JPH0426520Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a sluice control device for dividing the upstream water level into several stages and allowing the water to flow downstream in an overturning sluice gate.

[Conventional technology]

A tipping type flood gate control device that automatically controls the water gate to overturn and increase the discharge amount when the water level rises on the upstream side uses a level meter such as a float to detect the water level on the upstream side of a river or waterway. When the water level reaches a certain level, the sluice gate is tipped over to increase the amount of water released, and when the water level on the upstream side falls, the sluice gate is erected to its original state.

Conventional water gate control devices control the water gate so that it is in two states: either down or up, and therefore cannot adjust the amount of water discharged per hour.

In order to overcome this drawback, the applicant first devised an overturning water gate control device as shown in FIG. To explain this structure, 1 is an overturning water gate, 2 is a side wall on the upstream side of the river, and 3 is a bottom plate of the river. The water gate 1 is supported by a shaft 4 so as to be openable, and is driven by a hydraulic cylinder 5.
That is, the hydraulic cylinder 5 is attached to a bracket 6 fixed to the floor surface by a pin 7, and the rod 8 of the hydraulic cylinder 5 is attached to a bracket 9 fixed to the water gate 1 by a pin 10. 11 is a piston of the hydraulic cylinder 5.
A sprocket 12 is provided on the shaft 4 of the water gate 1. On the other hand, in the upper part of the device chamber 13, a rotary plate 14 having irregularities formed around the entire circumference is attached to a shaft 15, and a sprocket 16 is keyed to the shaft 15. The sprocket 12 and this sprocket 16 are linked by a chain 17. A convex portion 18a is provided in the middle of the lever 18, which is rotatable about the base end as a fulcrum, so as to come into contact with the uneven surface of the rotary plate 14. A rod 20 with a float 19 attached to its lower end is attached to the tip of the lever 18.
9 floats and sinks within the float chamber 21 due to fluctuations in water level. The float chamber 21 is provided with a water intake port 21a, so that changes in the external water level can be directly detected as vertical movements of the float 19. A collapse valve 22 is provided near the base end of the lever 18, and is operated by vertical movement of the lever 18. When the water level is low, the valve is switched to the check valve 22a side, and when the water level is high, the valve is switched to the pass 22b side. is being used.

Next, the configuration of the hydraulic circuit shown in FIG. 7 will be explained. The hydraulic oil in the oil tank 23 is sent out via a strainer 24 by a hydraulic pump 26 driven by an electric motor 25. A check valve 27 is provided midway to prevent backflow.
The pressure of the hydraulic oil is monitored by a pressure gauge 28, and when the pressure exceeds a certain level, a release valve 29 is activated to return the oil into the oil tank 23. Water gate 1
A manual switching valve 30 for manually operating the water gate has a forward port 30a for raising the water gate 1, a neutral portion 30b, and a reverse port 30c for causing the water gate 1 to fall. A stop valve 31 is provided between the lodging valve 22 and the manual switching valve 30.

In such a conventional device shown in FIG.
When raising the water gate 1, close the stop valve 31, operate the manual switching valve 30, and when the protrusion 18a of the lever 18 of the lodging valve 22 enters the recess of the rotary plate 14, the manual switching valve 30 is moved to the neutral position. Make it 30b,
The water gate 1 is stopped and a stop valve 31 is opened to cause the water gate 1 to fall over in several stages when the water level on the upstream side rises by a certain amount.

[Problem that the invention attempts to solve]

In such a conventional structure of an overturning water gate control device, the water gate 1 does not rise unless the stop valve 31 is closed. This is because the rotating plate 14 is connected and fixed to the rotational movement of the water gate 1.
When you move the rotary plate 14, the convex part 18a of the lever 18 is pushed up by the convex part of the rotary plate 14, so the lodging valve 22 is switched and the hydraulic oil does not go to the hydraulic cylinder 5, but from the lodging valve 22. oil tank 2
This is to return to step 3. Moreover, even if the water gate 1 is stopped while it is being erected, the water gate 1 will fall to the predetermined position if it is not in the predetermined position. This is because when the manual switching valve 30 is placed in the neutral position and the stop valve 31 is opened, thinking that the standing up is finished, if the convex part 18a of the lever 18 is not inserted into the concave part of the rotary plate 14, the lodging valve 22 will be closed. Since it is in the path 22b state, it falls over until it reaches the check valve state 22a. In other words, it will fall until the convex portion 18a of the overturning valve lever 18 enters the concave portion of the rotary plate 14. Therefore, a device must be provided to confirm when the convex portion 18a of the collapse valve lever 18 enters the concave portion of the rotary plate 14.

