KR100897242B1 - Chlorine automatic projecting device - Google Patents

Abstract

The present invention relates to an automatic chlorine dosing device, in more detail, the supply pipe (5) into which water is introduced, the water supply pipe (6) branched upward from the supply pipe (5), and the power supply level branched from the supply pipe (5) In the device is provided with a regulator 100, the discharge pipe 10 for discharging excess water, and the water tank (3) in which the water of the water supply pipe 6 is passed through the automatic chlorine injector 200, the automatic chlorine The injector 200 includes a diesel tank 201 in which water is introduced from the water supply pipe 6, ejected and dropped, a second supply pipe 202 formed at the bottom of the diesel tank 201, and the diesel tank 201. An impeller 210 configured to be operated at the bottom of the hydraulic water pipe 203 and the lower portion of the hydraulic water pipe 203 so that the impeller shaft 220 rotates by the water falling from the hydraulic water pipe 203; A speed reducer 400 for reducing the rotation of the impeller 210; A tube linked pump (500) for receiving power from the reducer (400) to discharge the disinfectant into the water tank (3); The impeller 210 is composed of four wings 230, evenly configured at an interval of 90 degrees to the impeller shaft 220, each of the wings 230 is composed of a water tank 232, the water tank ( 232 therein is provided with a float ball 234, one end of the float ball 234 is provided with a float 235; The locking device 300 provided adjacent to the impeller 210 captures the rising signal of the sub-ball 235 to release the locked impeller 210, and after the release, the impeller 210 rotates a predetermined angle again. It relates to a chlorine automatic charging device characterized in that the locking lock (220).

Goat, impeller, float

Description

Chlorine Automatic Projecting Device}

The present invention relates to an automatic chlorine dosing device, in particular disinfectant according to the flow rate flowing into the water tank through the water supply pipe to sterilize the bacteria contained in the drinking water, such as ground water, valley water stored in the water tank for storing drinking water It is to automatically disinfect (chlorine).

As is well known, in rural areas and mountain villages without water supply facilities, water tanks are installed on the hillsides of the mountains, and water is stored in the water tanks to supply water to each household. Since this water is to pump ground water, chlorine (or disinfectant) is added to the water tank to disinfect the stored water.

As such, when chlorine (or disinfectant) is added to sterilize bacteria contained in the water stored in the water tank, the disinfectant has been regularly added, but it is difficult to input the proper amount according to the amount of stored water. It is guessed. Therefore, there was a problem that the concentration of chlorine (or disinfectant) became high or too low.

The proper amount of chlorine (or disinfectant) should be added according to the amount of water flowing into the water tank, but it is impossible for human to input each time, so it is automatically equipped with a water level regulator to control the water level and an automatic disinfectant solution. To be supplied.

In the prior art, when the level of the water tank is about half, some of them go to the water supply pipe and some of them are sent to the discharge pipe, and there is a problem that the disinfectant injector operating on the watermill principle with a small amount of water does not work well. In addition, as shown in FIG. 14, the mouth opening 2 for adjusting the opening and closing of the check valve 1 is repeatedly operated within 90% to 100% of the opening and closing rate of the check valve 1 when a large number of valleys are introduced. There is a problem that the drug discharged from the drug injector (4) is not correctly discharged because it continues to replenish a small amount of valley water.

In the prior art, even if the amount of water supplied to the water tank 3 is constant, if the flow rate of water increases due to the water head difference (potential energy), the force (hit torque) applied to the impeller increases, thereby causing excessive administration of chlorine or disinfectant. The purpose of the present invention is to solve this problem, which is directly proportional to the water flowing into the water tank (3) irrespective of the flow rate of the water supplied or the water head difference between the supply point and the point where the water tank (3) is installed. In order to provide an automatic chlorine dosing device that chlorine can be introduced into the water tank (3).

An object of the present invention is to solve the problems of the prior art, and to provide an automatic chlorine dosing device that operates correctly even when the water supplied to the automatic chlorine dosing pipe.

In the prior art, when the level of the water tank is about half, some of them go to the water supply pipe and some of them are sent to the discharge pipe, and there is a problem that the disinfectant injector that operates on the watermill principle with a small amount of water does not work well. Even if the water tank is in the middle of the water level, all of the water can be sent to the water supply pipe, or all of the water can be sent to the discharge pipe so that the operation of the disinfectant injector can be made clear. To provide.

