JP6698928B2 - Liquid level sensor device and automatic liquid supply system - Google Patents

Description

  The present invention relates to a liquid level sensor device and an automatic liquid supply system.

Generally, an automatic water supply device (automatic liquid supply device) for supplying water to a paddy field or the like is used to manage the water surface (liquid level) position of agricultural water (liquid) in a paddy field or the like (see, for example, Patent Document 1). ).
The automatic water supply device is controlled by a float switch (liquid level sensor) that detects the position of the water surface. The float switch is installed at a desired height position from the ground (object to be installed) such as a paddy field. The float switch is turned on or off as the position of the water surface changes and the float moves up and down. When the position of the water surface is lowered and the float switch is turned off, the float switch instructs the opening operation of the water tap provided in the automatic water supply device. Water is supplied to paddy fields by opening the water tap.
The float switch instructs the closing operation of the water faucet when the position of the water surface rises and becomes ON. The water supply to the paddy fields is stopped by closing the water tap. As a result, the water surface is held at the desired position.

  Farmers manage the position of the water surface for each paddy field so that the position of the water surface is appropriate for the type of crop and the growth situation. For that purpose, it is necessary to install a plurality of float switches in the paddy field and adjust the height position of the float switches in detail and frequently according to the growth of the crop.

Japanese Patent No. 3897619

However, when adjusting the height position of the float switch, it is difficult for the user to recognize the height from the surface of the object to be installed to the float switch.
Further, when the float switch is installed in a paddy field, the installation standard varies due to the hardness of the object to be installed, etc. Therefore, it is difficult to unify the installation standard when installing a plurality of float switches.

  The present invention has been made in view of such problems, and when the user can easily recognize the height from the surface of the object to be installed to the liquid level sensor, when a plurality of objects are installed. It is an object of the present invention to provide a liquid level sensor device that can unify the installation standards of (1) and an automatic liquid supply system including the liquid level sensor device.

In order to solve the above problems, the present invention proposes the following means.
The liquid level sensor device of the present invention includes a liquid level sensor for detecting the position of the liquid level of a liquid, a lead wire connected to the liquid level sensor, and an opening formed at an end in the axial direction to form the liquid level inside thereof. A storage body having a storage space for storing the sensor is formed, and a lid portion that covers an opening of the storage body. An end portion of the storage body reaches the storage space from a side surface of the storage body and is A notch extending in the axial direction of the container is formed, and at least a part of the notch is exposed to the outside of the lid with the lid covering the opening of the container , and the lead wire is It is characterized by being draw out to the outside of the housing body.
According to this invention, since the liquid level sensor is housed in the container, it is possible to prevent the liquid level sensor from being damaged by wind and rain, and to prevent the accuracy of the liquid level sensor from being deteriorated due to dust or the like. ..
Further, since the lead wire of the liquid level sensor is pulled out of the housing body from the portion of the notch formed in the housing body exposed from the lid portion, the lid portion covering the opening of the housing body is provided. It is possible to make it difficult for foreign matter such as dust to enter.

  In the liquid level sensor device described above, the lid may be detachably attached.

  Further, in the above liquid level sensor device, the width of the notch may be about the outer diameter of the lead wire of the liquid level sensor.

A communication hole may be formed in the storage body at a position not buried in the ground to connect the storage space and the outside.
According to this invention, the liquid enters the container through the communication hole. The liquid level sensor detects the position of the liquid level of the liquid that has entered the container. Since the liquid level sensor is housed in the container, it is possible to prevent the liquid level sensor from being damaged by wind and rain, and to prevent the accuracy of the liquid level sensor from being deteriorated due to dust or the like.

Also, the automatic liquid supply system of the present invention is connected to the liquid level sensor device according to any one of the above, and the liquid level sensor of the liquid level sensor device, and the liquid based on the detection result of the liquid level sensor. And an automatic liquid supply device for supplying the liquid.
According to the present invention, by using the liquid level sensor device, the height from the surface of the object to be installed to the liquid level sensor can be easily recognized, and at the same time, the installation standard can be unified when a plurality of objects are installed. The automatic liquid supply device can be stably controlled.

  According to the liquid level sensor device and the automatic liquid supply system of the present invention, the user can easily recognize the height from the surface of the object to be installed to the liquid level sensor, and at the same time, the installation standard when a plurality of devices are installed. Can be unified.

It is the front view which fractured|ruptured a part which shows typically the automatic liquid supply system of 1st Embodiment of this invention. It is a side view of the same automatic liquid supply system. It is sectional drawing of the cutting line AA in FIG. It is an exploded view of a sensor guide, a measuring unit, and the like of the same automatic liquid supply system. It is a front view of a sensor guide of the same automatic liquid supply system. It is a front view of the measurement part of the same automatic liquid supply system. It is a perspective view which shows the procedure which installs the same automatic liquid supply system in a paddy field. It is a partially broken perspective view showing a procedure for installing the same automatic liquid supply system in a paddy field. It is a perspective view which shows the procedure which installs the same automatic liquid supply system in a paddy field. It is sectional drawing which shows the procedure of installing the same automatic liquid supply system in the recessed part of a paddy field. It is sectional drawing which shows the procedure which installs the some same automatic liquid supply system in a paddy field. It is the front view which fractured|ruptured a part which shows typically the automatic liquid supply system of 2nd Embodiment of this invention. It is a side view which shows the same automatic liquid supply system typically. FIG. 3 is a front sectional view of a main part of the automatic liquid supply system. FIG. 15 is a cross-sectional view taken along the section line A2-A2 in FIG. 14. It is a perspective view of the accommodation pipe of the same automatic liquid supply system. It is a perspective view showing the state where a sensor mount was attached to the accommodation pipe. It is a bottom view of the 1st lid part of the same automatic liquid supply system. It is sectional drawing which shows the procedure which installs the same automatic liquid supply system in the recessed part of a paddy field.

