JPH0647824U - Flow rate detector - Google Patents

Abstract

(57) [Summary] [Purpose] To eliminate the contact that causes chattering,
Provided is a flow rate detection device capable of preventing a failure of a detection element or a pump. [Structure] A paddle 15 installed in a horizontally extending portion of a discharge pipe 2 connected to a pump 1, rotated by being pushed by a discharge liquid, a permanent magnet 17 attached to this paddle, and a discharge pipe. When the paddle is attached and the paddle rotates, the distance from the permanent magnet changes, and the detection element 13 is a non-contact type electromagnetic conversion element that changes the electrical output according to the change in the magnetic force.
And is provided. [Function] Since the non-contact type electromagnetic conversion element whose electric output changes according to the magnetic force change due to the displacement of the permanent magnet is used, even if the paddle repeatedly swings due to the disturbance of the discharge flow, the contact is not separated. Therefore, chattering does not occur and damage to the contacts and the pump can be prevented.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a flow rate detection device used for automatic start / stop control of a pump in an automatic water supply device.

[0002]

[Prior art]

 In a device that sucks well water and automatically supplies water, when controlling the pump automatically, if the pressure on the discharge pipe side of the pump drops below a prescribed pressure due to the use of water at the end faucet, An operation control method is known in which the pump is stopped when the flow rate drops below a predetermined level by starting it and closing the end tap. In such an automatic water supply device, a pressure detection device and a flow rate detection device are installed on the discharge side of the pump.

A conventional flow rate detecting device is shown in FIG. That is, in the figure, reference numeral 30 is a discharge pipe, a horizontal portion 30b is connected to a vertical rising portion 30a of the discharge pipe 30, and a flow rate detecting device 40 is installed in the vertical rising portion 30a.

The flow rate detection device 40 has a float guide 42 extending vertically in a holder 41 screwed to the discharge pipe 30. The float guide 42 is pushed up by the flow of discharge water. The float 43 is attached so as to be vertically movable. A permanent magnet 44 is fixed to the float 43, while a magnet switch 45 is built in the float guide 42. In addition, 46 is a stopper and 47 is a cushion material.

In the flow rate detecting device 40 having such a configuration, when the float 43 is pushed up by the water pumped to the vertical rising portion 30 a of the discharge pipe 30, the float 43 rises along the float guide 42, and The permanent magnet 44 provided on the float 43 changes the magnetic field of the magnet switch 45 housed in the float guide 42, so that the magnet switch 45 is closed. This will close the pump drive circuit.

When the flow rate of the discharge pipe 30a drops below a predetermined flow rate, the float 43 descends, the permanent magnet 44 changes the magnetic field of the magnet switch 45, and thus the magnet switch 45 opens. As a result, the pump drive circuit is opened and the pump is automatically stopped.

However, such a conventional flow rate detecting device 40 has a structure in which the float 43 having the permanent magnets 44 is pushed up by the discharge flow, so that the vertical rising portion of the discharge pipe 30 is lifted. Must be installed at 30a. In the discharge pipe 30, there are few vertical rising portions 30a, so that the vertical rising portion 30a having a predetermined length must be purposely constructed, which complicates the structure and increases the height. There is a problem that it becomes high and becomes large.

For this reason, it is desired to provide the flow rate detecting device at a location extending in the horizontal direction of the discharge pipe. That is, a paddle that rotates according to the amount of water used is provided at a horizontal flow point in the discharge pipe, and a permanent magnet is attached to this paddle. If it is detected by a switch, the flow rate in the discharge pipe can be detected.

According to this, since the discharge pipe of the pump has a large number of horizontally extending portions, it can be installed anywhere, and since it is a horizontally extending portion, the height is not bulky, It can be miniaturized.

[0010]

[Problems to be solved by the device]

 However, in the discharge pipe, the paddle may vibrate violently under the influence of the turbulent flow of the pump, which is particularly remarkable when the pump is started. In this case, in the case of the magnet switch which operates by the change in magnetic force of the permanent magnet as in the above-mentioned conventional case, the contacts come into contact with and separate from each other to repeatedly turn on and off, which causes so-called chattering. As a result, not only the contacts are damaged, but also the pump is repeatedly started and stopped, which may cause the pump to malfunction.

The present invention has been made in view of the above circumstances. An object of the present invention is to provide a flow rate detecting device which can prevent a switch or a pump from being broken by eliminating a contact that causes chattering. Is what you are trying to do.

[0012]

[Means for Solving the Problems]

 In order to achieve the above-mentioned object, the present invention is installed in a discharge pipe connected to a pump, and in a flow rate detection device for detecting the flow rate of a discharge liquid flowing through this discharge pipe, installed in a portion extending in the horizontal direction of the discharge pipe. The paddle that is rotated by being pushed by the discharge liquid and the permanent magnet attached to this paddle,

The contactless electromagnetic conversion element is attached to the discharge pipe, the distance from the permanent magnet changes as the paddle rotates, and the electric output changes according to the change in magnetic force. And a detection element.

