KR20100003533U - Flow sensor - Google Patents

Abstract

The object of the present invention is to provide a fluid flow detection device that properly senses the flow of fluid and has a high durability, and the fluid flow detection device of the present invention has a communication hole for communicating with the fluid transport pipe and is attachable to the fluid transport pipe. Base plate 20; A metal bellows tube 31 having both ends open and empty; A bellows support plate (32) extending from a lower end of the bellows pipe to fix the bellows pipe to the base plate; A shaft (33) inserted into the bellows tube in a longitudinal direction, the upper end portion of which is closed and the upper end of the bellows tube being hermetically coupled; A seesaw plate 38 coupled to the top of the shaft and having a seesaw axis 39; And a seesaw frame 40 fixed to an upper portion of the base plate 20 and having a seesaw shaft receiving portion 49 for receiving the seesaw shaft 39.

Fluid flow detection device, bellows pipe, shaft, paddle, seesaw plate, fluid transfer pipe, control spring, switch, timer device. Initial malfunction prevention switch

Description

Fluid Flow Sensor {FLOW SENSOR}

The present invention relates to a fluid flow sensing device for use in a mechanical cooling system and a fluid transfer line in a modernized and high-tech industrial field, and more precisely detects a fluid flow and a more advanced fluid detecting device with more advanced durability.

In general, if the system system cooling water system or fluid line is not smoothly flowed from the fluid transfer pipe, expensive equipment cannot be used, and in the case of reduced productivity and fire extinguishing equipment, if the flow of the extinguishing water is not detected, it is difficult to extinguish the fire. It can be seen that the water flow detection device is important because it can occur.

An example of such a fluid flow sensing device is shown in FIG. 1. Figure 1 schematically shows a side cross-sectional view of a conventional fluid flow detection device.

In FIG. 1, the fluid flow detection device 100 is installed in the fluid transfer pipe 200 having the through hole 210. The fluid flow detection device 100 is composed of a base plate 110 directly contacting the through hole 210 and a cover 120 covering the base plate 110. The shaft 130 is installed at the portion of the base plate 110 contacting the through hole 210 by the sealing member 140, and the paddle 150 is attached to the lower end of the shaft 130.

With this configuration, the shaft 130 is moved back and forth in accordance with the hydraulic pressure of the fluid, this back and forth movement can operate the switch 160 by a known means to detect the occurrence of the fluid flow.

However, in the fluid flow sensing apparatus as described above, the shaft is generally supported and sealed using elastic rubber as a sealing member. When elastic rubber is used, there is a problem that the rubber hardens over time and the life is limited. Even at the same flow rate, the degree of inclination of the shaft varies according to the hardening of the rubber, and there is a problem in that the actual flow rate cannot be accurately detected by deformation due to pressure.

In addition, in the configuration of FIG. 1, the shaft may not only move back and forth (left and right in the drawing) but also left and right movement (in the drawing, in the direction perpendicular to the drawing) due to the fluid pressure. There was a problem that it is difficult to detect the exact flow rate of.

Moreover, the conventional sealing member has a constant restoring force. If the fluid is so slow that the force to move the shaft falls short of this restoring force, the fluid flow sensing device cannot detect the fluid. Therefore, in this case, the restoring force of the sealing member should be set low so that the shaft can move even at a weak hydraulic pressure. On the contrary, the restoring force of the sealing member must be set high according to the fluid transfer pipe which has a very fast fluid. The problem is that it is not easy to set up and change.

The present invention has been made to solve the above problems, an object of the present invention is to provide a fluid flow detection device that is appropriately detect the pressure of the fluid and excellent durability.

To achieve the above object, the shaft and sealing member according to the present invention are made of a bellows pipe assembly, and the bellows pipe assembly includes: a metal bellows pipe having open ends at both ends thereof; A bellows support plate extending from the bottom of the bellows pipe to secure the bellows pipe to the fluid flow sensor; And a shaft inserted in the bellows tube in the longitudinal direction of the bellows tube, wherein the upper end of the shaft and the upper end of the bellows tube are hermetically coupled to each other.