(First embodiment)
Hereinafter, a first embodiment of an automatic liquid supply system according to the present invention will be described with reference to FIGS. 1 to 11.
As shown in FIGS. 1 to 3, the automatic liquid supply system 1 of the present embodiment is connected to the liquid level sensor device 51 of the present embodiment and a water level sensor (liquid level sensor) 12 of the liquid level sensor device 51. And an automatic liquid supply device 46. It should be noted that all the drawings below are schematic, and the length, width, and thickness ratios of the respective components of the automatic liquid supply system are not necessarily the same as the actual ones, and can be appropriately changed. .

  The liquid level sensor device 51 includes a water level sensor 12 for detecting the position of the liquid level of the water (liquid), a sensor mount (sensor mounting portion) 15 to which the water level sensor 12 is mounted, and a sensor to which the sensor mount 15 is mounted. An accommodating pipe (accommodation) in which a guide (support portion) 52, a measuring portion 53 detachable from the sensor guide 52, and an accommodating space 16a for accommodating at least a part of the sensor guide 52, the water level sensor 12, and the sensor mount 15 are formed. Body 16).

As the water level sensor 12, for example, a known float type sensor can be used. The water level sensor 12 has a float which is passed through a shaft (not shown). When the float floats when immersed in water, the switch circuit inside the shaft switches from the OFF state to the ON state. In this example, it is assumed that the switch circuit switches from the OFF state to the ON state when the position of the liquid surface moves from below to above the reference position 12a of the water level sensor 12. On the other hand, it is assumed that the switch circuit switches from the ON state to the OFF state when the position of the liquid surface moves from above to below the reference position 12a of the water level sensor 12.
By switching the water level sensor 12 between the OFF state and the ON state, it can be seen that the water level is at the reference position 12a of the water level sensor 12.
However, the reference position 12a of the water level sensor 12 is not limited to this position, and is appropriately set according to the specifications of the water level sensor 12.

  A first end portion of a lead wire 19 is connected to the water level sensor 12. The length of the lead wire 19 is, for example, 30 cm. A connector 20 is provided at the second end of the lead wire 19. It is preferable that the connector 20 and the connector 48 of the automatic liquid supply device 46 described later are waterproof connectors.

  As shown in FIGS. 3 to 5, the sensor guide 52 is, for example, rod-shaped and has a U-shaped cross section orthogonal to the longitudinal direction. That is, the sensor guide 52 has a back plate 55 and a pair of side plates 56 extending from each end of the back plate 55 in a direction orthogonal to the back plate 55. The pair of side plates 56 are arranged so as to face each other. The sensor guide 52 can be formed by bending a stainless steel material or the like.

As shown in FIGS. 4 and 5, the back plate 55 is formed with a pair of through holes (connection regions) 55 a and 55 b extending in the longitudinal direction of the sensor guide 52. The first through hole 55a and the second through hole 55b are long holes that are long in the longitudinal direction of the sensor guide 52. The through holes 55a and 55b are formed at intervals in the longitudinal direction. The first through hole 55a is formed at the second end of the sensor guide 52, and the second through hole 55b is formed at the center of the sensor guide 52 in the longitudinal direction. For example, the length in the longitudinal direction of the through holes 55a and 55b is 10 cm.
A tapered portion 52b is formed at the first end of the sensor guide 52. In the tapered portion 52b, the width of the pair of side plates 56 becomes narrower toward the tip of the first end portion. The angle θ formed by the tip of the tapered portion 52b is an acute angle.
Since the tapered portion 52b is formed in the sensor guide 52, the work of inserting the sensor guide 52 becomes easy, as will be described later.

As shown in FIG. 1, the sensor guide 52 is arranged such that the longitudinal direction of the sensor guide 52 is along the axis C direction of the housing pipe 16.
The sensor mount 15 is installed on the sensor guide 52.

As shown in FIG. 6, for example, the measuring unit 53 may have an elongated plate shape (rod shape). Engagement holes 53a and 53b are formed at both ends of the measuring unit 53 in the longitudinal direction. A scale 58 and a numerical value 59 indicating the height of the scale 58 are described (provided) on the surface of the measurement unit 53 at the intermediate portion in the longitudinal direction.
The scale 58 has a main scale 58a and auxiliary scales 58b and 58c.

The main scale 58a is, for example, a relatively long linear groove extending in the width direction of the measuring unit 53, and is described at intervals of, for example, 5 cm in the longitudinal direction of the measuring unit 53. The auxiliary scales 58b and 58c are relatively short linear grooves extending in the width direction of the measuring unit 53, and are described in the longitudinal direction of the measuring unit 53, for example, at intervals of 1 cm.
The numerical value 59 is described as "0" at the position of the main scale 58a which represents 0 cm which is the origin in the vertical direction. The numerical value 59 is written above the main scale 58a representing 0 cm, for example, at intervals of 5 cm as "5" or "10". On the other hand, the numerical value 59 is written below the main scale 58a representing 0 cm, for example, "-5" and "-10" at intervals of 5 cm.
The scale 58 is formed on the measuring unit 53 by pressing or the like along the longitudinal direction of the measuring unit 53. The scale 58 represents the height at which the water level sensor 12 is installed.
The measuring unit 53 is configured independently of the sensor guide 52. In other words, the measuring unit 53 is separate from the sensor guide 52.

As shown in FIG. 4, the measuring unit 53 is arranged on the outer surface of the back plate 55 of the sensor guide 52. A pair of back metal plates 61 are arranged on the inner surface of the back plate 55. Female screws (not shown) are formed on each back metal plate 61.
The pair of setscrews (axial members) 62 are inserted into the engagement holes 53 a and 53 b of the measuring unit 53, and thus protrude from the outer surface of the measuring unit 53. One set screw 62 is inserted into the first through hole 55a and is screwed into the female screw of the back metal plate 61. The other set screw 62 is inserted into the second through hole 55b and screwed into the female screw of the back metal plate 61.