[0014]

[Action]

 According to the present invention, since the paddle that is rotated by being pushed by the discharge liquid is installed in the portion that extends in the horizontal direction of the discharge pipe, the height of the installation space can be small, and the position can be selected anywhere in the discharge pipe. It can be installed in a small size and its structure is simple. In addition, since the contactless electromagnetic conversion element whose electrical output changes according to the change in magnetic force due to the displacement of the permanent magnet was used as the detection element, even if the paddle repeatedly swings due to turbulence in the discharge flow, the contact of the contact There is no separation, and therefore chattering does not occur, and damage to the contacts and pump can be prevented. Further, even if a discharge flow is suddenly applied to the paddle, the paddle rotates in a direction away from the detection element, so that the detection element is not damaged.

[0015]

【Example】

 The present invention will be described below based on an embodiment shown in FIGS. FIG. 2 shows a pump device used in an automatic water supply device, 1 is a pump, 2 is a discharge pipe, 3 is a flow rate detecting device of the present invention, 4 is a check valve, and 5 is a pressure detecting device.

In this pump device, when the pressure in the discharge pipe 2 drops below a predetermined pressure by opening an end faucet (not shown), the pressure detection device 5 detects this and the pump 1 When the flow rate in the discharge pipe 2 drops below a predetermined flow rate by activating the valve, closing the end faucet, etc., the flow rate detection device 3 detects this and stops the pump 1. . The flow rate detecting device 3 will be described with reference to FIG.

A mounting pipe 6 is fixed to the discharge pipe 2 at a location extending in the horizontal direction by means such as welding, and a flange 7 is welded to the upper end of the mounting pipe 6. A flow rate detection unit body 10 is fitted to the mounting pipe 6, and the flow rate detection unit body 10 is kept liquid tight with respect to the flange 7 by an O-ring 11 and is fixed by a bolt or the like not shown. .

The flow rate detection unit body 10 is made of a non-magnetic material such as synthetic resin, and has a detection element 13 in a liquid-tightly-accommodated storage chamber 12. The detection element 13 is formed of a non-contact electromagnetic conversion element, such as a hall element or a magnetoresistive element, which has the property of changing its electrical characteristics in response to a change in the surrounding magnetic field.

A paddle 15 is attached to the flow rate detection unit body 10 so as to face the storage chamber 12 but be located on the downstream side. The paddle 15 is also made of a non-magnetic material such as synthetic resin, and its upper end is rotatably connected to the flow rate detection unit body 10 by a horizontal pin 16. Therefore, the paddle 15 has a horizontal pin 16 It hangs freely. When discharged water hits the paddle 15, the paddle 15 is pushed and rotationally displaced.

A permanent magnet 17 is embedded in the paddle 15. The permanent magnet 17 faces the detection element 13, and the magnetic force around the detection element 13 is changed by changing the distance between the permanent magnet 17 and the detection element 13. An opening 18 is formed in the paddle 15 such that the permanent magnet 17 is located on the surface facing the detection element 13. Reference numeral 19 in the drawing denotes a display element, which is turned on when a large current is flowing through the detection element 13, that is, when the pump is stopped. Reference numeral 20 is a cover made of a transparent resin or the like for covering the display element 19. The operation of the flow rate detection device 3 having such a configuration will be described.

When the water discharged from the pump 1 flows through the discharge pipe 2, the paddle 15 is pushed by this discharged water, so that the paddle 15 rotates so that the lower end faces the downstream side. Therefore, the permanent magnet 17 held by the paddle 15 separates from the detection element 13. Therefore, the magnetic force around the detecting element 13 becomes weak (the magnetic force is inversely proportional to the square of the distance from the magnet), and the detecting element 13 changes its electrical characteristics. As a result, the detection element 13 turns on the drive circuit of the pump 1, so that the pump 1 maintains the operating state.

That is, when the flow rate in the discharge pipe 2 becomes equal to or higher than a predetermined flow rate, the paddle 15 rotates to the downstream side, so that the pump 1 is driven. At this time, the display element 19 disappears.

Further, when the amount of water used in the end faucet is reduced and the flow rate in the discharge pipe 2 is reduced, the paddle 15 is not pushed by the discharge water, and the paddle 15 is rotated in a vertical posture due to gravity. Return. Therefore, the permanent magnet 17 held by the paddle 15 approaches the detection element 13, the magnetic force around the detection element 13 becomes strong, and the electrical characteristics of the detection element 13 change. As a result, the detection element 13 turns off the drive circuit of the pump 1 and thus stops the operation of the pump 1.

That is, when the flow rate in the discharge pipe 2 becomes equal to or lower than a predetermined flow rate, the paddle 15 returns to rotate, so that the pump 1 is stopped. At this time, the display element 19 is turned on.