If the stop valve 31 is not opened after the rising operation is completed, the water level on the upstream side will rise by a certain amount, and the lodging valve 2 will rise.
Even if 2 is activated, sluice 1 will not overturn by a certain amount.
That is, even if the stop valve 31 is not open, the manual switching valve 30 can be used to perform the overturning operation, but a person must be present to perform the operation, and in an emergency, the overturning operation may not be possible. The water level on the upstream side rises. The tipping water gate 1 is located in a river, and if the water level on the upstream side rises too much, water may overflow the river embankment, flooding houses, fields, etc., and causing great damage.

The present invention was devised in view of the above circumstances, and allows for the standing operation to be performed only by operating the manual switching valve, and also prevents abnormalities in the device when the stop valve is forgotten to be closed or opened. The purpose is to prevent damage to other parts.

[Means for solving problems]

In order to achieve this purpose, the water gate control device of the present invention is equipped with a hydraulic control device that drives the water gate body to overturn, and a one-way clutch is attached to the drive shaft that rotates in response to the displacement of the overturning movement of the water gate body. , a rotary plate having a plurality of irregularities on the circumference is rotatably attached to the drive shaft and configured to receive rotational force via the one-way clutch, and the base end is rotated by a support shaft. The overturning valve lever is freely supported and has a float at its tip that moves up and down according to fluctuations in the water level on the upstream side of the water gate, and a convex portion that engages with the unevenness of the rotary plate is provided in the middle part of the overturning valve lever. The invention is characterized in that a collapse valve that is linked to the rotation of the hydraulic pressure control device is connected to the hydraulic control device.

〔Example〕

Hereinafter, the present invention will be specifically explained based on the embodiments shown in FIGS. 1 to 6.

FIG. 1 is a side view showing an embodiment of the present invention, and FIG. 2 is a sectional view taken along the - line in FIG. 1. Note that structures similar to those of the conventional example shown in FIG. 7 are given the same reference numerals to avoid duplication of explanation. The present invention is characterized in that, as shown in FIG. 1, the stop valve 31 in FIG. 7 is removed, and a one-way clutch mechanism 32 is added as shown in FIG. 2. In Fig. 2, 33 is the bearing of the shaft 4;
34 indicates a bearing of the shaft 15.

The one-way clutch mechanism 32 is shown in FIGS.
As shown in the figure. FIG. 3 is a front view, and FIG. 4 is a side view. As shown in detail in FIG. 3, a clutch mounting plate 35 is attached to the shaft 15 with a key, and a rotating plate 14 is rotatably attached via a bearing 36. Clutch mounting plate 3
5, a pawl 38 is rotatably attached to the shaft 37, and is biased counterclockwise in the drawing by a spring 39. Tip 3 of the claw 38
8a is engaged with a recess 14a provided in a small diameter portion formed on the side of the rotary plate 14, and is connected to the shaft 15 in FIG.
Rotating plate 1 follows when rotates counterclockwise.
4 rotates in a clockwise direction, the rotary plate 14 idles and does not rotate as shown in FIG. Also, as shown in Figure 6,
A recess 14b is provided in the large diameter portion of the rotary plate 14 in the circumferential direction as in the conventional case, and when the rotary plate 14 rotates, the lever 18 moves up and down as the convex portion 18a of the lever 18 engages and disengages. It's becoming like that.

Next, the operation of this device will be explained. Electric motor 2
5 rotates, the hydraulic pump 26 rotates, sucks hydraulic oil from the strainer 24, and checks the check valve 2.
7 and reaches the manual switching valve 30. When the manual switching valve 30 is turned on in the direction a, hydraulic oil flows into the hydraulic cylinder 5, pushes the piston 11, and the rod 8 comes out in the direction a. When the rod 8 comes out in the direction a, the overturning water gate 1 is rotated in the upright direction by the bracket 9 and pin 10. When the overturning water gate 1 rotates in the upright direction, the shaft 4 of the overturning water gate fixed to the overturning water gate 1 rotates, and the sprocket 12
transmitted to. When sprocket 12 rotates, chain 17 moves in direction a, sprocket 16 rotates, and rotation is transmitted to shaft 15. When the shaft 15 rotates counterclockwise, the rotating plate 14 rotates. When the rotary plate 14 rotates counterclockwise, the convex portion 18a provided on the lever 18 moves toward the rotary plate 1.
The claw 38 that was inserted into the recess 14b of the rotating plate 14 does not rotate, but the claw 38 that was inserted into the recess 14a of the rotary plate 14 does not rotate.
The tip 38a rotates while sliding on the outer periphery of the rotary plate 14.