In addition, the fluid flow sensor according to the present invention, the base plate having a communication hole for communicating with the fluid transfer pipe and attachable to the fluid transfer pipe; A metal bellows tube with both ends open and empty; A bellows support plate extending from a lower end of the bellows pipe to fix the bellows pipe to the base plate; A shaft inserted into the bellows tube in a longitudinal direction, the upper end of which is closed and the upper end of the bellows tube being hermetically coupled; A seesaw plate coupled to the top of the shaft and having a seesaw axis; And a seesaw shaft frame fixed to the base plate and having a seesaw shaft receiving part for receiving the seesaw shaft.

In addition, the fluid flow sensor according to the present invention, the base plate having a communication hole for communicating with the fluid transfer pipe and attachable to the fluid transfer pipe; A shaft that is rotatably coupled to the communication hole of the base plate and provided to be vertically long; An elastic sealing member coupled to the communication hole and elastically supporting the shaft; A seesaw plate coupled to and fixed to an upper end of the shaft; And a seesaw shaft frame fixed to the base plate, wherein an adjustment spring is installed below the seesaw frame, one end of the adjustment spring is fixed to the seesaw frame and the other end is in contact with the seesaw plate. do.

By the bellows pipe assembly according to the present invention, it is possible to solve the problem caused by the hardening of the conventional sealing member over time, to provide a durable fluid flow detection device that can accurately detect the flow rate in the fluid transfer pipe It can be provided.

In addition, according to the fluid flow detection device according to the present invention can be installed by setting the restoring force of the shaft according to the flow rate in the fluid transfer pipe to be installed, and also after the installation of the fluid flow detection device can be set by adjusting the restoring force again, The fluid can be properly detected regardless of whether the fluid pressure is high or low.

Hereinafter, an embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

2 is an exploded perspective view of a fluid flow detection apparatus according to an embodiment of the present invention. Referring to FIG. 2, the fluid flow detecting apparatus 100 includes a base plate 20 and a cover 10 covering the base plate 20, and through holes (not shown) of the fluid transfer pipe through connection means 21 such as a socket. Connected with The seesaw frame 40 is attached and fixed to the upper portion of the base plate 20. The seesaw frame 40 is attached by conventional coupling means, such as means such as rivets, bolts, nuts.

The sensing switch 50 is installed on the top of the seesaw plate 40. In one embodiment, the detection switch 50 has a function of turning on and off the power of the fluid flow detection device 100 and a function of detecting the movement of the shaft 33 by the fluid to indicate that the fluid is generated.

In addition, in one embodiment according to the present invention, by providing a timer function to prevent the malfunction due to the shock wave of the fluid flow to the sensing switch, it is possible to delay the cycle width of the shock wave by using a timer, as well as manual power supply for initial commissioning It can be equipped with a function to remove the malfunction of the system by attaching a disconnect switch and to turn on the power to operate normally in normal operation.

The sensing switch 50 may be a type in which individual units each responsible for the above functions are combined, or one unit may be configured to perform all of the above functions.

The lower portion of the base plate 20 is attached to the bellows pipe assembly consisting of a bellows pipe 31, a bellows support plate 32, and a shaft 33. Specifically, as shown in FIG. 2, the bellows support plate 32 is attached to the lower portion of the base plate 20 by conventional coupling means such as rivets, bolts, and nuts.

As also shown in Figs. 3 and 4, the bellows pipe 31 is open at both ends and is empty inside. In a preferred embodiment the bellows tube is made of metal. Therefore, since the bellows tube according to the present invention uses a metallic bellows, the bellows tube according to the present invention can exert performance under any adverse conditions of the fluid.

The lower end of the bellows pipe 31 is connected to the bellows support plate 32. The bellows assembly is attached to the base plate 20 by the bellows support plate 32. Preferably, the bellows support plate 32 is made of metal, and the bellows pipe 31 and the bellows support plate 32 may be manufactured and combined, respectively, or may be integrally manufactured.

The shaft 33 is inserted in the bellows pipe 31 in the longitudinal direction of the bellows pipe 31. The length of the shaft further extends below the lower end of the bellows tube 31 to the through hole of the fluid transfer tube, and the length of the shaft is not particularly limited in the preferred embodiment of the present invention. The diameter of the shaft 33 is manufactured so that it may be smaller than the inner diameter of the bellows pipe | tube 31 so that there exists the clearance space which the shaft 33 can rotate back and forth by a fluid.