In addition, it is to provide a chlorine automatic dosing device with a set of automatic chlorine dosers and a non-power level controller that is durable, productive and economical, simple in structure and capable of performing a reliable control operation.

The present invention is intended to be sterilized by discharging the appropriate amount of disinfectant into the water stored in the water tank according to the flow rate of water introduced into the water tank. That is, to control the disinfectant discharged from the tube-driven pump according to the amount of water introduced into the water tank.

In addition, the present invention is an automatic disinfectant dosing device that can arbitrarily adjust the level (high and low water level) in the water tank by the designer by adjusting the height of the other parts to control the water level of the float to control the opening and closing of the check valve To provide.

The automatic chlorine injection device according to the present invention, the water supply pipe 5, the water supply pipe 6 branched upwardly from the supply pipe 5, branched from the supply pipe 5 and the no-power level regulator 100 In the device is provided with a discharge pipe 10 for discharging excess water, and the water tank (3) in which the water of the water supply pipe 6 is passed through the automatic chlorine injector 200, the automatic chlorine injector 200 Is,

A light oil tank 201 in which water flows from the water supply pipe 6 and is ejected and dropped;

A second supply pipe 202 configured at the bottom of the diesel tank 201,

An operating water pipe 203 configured at the bottom of the diesel tank 201,

An impeller 210 formed at a lower portion of the hydraulic water pipe 203 and having the impeller shaft 220 rotated by water falling from the hydraulic water pipe 203;

A reducer 400 which slows down the rotation of the impeller 210,

A tube linked pump (500) for receiving power from the reducer (400) to discharge the disinfectant into the water tank (3);

The impeller 210 is composed of four wings 230, evenly configured at an interval of 90 degrees to the impeller shaft 220, each of the wings 230 is composed of a water tank 232, the water tank ( 232 therein is provided with a float ball 234, one end of the float ball 234 is provided with a float 235;

The locking device 300 provided adjacent to the impeller 210 captures the rising signal of the sub-ball 235 to release the locked impeller 210, and after the release, the impeller 210 rotates a predetermined angle again. Locking by restraining 220.

In the automatic chlorine injection device according to the present invention, the no-power level controller 100,

A discharge pipe 10 branching from the supply pipe 5 and discharging excess water;

A valve (20) provided inside the discharge pipe (10) for opening and closing the discharge pipe (10), and opening and closing by rotating the operating shaft (22);

An extension of the shape extending while inclining outwardly from the first operation period 31, the second operation period 32 bent from the first operation period 31, and the second operation period 32; An operation rod 30 including a rod 34 and a boundary portion 33 of the first operation 31 and the second operation 32 coupled to the operation shaft 22;

A first weight weight 42 and a restoring portion 40 installed at an end of the extension rod 34 of the operation period 30;

The first operation section 31 is provided on one side of the discharge pipe 10 based on the operation shaft 22 to grip the first operation section 31, and when the water in the water tank reaches the upper limit level, the first operation section 31 is provided. A first holding part (50) comprising a support (51) fixed to the discharge pipe (10) and a hook (53) rotatably connected to the support (51);

An upper limit control section 60 for transmitting an upper limit water level ((L-upper limit)) signal to the hooking port 53 of the first holding part 50 and connected to the first holding part 50;

The second operating interval 32 is provided on the discharge pipe 10 on the opposite side of the first gripper 50 on the basis of the operation shaft 22 to grip the water, and the water in the water tank has a lower limit level (L−). Lower end) when the operation between the operation 32 is terminated, and the second support (71) fixed to the discharge pipe 10 and the second hook (22) rotatably connected to the second support (71) A gripping portion 70 made of 73;

One side is connected to the reverse line 81 connected to the second hanger 73, and the lower hook (L-lower limit) information connected to the lower end of the reverse line 81 through the reverse line 81 to the second hook ( 73) and a lower limit control portion 80 provided with a weight portion 82, characterized in that it comprises a.

The object of the present invention is to solve the problems of the prior art irrespective of the flow rate of the water supplied or the water head difference between the feed point and the point where the water tank 3 is installed, the chlorine is directly proportional to the water flowing into the water tank (3) There is provided an automatic chlorine dosing device that can be introduced into the tank 3.

According to the present invention solves the problems of the prior art, there is provided an automatic chlorine dosing device that works correctly even when there is little water supplied to the chlorine automatic dosing device.

