid movement and at the same time controlling the amount of movement.

In addition, the present invention has the effect of minimizing the friction by applying the rotational force by using a magnetic force and by minimizing the error by friction by applying the rotational force.

In addition, the present invention not only can store the flow measurement amount through wired or wireless communication with the outside, but also has an effect of correcting a measurement error.

Claims (9)

A cam for receiving the fluid received from the inlet, and a cam housing accommodating the cam, wherein the cam body is configured to discharge the fluid through an eccentric motion in the cam housing; A sensing unit main body for receiving and transmitting an eccentric motion of the cam; A display unit which displays the movement amount of the fluid by the rotational force applied from the sensor unit; And a housing accommodating the measuring unit body, the sensing unit body, and the display unit and coupled to the outside to receive and discharge the fluid. The method of claim 1, The measuring unit main body is rotatably coupled to the cam housing reference axis in various sizes so that the guide roller and the guide shaft provided on the lower part of the cam rotate along the outer circumferential surface of the guide roller to enable eccentric motion of the cam. And a first magnetic part positioned at an upper portion of the cam to apply an eccentric motion by a rotational force by a magnetic force, and provided at one side of the cam to isolate the inlet and the outlet, and the cam forms a constant trajectory. And a guide plate for rotating the flow rate measuring device. The method of claim 1, The sensing unit main body is coupled to the measuring unit main body adjacent to the first magnetic portion of the measuring unit main body and the second magnetic portion for applying the rotational force of the first intelligence portion to the display unit by a magnetic force; Flow measuring device, characterized in that. The method of claim 3, wherein And the first magnetic part and the second magnetic part are arranged eccentrically with respect to each other. The method of claim 4, wherein The first magnetic part and the second magnetic part is a flow rate measuring device, characterized in that at least one or more magnets having mutually staggered polarity is positioned to correspond to each other. The method of claim 1, The display unit includes a magnetic sensing unit for measuring the rotational force applied from the main body of the sensing unit and a control means for displaying the flow rate using the rotational force detected by the magnetic sensing unit, the wire and wireless communication with the outside; Characterized in that the flow measurement device. The method of claim 6, The control means includes a control module for controlling the rotational force to be converted to a flow rate, a display window for displaying the flow rate, a button for selecting the display type of the display window and communication with the outside; Flow measuring device. The method of claim 7, wherein The display window is a flow measurement device, characterized in that made of any one selected from analog or digital display. The method of claim 1, The housing further comprises a mesh filter positioned on the inlet and outlet of the fluid.

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