The upper end of the shaft 33 is hermetically coupled to the upper end of the bellows pipe 31 to prevent the fluid in the fluid transfer pipe from leaking into the fluid flow detection device 100. The shaft 33 may be made of a conventional material such as plastic or metal. In addition, the bellows tube 31 and the shaft 33 may be separately manufactured and combined, or the metal bellows tube and the metal shaft may be integrally manufactured.

The paddle 34 may be attached to the lower end of the shaft 33. As shown in FIG. 1, since the paddle 34 extends to the inside of the fluid transport pipe, the shaft 33 rotates in accordance with the fluid flow in the fluid transport pipe.

The seesaw plate 38 is attached to the upper end of the shaft 33. As shown in FIGS. 2 and 3A and the like, the seesaw plate 38 is coupled to the shaft 33 via conventional coupling means such as bolts or the like. In other embodiments, the seesaw plate 38 may be coupled to the upper end of the bellows tube 31. By such a configuration, the shaft 33 and the seesaw plate 38 are integrally formed to rotate.

The seesaw shaft 39 protrudes from the left and right sides of the seesaw plate 38. By inserting the seesaw shaft 39 at the corresponding portion of the seesaw frame 40 into the support opening, the seesaw shaft 39 is rotated by the fluid when the shaft 33 rotates. It will act as the axis of movement.

As shown in Figs. 2 and 4, openings are formed on one side of the seesaw plate 38, preferably in a direction inclined forward when the shaft 33 moves forward and backward (hereinafter referred to as 'front surface'). Have This opening is for penetrating the adjustment bolt 45 provided in the front surface of the seesaw frame 40. In one embodiment, the adjustment bolt 45 is installed below the front surface of the seesaw frame 40. The adjustment spring 43 is fitted to the adjustment bolt 45. One end of the adjustment spring 43 is fixed to the seesaw frame 40 and the other end is positioned in contact with the seesaw plate 38, in one embodiment shown in FIGS. 2 and 4 of the adjustment spring 43. One end is fixed to the adjustment bolt 45 extending from the seesaw plate 40 and the other end is in contact with the periphery of the opening of the seesaw frame 38.

The fluid flow sensing device having the configuration as described above operates as described below.

3A and 3B are side cross-sectional views schematically illustrating a state in which the fluid flow sensor of FIG. 2 is installed in a fluid transfer pipe. If no fluid is flowing in the fluid transfer pipe 200 or if the hydraulic pressure applied to the shaft 33 is less than the elastic restoring force of the adjustment spring 43, the shaft 33 does not move as shown in FIG. 3A.

If the fluid in the fluid transfer pipe 200 is greater than the restoring force of the adjustment spring 43 as shown in FIG. 3B, the shaft 33 is inclined in the fluid direction (right direction in the drawing) and is above the seesaw axis 39. The seesaw plate 38 attached to the top of the shaft 33 and the upper end of the shaft 33 located at is inclined in the left direction in the figure. Accordingly, the switch contact means 35 attached to the seesaw plate 38 is moved, and this movement is transmitted to the switch 50 in an electrical or mechanical manner so that the switch 50 is activated to detect the generation of fluid. The configuration of the switch contact means 35 and the electrical or mechanical connection method between the switch contact means and the switch 50 can be the same as the existing fluid flow sensing device.

4A, 4B, and 4C are partially enlarged views of the fluid flow detection device when the compression amount of the adjustment spring is set differently. In one embodiment, the adjustment spring 43 is fixed to the seesaw frame 40 by means of an adjustment bolt 45 and an adjustment nut 46. The lower end of the adjustment spring 43 is fixed by the adjustment bolt 45 and the upper end is in contact with the periphery of the opening of the seesaw plate 38 attached to the bellows assembly.

As shown in FIG. 4A, when the distance between the adjustment bolt 45 and the nut 46 is narrower than a predetermined interval (for example, the interval as shown in FIG. 4B), the adjustment spring 43 is compressed. As described above, when the spring is compressed in a large amount, the pressing plate 38 requires a lot of pressing pressure to press the spring 43. Therefore, if the fluid flow detector is installed in the fluid transfer pipe by setting the adjustment spring 43 in this state, the shaft 33 rotates only when a high pressure fluid flows, and thus the spring shown in FIG. 4A. The setting is usually a suitable setting when a fluid flow sensing device is installed in a fluid conveying tube having a large hydraulic pressure of the fluid.