The measuring portion 53 is attached to the sensor guide 52 by tightening each set screw 62 into the back metal plate 61 and sandwiching the back plate 55 and the measuring portion 53 with the back metal plate 61 and the pair of set screws 62. The measuring unit 53 is attached along the longitudinal direction of the sensor guide 52.
The pair of setscrews 62 may be fixed to the measuring unit 53.
On the other hand, when the back metal plate 61 and the set screw 62 are unscrewed, the measuring unit 53 is removed from the sensor guide 52.

When the user shifts the position where each set screw 62 is inserted into the through holes 55a and 55b in the longitudinal direction of the sensor guide 52 with the back metal plate 61 and the pair of set screws 62 loosened, the sensor The measuring unit 53 moves in the longitudinal direction with respect to the guide 52. In this state, the set screw 62 is tightened on each back metal plate 61 to hold the moved position of the measuring unit 53.
In this way, the measuring unit 53 is configured so that the relative position in the longitudinal direction with respect to the sensor guide 52 can be changed.
As will be described later, the measuring unit 53 is arranged such that the longitudinal direction of the measuring unit 53 is along the vertical direction. The through holes 55a and 55b of the sensor guide 52, the engagement holes 53a and 53b of the measuring unit 53, the back metal plate 61, and the set screw 62 continuously define the relative positions of the sensor guide 52 and the measuring unit 53 along the vertical direction. The fixing mechanism 63 that can be changed to

As shown in FIGS. 1 and 3, the sensor mount 15 includes a mount body 26 formed in a rectangular tube shape and an engagement portion 27 formed in an L shape in a front view and fixed to an outer surface of the mount body 26. And a set screw 28 screwed to the mount body 26.
In the mount body 26, the sensor guide 52 and the measuring unit 53 can be inserted inside a rectangular cylindrical hole.
The engagement portion 27 includes a sensor fixing portion that extends in the horizontal direction from the outer surface of the mount body 26. The water level sensor 12 is detachably fixed to the sensor fixing portion with a screw or the like. The method of fixing the water level sensor 12 to the engaging portion 27 is not limited to this.
The set screw 28 is screwed into a female screw portion (not shown) of the mount body 26. By rotating the set screw 28 with respect to the mount body 26, the relative position of the set screw 28 with respect to the mount body 26 changes. As a result, the length of the set screw 28 protruding into the cylindrical hole of the mount body 26 can be adjusted.

In the longitudinal direction of the sensor guide 52, the reference position 12a of the water level sensor 12 and the lower end of the mount body 26 may be aligned. With this configuration, the reference position 12a of the water level sensor 12 can be easily aligned with the scale 58 of the measuring unit 53.
Further, the mount body 26 may be provided with slits, holes or the like at positions corresponding to the reference position 12a of the water level sensor 12 in the longitudinal direction of the sensor guide 52. The reference position 12a of the water level sensor 12 can be arranged at a desired height by the user visually recognizing the scale 58 of the measuring unit 53 through a slit or the like.

  In the sensor mount 15 thus configured, the user attaches the water level sensor 12 to the engaging portion 27 of the sensor mount 15. The sensor guide 52 and the measuring unit 53 are inserted into the cylindrical hole of the mount body 26 of the sensor mount 15. The position of the water level sensor 12 with respect to the scale 58 of the measuring unit 53 is adjusted. Specifically, in the longitudinal direction of the sensor guide 52, the reference position 12a of the water level sensor 12 is matched with the desired height displayed on the scale 58. In this state, the set screw 28 is rotated to press the set screw 28 against the sensor guide 52, and the mount body 26 is fixed to the sensor guide 52.

By performing the above steps, the water level sensor 12 can be fixed at a desired position on the scale 58 of the measuring unit 53.
Even in this state, the measuring portion 53 can be moved in the longitudinal direction with respect to the sensor guide 52 by loosening the set screw 62 of the fixing mechanism 63.
In order to adjust the position of the water level sensor 12 with respect to the scale 58, the set screw 28 is rotated so that the set screw 28 is separated from the sensor guide 52, and the mount body 26 is released from the sensor guide 52. Then, the mount body 26 is moved with respect to the sensor guide 52 along the longitudinal direction of the sensor guide 52. The set screw 28 is rotated again, the set screw 28 is pressed against the sensor guide 52, and the mount body 26 is fixed to the sensor guide 52.

As shown in FIGS. 1 and 3, the housing pipe 16 is formed in a cylindrical shape from a resin such as vinyl chloride or a metal. In addition, the shape of the edge portion in the cross section orthogonal to the axis C of the accommodation pipe 16 is not limited to a circle, and may be an ellipse, a polygon, or the like.
The cylindrical hole of the accommodation pipe 16 is the accommodation space 16a described above. An opening 31 is formed at the first end 16b of the accommodation pipe 16 in the direction of the axis C.
A first notch 32 that extends from the side surface 16d of the storage pipe 16 to the storage space 16a is formed in the ground insertion portion that is the first end 16b of the storage pipe 16 in the axis C direction. The first notch 32 extends from the end surface of the accommodation pipe 16 in the axis C direction by a predetermined length in the axis C direction. The first notch 32 is formed over a half circumference or more in the circumferential direction of the storage pipe 16.
The protrusion 33 formed at the first end 16b of the storage pipe 16 by forming the first notch 32 is formed at a part of the storage pipe 16 in the circumferential direction.

As shown in FIGS. 1 and 2, an opening 35 is formed in the second end 16c of the accommodation pipe 16 in the direction of the axis C. The second end 16c of the accommodation pipe 16 is provided with a second notch (notch) 36 that extends from the side surface 16d of the accommodation pipe 16 to the accommodation space 16a. The second cutout 36 extends from the end surface of the housing pipe 16 in the axis C direction by a predetermined length in the axis C direction. The width of the second notch 36 is about the outer diameter of a lead wire 47 of the automatic liquid supply device 46, which will be described later.
A plurality of second communication holes (communication holes) 37 penetrating the accommodation pipe 16 are formed on the side surface 16 d of the accommodation pipe 16. Each second communication hole 37 allows water to flow between the outside of the storage pipe 16 and the storage space 16a (inside). The plurality of second communication holes 37 are formed around the axis C of the accommodation pipe 16 at intervals. The plurality of second communication holes 37 are formed at intervals in the axis C direction of the accommodation pipe 16.

  The liquid level sensor device 51 of this embodiment includes a second lid portion (lid portion) 40. The second lid 40 is detachably attached to the second end 16 c of the accommodation pipe 16 and covers the opening 35 of the accommodation pipe 16. The second lid portion 40 has a disc-shaped lid body 41 and an outer edge portion 42 that is provided upright on the edge portion of the lid body 41 over the entire circumference of the lid body 41. The inner diameter of the outer edge portion 42 is larger than the outer diameter of the storage pipe 16. As shown in FIG. 2, the length L1 of the outer edge portion 42 in the axis C direction is shorter than the length L2 of the second cutout 36 in the axis C direction. Therefore, a part of the second notch 36 is not covered by the second lid 40 when the second lid 40 is attached to the accommodation pipe 16. A part of the second notch 36 exposed from the second lid portion 40 to the outside of the second lid portion 40 forms a through portion 36a.

The automatic liquid supply device 46 has a known structure, and includes a water supply pump, a control unit, and the like, which are not shown. The first end of the lead wire 47 shown in FIG. 1 is connected to the controller. The lead wire 47 passes through the through portion 36 a of the accommodation pipe 16.
A connector 48 is provided at the second end of the lead wire 47. The connector 48 is attachable to and detachable from the connector 20 connected to the water level sensor 12.
When the water level sensor 12 is OFF, the control unit drives the water supply pump to supply water. On the other hand, the control unit stops the water supply pump when the water level sensor 12 is in the ON state. In this way, the control unit supplies the water to the supply target such as the paddy field based on the detection result of the water level sensor 12.

Next, a procedure for installing the automatic liquid supply system 1 configured as described above on the flat ground of a paddy field will be described.
The measuring unit 53 is previously attached to a predetermined position in the longitudinal direction of the sensor guide 52 by the fixing mechanism 63.
First, as shown in FIG. 7, the user attaches the sensor mount 15 to the sensor guide 52 and the measuring portion 53, and attaches the water level sensor 12 to the engaging portion 27 of the sensor mount 15.
Next, the first end portion of the sensor guide 52 is inserted (inserted) into the ground (body to be installed) F1 of the paddy field F. Since the sensor guide 52 is formed in a rod shape and the tapered portion 52b is formed at the first end of the sensor guide 52, the first end of the sensor guide 52 can be easily inserted into the ground F1.
The sensor guide 52 may be attached to the ground F1 and then the sensor mount 15 and the water level sensor 12 may be attached to the sensor guide 52.

  When inserting the sensor guide 52 into the ground F1, the longitudinal direction of the sensor guide 52 is made parallel to the vertical direction. Further, as shown in FIG. 1, the main scale 58a in which the numerical value 59 of “0” of the scale 58 is described is made to coincide with the surface of the ground F1. In this case, the height from the surface of the ground F1 to the liquid surface of the water and the display of the height by the scale 58 match.

Next, the set screw 28 is rotated to separate the set screw 28 from the sensor guide 52. The mount body 26 is moved in the longitudinal direction of the sensor guide 52 with respect to the sensor guide 52, and the position of the water level sensor 12 with respect to the scale 58 of the measuring unit 53 is adjusted. Since the scale 13 indicates the height at which the water level sensor 12 is installed, the user can easily know the height from the surface of the ground F1 to the water level sensor 12.
For example, the reference position 12a of the water level sensor 12 in the longitudinal direction of the sensor guide 52 is aligned with the auxiliary scale 58c corresponding to 8.5 cm.
In this state, the set screw 28 is rotated to press the set screw 28 against the sensor guide 14 to fix the mount body 26 to the sensor guide 52.

Note that the scale to be matched with the surface of the ground F1 is not limited to the main scale 58a in which the numerical value 59 of "0" is described, and other main scales 58a, auxiliary scales 58b, 58c, etc. may be used. In this case, the user stores, as the correction value, the positions of the other main scales 58a and the like that are aligned with the surface of the ground F1 with respect to the main scales 58a on which the numerical value 59 of "0" is written. In consideration of this correction value, the reference position 12a of the water level sensor 12 in the longitudinal direction of the sensor guide 52 is adjusted to the desired scale 58.
For example, a case will be described in which the reference position 12a of the water level sensor 12 is arranged at a height of 5 cm from the surface of the ground F1 when the auxiliary scale 58b representing 2 cm is aligned with the surface of the ground F1. In this case, the correction value is 2 cm, and the reference position 12a of the water level sensor 12 is aligned with the auxiliary scale 58b corresponding to 7 cm obtained by adding the correction value of 2 cm to the desired height of the water level sensor 12.

Next, as shown in FIG. 8, the housing pipe 16 is arranged so as to surround at least a part of the sensor guide 52, the water level sensor 12, and the sensor mount 15. The protrusion 33 of the accommodation pipe 16 is inserted into the ground F1. At this time, at least a part of the sensor guide 52, the water level sensor 12, and the sensor mount 15 are housed in the housing space 16 a of the housing pipe 16. Deposits such as mud enter the accommodation space 16a of the first end 16b of the accommodation pipe 16. When the accommodation pipe 16 is inserted into the ground F1, the entire opening 31 of the accommodation pipe 16 is closed by the ground F1.
Since the accommodating pipe 16 is formed in a hollow cylindrical shape instead of a columnar shape, by inserting the accommodating pipe 16 into the ground F1 along the direction of the axis C, the resistance received from the ground F1 can be suppressed and the insertion can be facilitated.