When the water surface on the upstream side, which was the water surface _L1 , becomes the water surface _L2 due to an upstream incident, water flows into the float chamber 21 from the water intake port 21a. Float chamber 21
The water flowing inside pushes up the float 19, raises the rod 20, and raises the lever 18. When the lever 18 rises, the lodging valve 22 moves to the path 22b.
In order to switch to the state shown in FIG. It passes through the path 22b of the lodging valve 22 and returns into the oil tank 23.

When the tipping type water gate 1 moves to the tipping side, the shaft 4 of the tipping type water gate fixed to the tipping type water gate 1 rotates.
It is transmitted to the sprocket 12. Sprocket 1
2 rotates, the chain 17 moves in the b direction, the sprocket 16 rotates, and the rotation is transmitted to the shaft 15. When the shaft 15 rotates clockwise, the clutch mounting plate 35 rotates.

When the clutch mounting plate 35 rotates clockwise, the convex portion 18a provided on the lever 18 moves into the concave portion 1 of the rotating plate 14.
It does not rotate at first because it is in 4b, but the claw 3
The tip 38a of the claw 38 slides on the circumference of the rotating plate 14, and the tip 38a of the claw 38 hits the recess 14a of the rotating plate 14, and simultaneously rotates counterclockwise in FIG. As a result, the lever 18 is
The convex portion 18a of the lever 18 is pushed up extra, slides around the circumference, moves to the next concave portion 14b of the rotating plate 14, and the convex portion 18a of the lever 18 is lowered.
When the convex portion 18a descends, the lever 18 descends, and the collapse valve 22 becomes the check valve 22a from the path 22b.
The hydraulic circuit is closed, hydraulic oil stops flowing, the piston 11 stops, and the overturning water gate 1 stops.

[Effect of idea]

As explained above, in this invention, a one-way clutch is attached to the drive shaft that rotates according to the movement of the water gate, and a lever that moves up and down as the water level rises and falls on the circumference of this drive shaft is engaged. A rotary plate provided with unevenness for the purpose of rotation is rotatably mounted and configured to receive rotational force via the one-way clutch, and the operation of the undulation valve of the hydraulic circuit is switched by moving the lever up and down. There is. Therefore, it is possible to perform the standing operation using only the manual switching valve without operating the stop valve as in the conventional case. Further, it is possible to eliminate problems with the device caused by forgetting to close or open the stop valve, and also to prevent damage to the area surrounding the river due to flooding.

[Brief explanation of drawings]

Fig. 1 is a schematic configuration diagram of an embodiment of the present invention, Fig. 2 is a sectional view taken along the - line of Fig. 1, Fig. 3 is an enlarged view of the main part of Fig. 2, and Fig. 4 is a - of Fig. 3. 5 is a sectional view of the operating state shown in FIG. 3, FIG. 6 is an explanatory view showing the engagement relationship between the rotating plate and the lever, and FIG. 7 is a schematic diagram of the conventional device. 1... Tipping type water gate, 2... Side wall, 3... Bottom plate,
4...Shaft, 5...Hydraulic cylinder, 6...Bracket, 7...Pin, 8...Rod, 9...Bracket, 10...Pin, 11...Piston, 12...
...Sprocket, 13...Equipment chamber, 14...Rotating plate, 15...Shaft, 16...Sprocket, 17...
...Chain, 18...Lever, 18a...Protrusion,
19... Float, 20... Rod, 21... Float chamber, 21a... Water intake, 22... Lodging valve,
22a... Check valve, 22b... Pass, 23... Oil tank, 24... Strainer, 25... Electric motor,
26...Hydraulic pump, 27...Check valve, 28
... Pressure gauge, 29 ... Release valve, 30 ... Manual switching valve, 30a ... Forward direction port, 30b ... Neutral section, 30c ... Reverse direction port, 31 ... Stop valve, 32 ... One-way clutch Mechanism, 33, 34
... Bearing, 35 ... Clutch mounting plate, 36 ... Bearing, 37 ... Shaft, 38 ... Pawl, 39 ... Spring.

Claims (1)

[Scope of utility model registration request] A hydraulic control device is provided to drive the water gate body overturning, a one-way clutch is attached to a drive shaft that rotates in response to the displacement of the overturning motion of the water gate body, and a plurality of irregularities are provided on the circumference of the drive shaft. The rotating plate is rotatably attached and configured to receive rotational force via the one-way clutch, the base end is rotatably supported by a spindle, and the tip is configured to receive rotational force through the one-way clutch. A protrusion that engages with the unevenness of the rotary plate is provided at the intermediate portion of the overturning valve lever, which is provided with a float that moves up and down by the overturning valve, and the overturning valve that is linked to the rotation of the overturning valve lever is connected to the hydraulic control device. A water gate control device characterized by: