JP2020106286A - Flow switch and electric pump provided with the same - Google Patents

Abstract

To provide a flow switch in which a surface area of a water receiving part of a paddle is enlarged relative a water flow to enable the flow switch to start at a small flow rate, and to provide an electric pump provided with the same.SOLUTION: A flow switch 6 comprises: a base 12 having a reed switch 17; a paddle casing 13 fixed to the base 12; a paddle 14 coupled to the paddle casing 13; and switch startup means 18 which starts the reed switch 17. The paddle casing 13 includes a paddle passage 26 in which liquid flows. The paddle 14 includes a water receiving part 19, a paddle rotating shaft 20, and a holding part 21, and is coupled to the paddle casing 13 through the paddle rotating shaft 20. The switch startup means 18 is held by the holding part 21. The water receiving part 19 is disposed on the paddle passage 26, and has a bowl shape denting toward downstream of liquid flowing in the paddle passage 26. An electric pump 1 is provided with the flow switch 6.SELECTED DRAWING: Figure 3

Description

The present invention relates to a flow switch or an electric pump with a flow switch.

2. Description of the Related Art Conventionally, this type of auto pump with a flow switch is known in which a flow switch is provided behind a discharge port (for example, see Patent Document 1).

The pump will be described below with reference to FIG.

As shown in FIG. 11, the pump 101 includes an electric motor 102, a pump casing 103, and a flow rate switch 104.

A flow rate switch 104 is provided on the discharge port 105 side of the pump, and a paddle 106 of the flow rate switch 104 is arranged in a tubular flow path and is rotated by water flowing inside the pipe. At this time, the magnet 107 provided on the paddle 106 approaches the reed switch 108 provided outside the flow path to operate, whereby the pump 101 is activated.

JP, 2009-36149, A

In such a conventional pump with a flow switch, since a flat paddle is used, the opening angle of the paddle is small in the case of a small water flow. Therefore, there is a problem that it is difficult to start the pump at a small flow rate.

Then, this invention solves the said conventional subject, and changes the shape of a paddle and aims at providing the flow switch or electric pump which can perform a sensitive reaction with respect to a water flow.

In order to achieve this object, a flow switch according to one aspect of the present invention includes a base having a reed switch, a paddle casing fixed to the base, a paddle connected to the paddle casing, and the reed. A flow switch having a switch starting means for starting a switch, wherein the paddle casing has a paddle flow path through which a liquid flows, and the paddle includes a water receiver, a paddle rotating shaft, and a holder. It is connected to the paddle casing via a paddle rotation shaft, the switch starting means is held by the holding portion, the water receiving portion is arranged on the paddle flow passage, and is located on the downstream side of the liquid flowing through the paddle flow passage. It is characterized by having a bowl shape that is recessed toward the side, and thereby achieves the intended purpose.

According to the present invention, by increasing the surface area of the water receiving portion of the paddle with respect to the water flow, it is possible to efficiently convert the force received by the water receiving portion from the water into the force for opening the paddle, so that the reaction is sensitive even at a small flow rate. It is possible to provide a flow switch or an electric pump that can be activated by the above.

The schematic diagram of the side half section showing the electric pump of Embodiment 1 of the present invention. Perspective view of the electric pump Schematic of side cross section of the same flow switch mounting part Perspective view of the paddle Perspective view of the paddle casing Schematic of side cross section when water flow is generated at the same flow switch mounting part (A) Schematic diagram of the side cross section of the paddle (b) Schematic diagram of the side cross section of the flat paddle Exploded perspective view of the same flow switch The schematic of the side section which shows the inclination angle of the bowl paddle of Embodiment 2 of this invention. 3 is a schematic side sectional view showing a structure according to a third embodiment of the present invention. Schematic diagram showing a conventional pump

A flow switch according to one aspect of the present invention includes a base having a reed switch, a paddle casing fixed to the base, a paddle connected to the paddle casing, and a switch starting means for activating the reed switch. The paddle casing has a paddle flow path through which the liquid flows, and the paddle includes a water receiving portion, a paddle rotation shaft and a holding portion, is connected to the paddle casing via the paddle rotation shaft, and the switch activation means is The water receiver is held by the holder and is arranged on the paddle flow path and has a bowl shape which is recessed toward the downstream side of the liquid flowing through the paddle flow path.

According to this configuration, the surface area of the water receiving portion of the paddle with respect to the water flow can be increased as compared with the flat paddle, so that the force received from water can be efficiently converted into the force for opening the paddle. .. As a result, even if the flow rate is small, the flow rate switch reacts sensitively and is activated, so that it is possible to provide a good quality flow rate switch or electric pump.

Further, the water receiving portion has a first inclined portion and a second inclined portion, the first inclined portion is located closer to the tip end side than the second inclined portion, and flows through the paddle flow path in a state in which the paddle is closed. If the angle of inclination of the first inclined portion toward the downstream side of the liquid is θ1 and the angle of inclination of the second inclined portion toward the downstream side of the liquid flowing through the paddle channel is θ2, then θ1>θ2. It may be configured.

According to this configuration, the surface area of the tip end side of the water receiving portion through which a large amount of water flows can be increased, so that the water receiving portion efficiently receives the force from the water. Therefore, the force received from water can be collected on the tip side of the water receiving portion and efficiently converted into the force for opening the paddle, and the flow rate switch can be sensitively activated even at a smaller flow rate.

Further, the water receiving portion may have a water receiving edge portion on the bottom surface, and the water receiving edge portion may overlap the flow passage edge portion that is the periphery of the paddle flow passage when the paddle is closed.

According to this configuration, almost all the water flow hits the water receiving portion from the paddle flow path in the closed state of the paddle, so that the force of the water flow is applied to almost the entire water receiving portion. Therefore, the force received by the water receiving portion from the water can be more efficiently converted into the force for opening the paddle.

In addition, the inner surface of the water receiving edge portion and the inner surface of the flow path edge portion may be configured to coincide with each other on the tip side of the water receiving portion.

According to this configuration, since water can be smoothly guided from the paddle flow path to the water receiving portion, it is possible to more efficiently convert the force received by the water receiving portion from the water into the force for opening the paddle.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
1 and 2 show an electric pump according to a first embodiment of the present invention.

As shown in FIGS. 1 and 2, the electric pump 1 includes a motor 2 and a pump casing 3.

The pump casing 3 has a suction port 4 and a discharge port 5. The flow rate switch 6 is attached to the discharge port 5 side of the pump casing 3.

The motor 2 includes a rotating shaft 11. The impeller 7 is fixed to a protruding portion at one end of the rotating shaft 11. The impeller 7 is arranged so as to be included in the pump casing 3.

A cooling fan 10 is provided at a protruding portion at the other end of the rotating shaft 11 on the side opposite to the one end of the rotating shaft 11 to which the impeller 7 is fixed. The fan cover 9 is fixed to the motor 2 and covers the cooling fan 10.

A terminal cover 8 is provided on the top of the motor 2. The terminal cover 8 is fixed to the motor 2.

The power of the motor 2 is transmitted to the impeller 7 via the rotating shaft 11, and the impeller 7 rotates. The water (liquid) sucked from the suction port 4 is discharged from the discharge port 5 by the rotation of the impeller 7.

As shown in FIG. 3, the flow rate switch 6 is composed of a base 12, a paddle casing 13, a paddle 14, and a cover 15.

The base 12 is provided with a substrate 16.

The board 16 is provided with a reed switch 17, and has a circuit for turning on/off the electric pump 1 based on a signal from the reed switch 17. The cover 15 is fixed to the base 12.

The paddle casing 13 is fixed to the base 12.

As shown in FIG. 4, the paddle 14 includes a water receiving portion 19, a paddle rotating shaft 20, and a holding portion 21. The switch activation means 18 is, for example, a magnet and is fixed to the holding portion 21.

The paddle 14 includes a spring 30.

A water receiving edge portion 22 is provided on the bottom surface of the water receiving portion 19.

The paddle 14 is connected to the paddle casing 13 via the paddle rotation shaft 20.

As shown in FIG. 5, the paddle casing 13 has a paddle passage 26 through which the liquid flows. A flow path edge portion 27 is provided around the paddle flow path 26. The paddle casing 13 may be provided with an insertion opening 28 into which the paddle rotation shaft 20 is inserted.

In the state where the paddle 14 is connected to the paddle casing 13, the water receiving portion 19 of the paddle 14 is arranged on the paddle flow path 26 of the paddle casing 13. The water receiving portion 19 has a bowl shape which is recessed toward the downstream side of the liquid flowing through the paddle flow path 26.

Even when the electric pump 1 is not activated, the water flow 23 shown in FIG. 6 may be generated by relaxing the water pressure of the water pipe connected to the paddle flow path 26 by opening the tap of the water supply, for example. it can.

As shown in FIG. 6, when the water receiving portion 19 receives the force of the water flow 23, the paddle 14 rotates in the opening direction about the paddle rotation shaft 20. Then, the reed switch 17 is activated by the switch activation means 18 provided in the paddle 14 approaching the reed switch 17. The activation signal of the reed switch 17 is transmitted to the motor 2 via the board 16 and the motor 2 is activated. When the motor 2 is started, the power of the motor 2 is transmitted to the impeller 7 via the rotating shaft 11, and the impeller 7 rotates. The electric pump 1 is activated by such steps, and the water flow 23 can be increased.

A force is constantly applied to the paddle 14 by a spring 30 in a closing direction. Therefore, by closing the faucet of the water supply, the water flow 23 is reduced, and the paddle 14 rotates in the closing direction about the paddle rotation shaft 20. Then, the switch activation means 18 provided in the paddle 14 moves away from the reed switch 17, the reed switch 17 stops, and the electric pump 1 stops.

FIG. 7A shows a paddle 14 in which the water receiving portion 19 according to the present embodiment is bowl-shaped, and FIG. 7B shows a flat paddle 24 in which the water receiving portion 29 is flat.

Compared with FIG. 7B, the surface area of the water receiving portion 19 for the water flow 23 can be increased in the embodiment of FIG. 7A. Therefore, the force received from the water stream 23 can be efficiently converted into the force for opening the paddle 14.

Therefore, when the electric pump 1 is stopped, even if the flow rate in the paddle flow path 26 is small, the flow rate switch 6 can react sensitively and can be activated. 1 can be provided.

Note that FIG. 8 shows an exploded perspective view of the flow rate switch 6 of the present embodiment.

(Embodiment 2)
In FIG. 9, the same components as those in the first embodiment are designated by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIG. 9, the water receiving portion 19 of the paddle 14 has a first inclined portion 19a and a second inclined portion 19b. The first inclined portion 19a of the water receiving portion 19 is located closer to the tip end side of the paddle 14 than the second inclined portion 19b.

With the paddle 14 closed, the angle at which the first inclined portion 19a inclines toward the downstream side of the liquid (water flow 23) flowing through the paddle flow passage 26 of the paddle casing 13 is θ1, and the downstream of the liquid flowing through the paddle flow passage 26 is θ1. If the angle at which the second inclined portion 19b inclines toward the side is θ2, it is preferable that θ1>θ2.

In the above-described configuration, since a large amount of water flow 23 flows in the first inclined portion 19a that is the tip side of the water reception unit 19, the water reception unit 19 efficiently receives force from the water flow 23.

Further, by increasing the angle θ1 at which the first inclined portion 19a that is far from the paddle rotation shaft 20 is inclined, the force received by the water receiving portion 19 from the water flow 23 is efficiently converted into the force for rotating the paddle 14. be able to.

In this way, the force received from the water flow 23 can be collected at the tip end side of the water receiving portion 19 and efficiently converted into the force for opening the paddle 14, so that the flow rate switch 6 reacts sharply with a smaller flow rate and is activated. It is possible to provide the flow switch 6 or the electric pump 1 of good quality.

(Embodiment 3)
10, components similar to those in Embodiments 1 and 2 are designated by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIG. 10, when the paddle 14 is closed, the water receiving edge portion 22 of the water receiving portion 19 preferably overlaps the flow passage edge portion 27 which is the periphery of the paddle flow passage 26.

With this configuration, when the paddle 14 is closed, almost all the water flow 23 hits the water receiving portion 19, so that the water flow 23 efficiently receives a force.

As a result, almost all of the water receiving portion 19 receives a force from the water flow 23, and it can be more efficiently converted into a force for opening the paddle 14, and the flow rate switch 6 can be sensitively activated even at a smaller flow rate. it can.

In addition, as shown in FIG. 10, the inner surface 22a of the water receiving edge portion 22 provided on the bottom surface of the water receiving portion 19 and the inner surface 27a of the flow channel edge portion 27 of the paddle flow channel 26 are aligned. Preferably.

With this configuration, water can be smoothly guided from the paddle flow path 26 to the water receiving portion 19, so that the force received by the water receiving portion 19 from the water can be more efficiently converted into the force for opening the paddle 14.

Although the flow switch or the electric pump according to the present invention has been described above based on the embodiment, the present invention is not limited to the embodiment. Unless departing from the gist of the present invention, various modifications that can be conceived by those skilled in the art are made to the present embodiment, and forms constructed by combining the constituent elements of different embodiments are also included in the scope of the present invention. ..

INDUSTRIAL APPLICABILITY The flow rate switch or the electric pump according to the present invention is effective as a flow rate switch or an electric pump or the like that can open and close the paddle even when the flow rate is small, and can be activated by reacting sharply even at a small flow rate.

1 Electric Pump 2 Motor 3 Pump Casing 4 Suction Port 5 Discharge Port 6 Flow Switch 7 Impeller 8 Terminal Cover 9 Fan Cover 10 Cooling Fan 11 Rotating Shaft 12 Base 13 Paddle Casing 14 Paddle 15 Cover 16 Board 17 Reed Switch 18 Switch Starting Means 19 Water receiving portion 19a First inclined portion 19b Second inclined portion 20 Paddle rotation shaft 21 Holding portion 22 Water receiving edge portion 22a Inner surface 23 Water flow 24 Flat paddle 26 Paddle flow passage 27 Flow passage edge portion 27a Inner surface 28 Insertion port 29 Water receiving portion 30 spring θ1 angle θ2 angle

Claims (5)

A base having a reed switch,
A paddle casing fixed to the base,
A paddle connected to the paddle casing,
A flow rate switch having a switch starting means for starting the reed switch,
The paddle casing has a paddle flow path through which liquid flows,
The paddle includes a water receiving portion, a paddle rotation shaft and a holding portion, and is connected to the paddle casing via the paddle rotation shaft,
The switch starting means is held by the holding unit,
The water receiving part is arranged on the paddle flow path and has a bowl shape which is recessed toward a downstream side of a liquid flowing through the paddle flow path. The water receiving portion has a first inclined portion and a second inclined portion,
The first inclined portion is located closer to the tip side than the second inclined portion,
In the state where the paddle is closed, the angle at which the first inclined portion is inclined toward the downstream side of the liquid flowing through the paddle channel is θ1, and the second inclination is toward the downstream side of the liquid flowing through the paddle channel. If the angle at which the part inclines is θ2,
The flow switch according to claim 1, wherein θ1>θ2. The water receiving portion has a water receiving edge portion on the bottom surface,
The flow switch according to claim 1 or 2, wherein the water receiving edge portion overlaps a flow path edge portion that is the periphery of the paddle flow path when the paddle is closed. The flow rate switch according to claim 3, wherein an inner surface of the water receiving edge portion and an inner surface of the flow path edge portion coincide with each other on a tip side of the water receiving portion. An electric pump provided with the flow rate switch according to any one of claims 1 to 4.