In the flow rate detecting device 3 having the above-mentioned configuration, since it is attached to the portion of the discharge pipe 2 that extends in the horizontal direction, there is no need for a vertical space, and the pump pipe is installed in the horizontal direction. Since there are many places to install, there are no restrictions on installation.

Further, since the paddle 15 is provided with a permanent magnet 17 and the displacement of the permanent magnet 17 allows the detection element 13 to change the electrical output, it becomes a non-contact type switch, which is equivalent to a conventional contact type switch. As a result, damage due to the mechanical contact and separation of the contacts is prevented, and the life of the switch is extended.

When the paddle 15 is returned, the detection element 13 causes a relatively large current to flow to activate the control unit of the pump, thereby stopping the pump. That is, when a large current is flowing through the detection element 13, the pump is stopped and the display element 19 is turned on. However, if the detection element 13 is disconnected from the pump control unit installed outside, no current will flow through the detection element 13, so the control unit of the pump operates to operate the pump, and the display element 19 is turned off. That is, when the connection is disconnected, the water supply amount is equal to or more than the predetermined flow rate, that is, the paddle 15 is rotated, and the display element 19 is turned off. If the pump is stopped regardless, a contradiction occurs. Therefore, it can be determined that there is a failure, which enables failure detection.

Even when the paddle 15 is suddenly subjected to a pressing force such as when the pump is started and the paddle 15 vibrates greatly and violently, the tip end of the paddle 15 is detected by the detection element 13. Since the direction of separation is larger, there is no risk of collision with the detection element 13, no impact is given to the detection element 13, and failure of the detection element 13 and disconnection of lead wires can be prevented. Further, when the flow rate decreases, the paddle 15 is pivotally returned due to gravity, but since the paddle 15 has the permanent magnet 17, the paddle 15 receives a large gravity and quickly returns.

The detection element 13 is formed of a magnetoelectric conversion element, and its electrical output changes in response to a change in magnetic force. Therefore, the electrical output changes in proportion to the amount of water supplied. Therefore, it is possible to input such a linearly changing output characteristic to the control unit and use it as a signal for water supply control such as stop flow rate, parallel start flow rate of multiple pumps, and parallel flow rate. It is also possible to adjust or automatically set the flow rate value required for the water supply control by the control unit. The present invention is not limited to the above embodiment.

That is, if a magnetic body (not shown) is attached to the flow rate detection unit body 10 so that the magnet 17 provided on the paddle 15 is attracted, it becomes a resistance when the magnet 17 separates, and reversely returns. If it does, it will prompt a recovery, thus creating a hysteresis characteristic. Therefore, the operation of the detection element 13 can be stabilized.

Further, the parallel pin 16 at the upper end of the paddle is provided at a position displaced slightly to the left from the state shown in the figure, and when the paddle 15 is about to be in a vertical state when stopped, the entire body is brought into contact with the flow rate detection unit body 10. Tilt to stabilize the stop condition.

[0032]

[Effect of device]

 As described above, according to the present invention, since the paddle that is rotated by being pushed by the discharge liquid is installed in the portion that extends in the horizontal direction of the discharge pipe, the height of the installation space is small, and the discharge pipe can be located anywhere. It can be selected and installed, and it is small and has a simple structure. In addition, since the contactless electromagnetic conversion element whose electrical output changes according to the change in magnetic force due to the displacement of the permanent magnet was used as the detection element, even if the paddle repeatedly swings due to the disturbance of the discharge flow, the contact of the contact There is no separation, and therefore chattering does not occur, and damage to the contacts and pump can be prevented. Further, even if a discharge flow is suddenly applied to the paddle, the paddle rotates in a direction away from the detecting element, so that the detecting element is not damaged.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of a flow rate detector showing an embodiment of the present invention.

FIG. 2 is a front view of a pump device in an automatic water supply device provided with the flow rate detection device.

FIG. 3 is a sectional view showing a conventional flow rate detecting device.

[Explanation of symbols]

1 ... Pump 2 ... Discharge pipe 3
... Flow rate detection device 4 ... Check valve 5 ... Pressure detection device 10 ... Flow rate detection unit body 13 ... Detection element (magnetoelectric conversion element) 15 ... Paddle 16 ... Parallel pin 17 ... Permanent magnet

Claims (1)

[Scope of utility model registration request] 1. A discharge pipe connected to a pump,
In a flow rate detecting device for detecting a flow rate of a discharge liquid flowing through the discharge pipe, a paddle which is installed in a portion of the discharge pipe extending in a horizontal direction and which is rotated by being pushed by the discharge liquid, and a permanent member attached to the paddle. A non-contact electromagnetic conversion element attached to the magnet and attached to the discharge pipe, the distance between the magnet and the permanent magnet changes as the paddle rotates, and the electric output changes according to the change in magnetic force. A flow rate detection device comprising: a detection element.