As will be described later, when changing the height of the water level sensor 12, the accommodation pipe 16 is pulled out from the ground F1. Therefore, the depth of inserting the accommodation pipe 16 into the ground F1 is shorter than the depth of inserting the sensor guide 52 into the ground F1 by, for example, 70 mm.
The user connects the connector 48 of the automatic liquid supply device 46 and the connector 20 of the water level sensor 12. The lead wire 47 of the automatic liquid supply device 46 is passed through the second notch 36 of the storage pipe 16.

Next, as shown in FIG. 9, the second lid portion 40 is attached to the second end portion 16c of the storage pipe 16. By attaching the second lid portion 40 to the storage pipe 16, it becomes difficult for foreign matter such as dust to enter the storage pipe 16.
At this time, since the through portion 36a exposed from the second lid portion 40 is formed in the second cutout 36, the lead wire 47 is drawn out of the housing pipe 16 from the through portion 36a of the second cutout 36.
Through the above steps, the automatic liquid supply system 1 is installed on the flat ground F1 of the paddy field F.

Next, a procedure for installing the automatic liquid supply system 1 on the depressed ground F1 of the paddy field F will be described.
First, as shown in FIG. 10, a recess F2 is formed in the ground F1. The first end of the sensor guide 52 is inserted into the bottom surface of the recess F2. At this time, the longitudinal direction of the sensor guide 52 is made parallel to the vertical direction. The main scale 58a in which the numerical value 59 of "0" of the scale 58 is described is made to coincide with the surface of the ground F1 other than the concave portion F2. In the longitudinal direction of the sensor guide 52, the reference position 12a of the water level sensor 12 is aligned with the main scale 58a corresponding to, for example, -5 cm. The sensor mount 15 and the water level sensor 12 are fixed to the sensor guide 52.
The housing pipe 16 is inserted into the bottom surface of the recess F2, and the housing pipe 16 surrounds the sensor guide 52 and the like. The connector 48 and the lead wire 47 of the automatic liquid supply device 46 are processed as described above, and the second lid portion 40 is attached to the storage pipe 16.
Through the above steps, the automatic liquid supply system 1 is installed on the bottom surface of the recess F2.

  When the automatic liquid supply system 1 is installed in this way, the height of the liquid surface of the water is maintained at a position 5 cm below the surface of the ground F1 other than the recess F2.

Next, a procedure for changing the height of the water level sensor 12 will be described.
First, the user removes the second lid 40 from the storage pipe 16. The lead wire 47 of the automatic liquid supply device 46 is removed from the second notch 36 of the storage pipe 16. The connection between the connector 48 of the automatic liquid supply device 46 and the connector 20 of the water level sensor 12 is released.
The storage pipe 16 is pulled out from the ground F1. Deposits such as mud that enter the accommodation space 16a from the first end portion 16b of the accommodation pipe 16 are retained in the accommodation space 16a because the first notch 32 is formed in the first end portion 16b. It gets harder. Therefore, when the storage pipe 16 is pulled out from the ground F1, it is possible to prevent the storage pipe 16 from being lifted up while the attached matter remains on the first end portion 16b of the storage pipe 16.

Next, the set screw 28 is rotated so that the set screw 28 is separated from the sensor guide 52, and the mount body 26 is moved with respect to the sensor guide 52 along the longitudinal direction of the sensor guide 52. The reference position 12a of the water level sensor 12 in the longitudinal direction of the sensor guide 52 is adjusted to a new desired scale 58.
The set screw 28 is rotated again, the set screw 28 is pressed against the sensor guide 52, and the water level sensor 12 is fixed to the sensor guide 52.
The housing pipe 16 is inserted into the ground F1, and the housing pipe 16 surrounds the sensor guide 52 and the like. The connector 48 and the lead wire 47 of the automatic liquid supply device 46 are processed as described above, and the second lid portion 40 is attached to the storage pipe 16.
Through the above steps, the height of the water level sensor 12 is changed.

Next, the operation of the automatic liquid supply system 1 will be described.
For example, as shown in FIG. 1 and FIG. 2, a case where the position L6 of the liquid surface of the water is lower than the auxiliary scale 58c corresponding to 8.5 cm including the reference position 12a of the water level sensor 12 will be described.
In this case, the water enters the accommodation space 16 a of the accommodation pipe 16 through the second communication hole 37 of the accommodation pipe 16. Floating matter F6 such as dead grass may float on the surface of the irrigation water. Even in this case, since the plurality of second communication holes 37 are formed around the axis C at intervals, even if a part of the plurality of second communication holes 37 is clogged with the suspended matter F6, all of the remaining portion is left. Is unlikely to become clogged. Therefore, it becomes difficult for the plurality of second communication holes 37 to be completely clogged. In addition, since the plurality of second communication holes 37 are formed at intervals in the axis C direction, the water is supplied into the accommodation space 16a through the second communication hole 37 regardless of the position of the liquid surface in the axis C direction. Can easily penetrate.
Since at least a part of the sensor guide 52, the water level sensor 12, and the sensor mount 15 are housed in the housing space 16a of the housing pipe 16, the water level sensor 12 is damaged by wind and rain, or the water level with respect to the sensor guide 52. The sensor 12 is less likely to be displaced.

Since the position L6 of the liquid surface of the water is below the reference position 12a of the water level sensor 12, the water level sensor 12 is in the OFF state. The control unit drives the water supply pump to supply water to the paddy field F. When the water is supplied to the paddy field F, the position L6 of the liquid surface of the water rises.
As shown in FIG. 1, when the position L7 of the water surface of the water reaches the auxiliary scale 58c corresponding to 8.5 cm, the water level sensor 12 is turned on. The control unit stops the water supply pump.

When a certain period of time elapses after the water supply pump has stopped, the position L7 of the liquid surface of the water drops due to evaporation of the water or the like. The water level sensor 12 is turned off, and the control unit drives the water supply pump to supply water to the paddy field F.
In this way, the water level sensor 12 detects the position of the liquid surface of the irrigation water, and the automatic liquid supply device 46 supplies the irrigation water to the paddy field F based on the detection result of the water level sensor 12, so that the irrigation water is supplied from the surface of the ground F1. The height to the liquid surface is kept at about 8.5 cm.

Next, a procedure for installing the plurality of automatic liquid supply systems 1 on the flat ground F1 of the paddy field will be described.
In this example, as shown in FIG. 11, a case where a plurality of automatic liquid supply systems 1 (hereinafter referred to as automatic liquid supply systems 1A and 1B) are installed in the ground F1 will be described. The configuration of the automatic liquid supply system 1A is indicated by adding an uppercase letter "A" to the reference numeral of each configuration. Similarly, the configuration of the automatic liquid supply system 1B is indicated by adding a capital letter "B" to the reference numeral of each configuration. The user attaches the sensor mounts 15A and 15B and the water level sensors 12A and 12B to the sensor guides 52A and 52B. The first ends of the sensor guides 52A and 52B are inserted into the ground F1 of the paddy field F. The sensor guides 52A and 52B are inserted so that their longitudinal directions are parallel to the vertical direction.
At this time, it is assumed that the sensor guide 52B is inserted deeper than the sensor guide 52A because the hardness of the ground F1 varies depending on the location.

  The positions of the sensor guides 52A and 52B inserted in the ground F1 are not changed, and the measuring units 53A and 53B are moved in the longitudinal direction with respect to the sensor guides 52A and 52B, so that the scales 58A and 58B of the measuring units 53A and 53B are adjusted. Unify the height, which is the installation standard. Specifically, on the surface of the flat ground F1, the main scales 58aA, 58aB (hereinafter referred to as zero points), etc., on which the numerical values 59A, 59B of "0" of the scales 58A, 58B of the measurement units 53A, 53B are described. Match the height. The heights of the zero points and the like of the measurement units 53A and 53B may be adjusted to the position of the liquid surface of the water. In this way, by moving the measuring units 53A and 53B in the longitudinal direction with respect to the sensor guides 52A and 52B, the scales 58A of the measuring units 53A and 53B, regardless of the positions where the automatic liquid supply systems 1A and 1B are installed, The height of the zero point of 58B is the same.

  Hereinafter, the procedure to be performed for the automatic liquid supply systems 1A and 1B is the same as the above-mentioned procedure, and thus the description thereof is omitted.

As described above, according to the liquid level sensor device 51 of the present embodiment, the user installs the sensor guide 52 on the ground F1. Since the scale 58 is described on the measuring unit 53 attached to the sensor guide 52, the height from the surface of the ground F1 to the water level sensor 12 can be easily recognized.
Further, since the position of the measuring unit 53 serving as the reference can be adjusted with respect to the sensor guide 52, the reference of the same height such as the surface of the ground F1 is not affected by properties such as hardness of the ground F1. It is defined as the zero point. Therefore, when a plurality of liquid level sensor devices 51 are installed on the ground F1, it is possible to unify the installation standards for the height of the measuring unit 53.

By providing the liquid level sensor device 51 with the storage pipe 16, it is possible to prevent the water level sensor 12 from being damaged by wind and rain, and the water level sensor 12 from being displaced with respect to the sensor guide 52. It is possible to prevent a decrease in the accuracy of the water level sensor 12 due to dust or the like.
The accommodation pipe 16 is formed in a tubular shape. The sensor guide 52 is formed in a rod shape, and the sensor guide 52 is arranged such that the longitudinal direction of the sensor guide 52 is along the direction of the axis C of the housing pipe 16. Since the accommodation pipe 16 is cylindrical and the sensor guide 52 is rod-shaped, it is possible to easily insert the accommodation pipe 16 and the sensor guide 52 into the ground F1 in the axis C direction.

The deposit such as mud that has entered the accommodation space 16a of the first end 16b of the accommodation pipe 16 is retained in the accommodation space 16a because the first notch 32 is formed in the first end 16b. It gets harder. Therefore, when the storage pipe 16 is pulled out from the ground F1, it is possible to prevent the storage pipe 16 from being lifted up while mud or the like remains on the first end portion 16b of the storage pipe 16.
By providing the liquid level sensor device 51 with the second lid portion 40, it is possible to make it difficult for foreign matter such as dust to enter the accommodation pipe 16.
Since the second notch 36 having the through portion 36a exposed from the second lid portion 40 is formed, the lead wire 47 of the automatic liquid supply device 46 can be drawn out of the housing pipe 16 through the through portion 36a. .

Since the liquid level sensor device 51 includes the fixing mechanism 63, the relative position between the sensor guide 52 and the measuring unit 53 along the vertical direction (longitudinal direction of the sensor guide 52) can be continuously changed. With the simple structure of the through holes 55a and 55b of the sensor guide 52, the engaging holes 53a and 53b of the measuring unit 53, the back metal plate 61, and the set screw 62, which constitute the fixing mechanism 63, the measuring unit 53 can be attached to the sensor guide 52. Can be moved along the vertical direction.
Since the numerical value 59 is written on the surface of the measuring unit 53, the user can easily recognize the height value of the scale 58.

Since the plurality of second communication holes 37 are formed around the axis C with a space therebetween, even if a part of the plurality of second communication holes 37 is clogged by the suspended matter F6 floating on the liquid surface of the water, The possibility that all of the remaining portions of the plurality of second communication holes 37 are clogged is small. Therefore, water can be passed through the remaining portions of the plurality of second communication holes 37.
In addition, according to the automatic liquid supply system 1 of the present embodiment, the user can easily recognize the height from the surface of the ground F1 to the water level sensor 12, and at the same time, the measuring unit 53 when a plurality of units are installed is used. The automatic liquid supply device 46 can be stably controlled by using the liquid level sensor device 51 capable of unifying height installation standards.

In this embodiment, the connection regions are the through holes 55a and 55b. However, the connection region is not limited to this, and may be a notch or the like formed in the back plate 55.
The numerical value 59 may not be written in the measurement unit 53. This is because even if the numerical value 59 is not described, the user can recognize the height that the scale 58 means.
The fixing mechanism 63 is configured to include the through holes 55a and 55b of the sensor guide 52, the engaging holes 53a and 53b of the measuring unit 53, the back metal plate 61, and the set screw 62. However, the fixing mechanism is not limited to this. The fixing mechanism may be a magnet or a hook-and-loop fastener that is fixed to each of the sensor guide 52 and the measuring unit 53 and is detachable from each other. The fixing mechanism may be an adhesive tape that is fixed to one of the sensor guide 52 and the measuring unit 53 and is removable from the other.
The sensor mount 15 may be fixed to the sensor guide 52. In this case, the water level sensor 12 installed in the sensor guide 52 cannot be moved in the longitudinal direction of the sensor guide 52.

(Second embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS. 12 to 19, but the same parts as those of the above-mentioned embodiment are designated by the same reference numerals, and the description thereof will be omitted. Only different points will be described. To do.
As shown in FIGS. 12 and 13, the automatic liquid supply system 2 of the present embodiment includes a liquid level sensor device 71 of the present embodiment instead of the liquid level sensor device 51 of the automatic liquid supply system 1 of the first embodiment. I have it.
The liquid level sensor device 71 is replaced with the sensor mount 15, the containing pipe 16, and the second lid part 40 of the liquid level sensor device 51, and the sensor mount 73, the containing pipe 74, the second lid part 75, and the first lid part. It is equipped with 76.

  As shown in FIGS. 14 and 15, the sensor mount 73 has, in addition to the respective components of the sensor mount 15, a pair of sandwiching pieces 78 extending downward from the sensor fixing portion of the sensor mount 15. The pair of sandwiching pieces 78 form an auxiliary fixing portion 79. The pair of sandwiching pieces 78 are arranged at intervals in the direction in which the sensor fixing portion extends from the mount body 26. As will be described later, the auxiliary fixing portion 79 is for attaching the accommodation pipe 74 to the sensor mount 73.

As shown in FIG. 16, the accommodation pipe 74 is formed in a cylindrical shape from a resin such as vinyl chloride or a metal. A guide notch 82 reaching from the side surface of the accommodation pipe 74 to the accommodation space of the accommodation pipe 74 is formed at the second end of the accommodation pipe 74 in the direction of the axis C2. The guide notch 82 extends from the end surface of the second end of the accommodation pipe 74 by a predetermined length in the axis C2 direction. The width of the guide notch 82 is longer than the width of the engaging portion 27 of the sensor mount 73.
Note that, for example, the length of the lead wire 19 connected to the water level sensor 12 used in this embodiment is 35 cm.
The accommodation pipe 74 is formed with a fixed notch (fixed portion) 83 extending from the bottom surface of the guide notch 82 in the circumferential direction of the accommodation pipe 74. The fixed notch 83 reaches the accommodation space of the accommodation pipe 74 from the side surface of the accommodation pipe 74. The fixed notch 83 is connected to the guide notch 82.

A second cutout 84 is formed at the second end of the accommodation pipe 74, similar to the second cutout 36 described above. The second notch 84 is arranged so as to be displaced in the circumferential direction from the guide notch 82. The second cutout 84 extends from the end surface of the second end of the accommodation pipe 74 by a predetermined length in the axis C2 direction. The width of the second notch 84 is about the outer diameter of the lead wire 19 connected to the connector 20.
A cutout similar to the second cutout 84 may be formed at the first end of the accommodation pipe 74.
As shown in FIG. 14, the accommodation pipe 74 is formed with a second communication hole 85 that connects the outside and the inside of the accommodation pipe 74. In this example, a plurality of second communication holes 85 are formed around the axis C2 of the accommodation pipe 74 with a space.

Here, a procedure for attaching the sensor mount 73 to the housing pipe 74 configured as described above will be described. It is assumed that the water level sensor 12 is previously fixed to the sensor mount 73.
As shown in FIG. 17, the water level sensor 12 is arranged in the accommodating space of the accommodating pipe 74, and the engaging portion 27 of the sensor mount 73 is arranged at a position P1 in the guide cutout 82 of the accommodating pipe 74. The edge portion of the guide cutout 82 in the accommodation pipe 74 is sandwiched by the pair of sandwiching pieces 78 of the auxiliary fixing portion 79. The sensor mount 73 is rotated around the axis C2 with respect to the housing pipe 74, and the engaging portion 27 of the sensor mount 73 is arranged in the fixed notch 83 of the housing pipe 74. As a result, the sensor mount 73 is attached to the accommodation pipe 74. In this way, the fixed notch 83 and the auxiliary fixing portion 79 fix the sensor mount 73 to the housing pipe 74.

As shown in FIG. 12, when the sensor mount 73 is fixed to the sensor guide 52, the housing pipe 74 is arranged such that the axis C2 is along the longitudinal direction of the sensor guide 52.
The housing pipe 74 houses a part of the sensor mount 73 and the water level sensor 12. The housing pipe 74 is attachable to and detachable from the sensor guide 52 via the sensor mount 73.

  On the other hand, in order to remove the sensor mount 73 from the accommodation pipe 74, the sensor mount 73 is rotated with respect to the accommodation pipe 74 to the other side around the axis C2. The sensor mount 73 is removed from inside the guide notch 82 of the accommodation pipe 74.

  As shown in FIG. 14, the second lid part 75 differs from the above-mentioned second lid part 40 only in size. The second lid portion 75 has a disk-shaped lid body 88 and an outer edge portion 89 that is provided upright on the edge portion of the lid body 88 over the entire circumference of the lid body 88. The inner diameter of the outer edge portion 89 is larger than the outer diameter of the accommodation pipe 74. The second lid 75 is detachably attached to the second end of the storage pipe 74. The second lid portion 75 covers the opening formed at the second end of the storage pipe 74.

As shown in FIGS. 14 and 18, the first lid portion 76 has a disc-shaped lid body 92 and an outer edge portion 93 that is provided upright on the edge portion of the lid body 92 over the entire circumference of the lid body 92. ing. The lid main body 92 is formed with a first through hole 92a that connects the outside and the inside of the accommodation pipe 74.
The inner diameter of the outer edge portion 93 is larger than the outer diameter of the accommodation pipe 74. The first lid portion 76 is detachably attached to the first end portion of the accommodation pipe 74. The first lid portion 76 covers the opening formed in the first end portion of the accommodation pipe 74.

In this example, the lead wire 19 of the water level sensor 12 is passed through the second notch 84 of the accommodation pipe 74.
As shown in FIG. 12, the automatic liquid supply device 46 and the connectors 20, 48 connected to each other are housed in a casing 96.

Next, a procedure for installing the automatic liquid supply system 2 configured as above in the recess F2 of the ground F1 will be described.
First, the user mounts the sensor mount 73 and the water level sensor 12 on the sensor guide 52, as shown in FIG. The water level sensor 12 and the like are surrounded by the accommodation pipe 74. As described above, the accommodation pipe 74 is attached to the sensor mount 73. The lead wire 19 of the water level sensor 12 is passed through the second cutout 84 of the accommodation pipe 74. The first lid portion 76 and the second lid portion 75 are attached to the accommodation pipe 74.
The first end of the sensor guide 52 is inserted into the bottom surface of the recess F2 formed in the ground F1. The connector 48 of the automatic liquid supply device 46 and the connector 20 of the water level sensor 12 are connected. The connectors 20, 48 and the automatic liquid supply device 46 connected to each other are housed in a casing 96.
Through the above steps, the automatic liquid supply system 2 is installed on the bottom surface of the recess F2.
The water flows into the accommodation space of the accommodation pipe 74 or flows out from the accommodation pipe 74 through the first communication hole 92 a of the first lid portion 76 and the second communication hole 85 of the accommodation pipe 74. ..

  When adjusting the position of the water level sensor 12, the sensor mount 73 may be moved vertically with respect to the sensor guide 52 while the water level sensor 12 is housed in the housing pipe 74.

As described above, according to the liquid level sensor device 71 of the present embodiment, the user can easily recognize the height from the bottom surface of the recess F2 of the ground F1 to the water level sensor 12.
Since the liquid level sensor device 71 includes the storage pipe 74, it is possible to prevent the water level sensor 12 from being damaged by wind and rain, and to prevent the accuracy of the water level sensor 12 from being reduced due to dust or the like.
Since the liquid level sensor device 71 includes the first lid portion 76, it is possible to prevent foreign matter such as dust from entering the accommodation pipe 74.

As described above, the first embodiment and the second embodiment of the present invention have been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and a configuration within a range not departing from the gist of the present invention Change, combination, deletion, etc. are also included. Further, it goes without saying that the configurations shown in the respective embodiments can be appropriately combined and used.
For example, in the first and second embodiments, the number of the second communication holes formed in the accommodation pipe may be one instead of plural.

Although the through portion 36a of the second cutout 36 of the storage pipe 16 is exposed from the second lid 40, the cutout is formed in the outer edge portion 42 of the second lid 40 so as to overlap the second cutout 36. Therefore, the entire second cutout 36 may be exposed from the second lid 40. The same applies to the second embodiment.
The liquid level sensor device may not be provided with a lid when the amount of dust around the place where the liquid level sensor device is installed is small.
If there is no problem even if mud or the like adheres to the first end portion 16b of the storage pipe 16, the first cutout 32 may not be formed in the storage pipe 16.
Although the container is formed in a cylindrical shape, the container may be formed in a spherical shell shape, a box shape, or the like.

When it is known that the influence of wind and rain acting on the liquid level sensor device is sufficiently small, the liquid level sensor device may not include the accommodation pipe.
The liquid is not limited to water, and may be water, pure water, an aqueous solution, brine, or the like.
The liquid supply method by the automatic liquid supply device 46 is not limited to driving the water supply pump, and may be opening/closing of the water supply valve.

1, 2 Automatic liquid supply system 51, 71 Liquid level sensor device 12 Water level sensor (liquid level sensor)
58 scale 52 sensor guide (support)
15, 73 Sensor mount (Sensor mounting part)
16,74 Containing pipe (container)
16b 1st end part 16c 2nd end part 32 1st notch 36 36 2nd notch (notch)
37, 85 Second communication hole (communication hole)
40, 75 Second lid (lid)
46 Automatic Liquid Supply Device 53 Measuring Unit 59 Numerical Value 63 Fixing Mechanism 76 First Lid 92a First Series of Through Holes C, C2 Axis

Claims (5)

A liquid level sensor that detects the position of the liquid level of the liquid,
A lead wire connected to the liquid level sensor,
A container in which an opening is formed at an end in the axial direction and a housing space for housing the liquid level sensor is formed therein,
A lid portion that covers the opening of the container,
Equipped with
A notch extending from the side surface of the container to the housing space and extending in the axial direction of the container is formed at the end of the container.
The notches, characterized in that said lid portion at least partially in a state of covering the opening of the container is exposed to the outside of the lid, the lead wire is pull out to the outside of the housing body Liquid level sensor device. The liquid level sensor device according to claim 1, wherein
The liquid level sensor device, wherein the lid is detachably attached. The liquid level sensor device according to claim 1 or 2, wherein
The liquid level sensor device, wherein the width of the notch is about the outer diameter of the lead wire of the liquid level sensor. The liquid level sensor device according to any one of claims 1 to 3,
The liquid level sensor device, wherein a communication hole that communicates the storage space with the outside is formed in the storage body at a position not buried in the ground. A liquid level sensor device according to any one of claims 1 to 4,
An automatic liquid supply device that is connected to the liquid level sensor of the liquid level sensor device and supplies the liquid based on a detection result of the liquid level sensor,
An automatic liquid supply system comprising:

Images