Similarly, in the embodiment shown in FIG. 4B, the spacing between the adjustment bolt 45 and the nut 46 is set wider than the preset spacing. In this state, since the spring 43 is compressed only a small amount, the shaft 33 can move even if the seesaw plate 38 presses the spring 43 little or very little. Therefore, if the fluid flow detector is installed in the fluid transfer pipe by setting the adjustment spring 43 in this state, the shaft 33 rotates even when very low pressure fluid flows. Appropriate setting is provided when a fluid flow detector is installed in a low hydraulic fluid transfer pipe.

As such, when the fluid flow detection device according to the present invention is installed in the fluid transfer pipe, the restoring force of the spring can be preset and installed in a convenient way according to the fluid pressure of the fluid transfer pipe, so that the fluid of the fluid transfer pipe to install the fluid flow detection device is installed. Regardless of the high and low water pressure, the fluid can be properly sensed, and even after installation, the cover 10 can be removed and the restoring force can be easily and easily readjusted by adjusting only the adjustment bolt 45 and the nut 46. There is this.

In the above description of specific preferred embodiments of the present invention, the present invention is not limited to the above-described embodiment, the technical field to which the present invention belongs without departing from the spirit of the present invention claimed in the utility model registration claims. Anyone of ordinary skill in the art that various modifications can be made, of course, such modifications fall within the scope of the claims.

1 is a schematic side cross-sectional view of a conventional fluid flow detection device.

Figure 2 is an exploded perspective view of the fluid flow detection device according to an embodiment of the present invention.

3A and 3B are side cross-sectional views schematically illustrating a state in which the fluid flow detection device of FIG. 2 is installed in a fluid transfer pipe;

4A, 4B, and 4C are partially enlarged views of the fluid flow detection device when the compression amount of the adjustment spring is set differently.

Claims (6)

In a bellows pipe assembly used for a fluid flow sensing device, A bellows tube 31 having both ends opened and the inside empty; A bellows support plate (32) extending from the lower end of the bellows pipe to secure the bellows pipe to the fluid flow sensor; And And a shaft 33 inserted into the bellows tube in the longitudinal direction of the bellows tube. The bellows pipe is made of a metal, the bellows pipe assembly, characterized in that the upper end of the shaft and the upper end of the bellows tube is hermetically coupled. The bellows pipe assembly according to claim 1, wherein the bellows pipe (31) and the bellows pipe support plate (32) are integrally molded. In the fluid flow detection device, A base plate 20 having a communication hole for communicating with the fluid transfer pipe and attachable to the fluid transport pipe; A metal bellows tube 31 having both ends open and empty; A bellows support plate (32) extending from the lower end of the bellows pipe to fix the bellows pipe to the base plate (20); A shaft (33) inserted into the bellows tube in a longitudinal direction, the upper end portion of which is closed and the upper end of the bellows tube being hermetically coupled; A seesaw plate 38 coupled to the top of the shaft and having a seesaw axis 39; And And a seesaw frame (40) having a seesaw shaft receiving portion (49) fixed to the base plate (20) and accommodating the seesaw shaft (39). In the fluid flow detection device, A base plate 20 having a communication hole for communicating with the fluid transfer pipe and attachable to the fluid transport pipe; A shaft that is rotatably coupled to the communication hole of the base plate and provided to be vertically long; An elastic sealing member coupled to the communication hole and elastically supporting the shaft; Seesaw plate 38 is fixed to the upper end of the shaft; Includes; seesaw frame 40 is fixed to the base plate 20, An adjustment spring 43 is installed below the seesaw frame 40, one end of the adjustment spring 43 is fixed to the seesaw frame 40, and the other end is in contact with the seesaw plate 38. Fluid flow detection device. The method of claim 4, wherein the shaft, A metal bellows tube 31 having both ends open and empty; A bellows support plate (32) extending from a lower end of the bellows pipe to fix the bellows pipe to the base plate; And And a shaft (33) inserted into the bellows tube in a longitudinal direction and having an upper end thereof and an upper end of the bellows tube sealingly coupled thereto. 6. Fluid flow sensing device according to claim 4 or 5, characterized in that the adjustment spring is fixed to the seesaw frame (40) by means of an adjustment bolt (45) passing through the adjustment spring (43).

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