In the prior art, when the level of the water tank is about half, some of them go to the water supply pipe and some of them are sent to the discharge pipe, and there is a problem that the disinfectant injector that operates on the watermill principle with a small amount of water does not work well. Therefore, even if the water tank is in the middle of the water level, all of the water can be sent to the water supply pipe, or all of the water can be sent to the discharge pipe. do.

In addition, an automatic disinfectant dispensing apparatus comprising a disinfectant dispensing apparatus and a non-power level controller, which is durable, productive and economical, has a simple structure, and can perform a reliable control operation.

In addition, a suitable amount of disinfectant can be disinfected by discharging it into the water stored in the water tank according to the flow rate of water flowing into the water tank, and disinfectant discharged from the tube interlocking pump according to the amount of water introduced into the water tank. It is provided with an automatic disinfectant dispensing device that can reduce the volume while simplifying the shifting of the driving device for adjustment.

In addition, there is provided an automatic disinfectant dispensing device that allows the designer to arbitrarily adjust the height level (upper level and lower limit level) in the desired water tank by adjusting the height of another part that controls the level of the float that controls the opening and closing of the check valve. .

Hereinafter, the chlorine automatic charging device according to the present invention will be described in detail according to the embodiment shown in the accompanying drawings. 1 is an overall configuration of the automatic chlorine dosing device according to an embodiment of the present invention, Figure 2 is an impeller perspective of the automatic chlorine dosing device according to an embodiment of the present invention, Figure 3 is a chlorine according to an embodiment of the present invention 4 is a view illustrating the operation flow of the automatic dosing device, Figure 4 is a block diagram of the automatic chlorine dosing device according to an embodiment of the present invention, Figure 5 is a perspective view of the impeller and locking device according to an embodiment of the present invention, Figure 6 Front view of the impeller and the locking device according to an embodiment of the present invention, Figure 7 is a front view of the impeller and locking device according to a second embodiment of the present invention.

As shown in FIG. 1, the automatic chlorine injection device according to the present invention includes a supply pipe 5 into which water is introduced, a water supply pipe 6 branched upward from the supply pipe 5, and a branch from the supply pipe 5. And a non-powered water level controller 100 and a discharge pipe 10 for discharging excess water and a water tank 3 in which the water of the water supply pipe 6 passes through the chlorine autocharger 200. .

First, the chlorine auto input machine 200 will be described in detail. As shown in Figures 2, 4 to 6, the automatic chlorine injector 200 is configured in the diesel tank 201 and the bottom of the diesel tank 201, the water flows into the water flowing from the water supply pipe 6 is dropped The impeller shaft 220 is formed by the second supply pipe 202, the hydraulic water pipe 203 formed at the bottom of the diesel oil tank 201, and the water falling from the hydraulic water pipe 203, which is disposed below the hydraulic water pipe 203. The rotating impeller 210, the reducer 400 for slowing the rotation of the impeller 210, and a tube-operated pump for discharging disinfectant into the water tank 3 by receiving power from the reducer 400 ( 500).

As shown in Figures 2, 4 to 6, the impeller 210 is composed of four wings 230, evenly configured at an interval of 90 degrees to the impeller shaft 220, the wing 230 Each of the tank 232 is configured, the float lever 234 is provided in the tank 232, and one end of the float lever 234 is provided with a float 235.

As shown in FIG. 5 or FIG. 6, the locking device 300 provided adjacent to the impeller 210 captures the rising signal of the buckle 235 to release the locked impeller 210 and releases the impeller. When the 210 rotates by a predetermined angle, the impeller 220 is restrained and locked again.

As shown in FIG. 5 or FIG. 6, the locking device 300 includes a hitting rod 320 that is lifted by the float 235 and a hit rod 330 that is hit by the hitting rod 320. The first gear 340, the second gear 350 is provided to be engaged with the lower portion of the first gear 340, the second gear 350 is connected and rotates together with the second gear 350 and the tank 232 It is configured to include an operating lever 360 configured to support the bottom of the).

As shown in Figure 5, in the automatic chlorine injector 200 according to an embodiment of the present invention, the mouth 235 and the blow rod 320 attached to the mouth 235 is obliquely outward (Fig. As shown in FIG. 5, it is preferable to rise upwardly inclined relative to the water surface. The end of the striking rod 320 is moved upward and outward to hit even the hit rod 330 that is more outer than the largest rotation radius of the tank (232). One end of the rod 330 is preferably more outward than the largest radius of rotation of the tank 232 otherwise it hits the bottom of the tank 232 to enter in succession to achieve the desired purpose This can happen.

In all cases, however, the striking rod 320 must not be obliquely raised outwardly or one end of the rod 330 must be outside the largest radius of rotation of the tank 232 and is shown in FIG. Likewise, the striking rod 320 and the float 235 may be configured to rise upward as it is. In this case, additionally configured means for preventing the first gear 340 and the hit rod 330 rotated in the clockwise direction immediately by the rise of the striking rod 320 to immediately rotate in the counterclockwise direction (see FIG. 7). Just do it. This can be done by appropriately adjusting the inertia (or moment of inertia) such as the first and second gears 340 and 350 or the support shaft supporting it, and the restoring spring constant. That is, the first gear 340, once rotated in a clockwise direction, may be configured to rotate in a clockwise direction after the upcoming water tank 232 passes without touching the end of the hitting rod 320.

As shown in FIG. 5, the first gear 340 is provided with a stopper 370, and the stopper 370 is in contact with the support 371 in a counterclockwise direction of the first gear 340 (see FIG. 6). It is desirable to set the rotation limit. As shown in FIG. 5, the second gear 350 is rotated counterclockwise and rotates at an angle greater than that of the first gear 340. More preferably, the first gear 340 is rotated at 0.1 rotation. When the second gear 350 is composed of a gear ratio of 0.2 rotation is advantageous in terms of operation.

In terms of operation, the blow rod 320 rises when the float 235 rises due to the water level, the blow rod 320 strikes the hit rod 330, and the hit hit rod 330 is formed of the first rod. One gear 340 is rotated clockwise. When the first gear 340 is rotated in the clockwise direction, the second gear 350 is rotated in the counterclockwise direction to rotate the operating lever 360 in the counterclockwise direction, thereby increasing the level of the operating lever ( The tank 232, which was stopped by 360, is to be rotated a quarter of a turn. The upcoming empty bath 232 is again locked by the restored operating lever 360 until the water reaches the design level.

Restoration (rotating counterclockwise toward the initial position) of the operating lever 360, the first gear 340 and the second gear 350 may be performed using a separate restoring spring, It may be automatically restored by the weight of the 330.

As shown in Figure 1 or 3, the chlorine dosing machine 200 of the present invention is rotated step by step 1/4. When water is supplied from the working water pipe 203 to one water tank 232 and the water level of the water tank 232 rises, the lock is released through the above-described process, and the impeller 210 rotates a quarter of a turn. After that, the water reaches another water level again and remains stationary until the rod 330 is hit.

In the present invention, the unique effects produced by the diesel oil tank 201 will be described. Valley water groundwater supplied from any water source flows into the supply pipe (5). The kinetic energy of the introduced water is almost zero in the diesel tank 201. Regardless of the flow rate of the water entering the diesel tank 201, the speed of the water exiting from the diesel tank 201 to the second supply pipe 202 or the working water pipe 203 is almost uniform. That is, the amount of rotation of the impeller 210 is irrelevant to the flow rate of the water entering the diesel tank 201 from the supply pipe 5, and the amount of water (speed is the same) going out of the working water pipe 203. Thus, chlorine which is directly proportional to the water flowing into the water tank 3 may be introduced into the water tank 3 regardless of the flow rate of the water supplied or the head difference between the feed point and the point where the water tank 3 is installed. The automatic chlorine dosing device is provided.

The present invention is to automatically discharge the disinfectant for sterilizing bacteria contained in the valley water, groundwater, etc., which is fresh in the water tank (3) installed in the countryside or mountain village without water facilities, as shown in FIG. As described above, a water supply pipe 6 for introducing ground water, valley water, or the like into the water tank 3 is mounted, and the water supply pipe 6 includes an impeller 220 that rotates according to a flow rate flowing into the water supply pipe 6. It is installed. And although not shown in the drawing, the water supply pipe 6 is equipped with a flow meter for checking the amount of water introduced into the water tank (3).

As shown in FIG. 4 or FIG. 13, the rotation of the impeller 220 is transmitted to the tubular pump 500 for discharging the disinfectant according to the flow rate through the impeller shaft 210 and the reducer 400. As shown in FIG. 13, the tubular pump 500 includes a flexible tube 551 and a first shoe 552, a second shoe 553, which transfers a fluid in the tube 551. The third shoe 554 and the fourth shoe 555 are formed, and the supply pipe is connected to the inlet side of the tube 551 and the discharge pipe is connected to the outlet side. In addition, by installing the front end of the supply pipe connected to the chemical tank in which the disinfectant is stored so that the disinfectant can be supplied to the tube-linked pump 500.

That is, in the state where the tube 551 is compressed by the second shoe 553, the connection between the inlet side and the outlet side of the tube 551 is closed, so that disinfectant is not supplied. When the first, second, third, and fourth shoes 552, 553, 554, and 555 are rotated (rotated clockwise in the accompanying drawings) by the rotation, the second shoe 553 is located inside the tube 551. The disinfectant is pushed and moved to the outlet side of the tube 551, and the first shoe 552 is pushed and moved to the inside of the inlet side of the tube 551. Therefore, the tube 551 is compressed at two places by the second shoe 553 and the first shoe 552, and the inlet side of the tube 551 is between the second shoe 553 and the first shoe 552. The disinfectant supplied by the drug will be collected. Subsequently, when the rotating shaft 5257 is further rotated, the first shoe 552 is moved to push the collected disinfectant to the outlet side of the tube 551, and the fourth shoe 555 is placed at the inlet side of the tube 551. The disinfectant is pushed and moved to collect a new disinfectant between the fourth shoe 555 and the first shoe 552.

Hereinafter, the non-power level controller will be described. Figure 8 is a perspective view of the non-power level controller of the present invention, Figure 9 is a front view of the non-power level controller of the present invention, Figure 10 is a non-power level controller of the present invention by opening the discharge pipe in the discharge pipe closing mode (water supply mode) by reaching the upper limit water level Figure 11 is an operating state showing the state of switching to the mode (discharge mode), Figure 11 shows the state of the power supply level regulator of the present invention to switch from the discharge pipe opening mode (discharge mode) to the discharge pipe closing mode (water supply mode) by reaching the lower limit level. Fig. 12 is a view of the hook structure of the present invention.

As shown, the non-power level controller according to an embodiment of the present invention is to open the valve 20 of the discharge pipe 10 when the water tank 3 is full water level to discharge excess water, water tank ( When 3) is the low water level, the valve 20 of the discharge pipe 10 is closed and water (valley water) is sent to the water supply pipe 6 to supply the water tank 3.

As shown in FIG. 8 or FIG. 9, the non-power level controller of the present invention includes a discharge pipe 10, a discharge pipe valve 20, an operation 30, a recovery port 40, and a first gripper 50. ), The upper limit control section 60, and the holding unit 70 and the lower limit control section (80).

The discharge pipe 10 is branched from the supply pipe 5 and used to discharge excess water.

The valve 20 is provided inside the discharge pipe 10 to open and close the discharge pipe 10, and performs the opening and closing action by the rotation of the operating shaft 22. When the valve 20 is closed, water is sent to the water supply pipe 6.

The operation section 30 is inclined outwardly from the first operation section 31, the second operation section 32 having a shape bent from the first operation section 31, and the second operation section 32. An extension rod 34 having an extended shape, and the boundary 33 between the first operation 31 and the second operation 32 is coupled to the operation shaft 22. When the operation 30 rotates, the operation shaft 22 rotates together to control the behavior of the valve 20.

Restoration buckle 40 is installed at the end of the extension rod 34 of the operation period (30). Along with this, the first weight 42 is also provided at the end of the extension rod 34.

The first gripper 50 is provided on one side of the discharge pipe 10 based on the operation shaft 22 to grip the first operation 31 to enter. In addition, when the water in the water tank reaches the upper limit level, the first operation period 31 is released, and the hanger is rotatably connected to the support 51 and the support 51 fixed to the discharge pipe (10) It consists of 53.

The upper limit controller 60 transmits an upper limit water level ((L-upper limit)) signal to the hook 53 of the first gripper 50 and is connected to the first gripper 50. The buoyancy of the upper limit control section 60 provides power to cause the first operation 31 to be released from the first gripping section 50.

The second gripping portion 70 is provided on the discharge pipe 10 on the opposite side of the first gripping portion 50 with respect to the operation shaft 22 to grip the second operation interval 32 to enter. When the water in the water tank reaches the lower limit level (L-lower limit), the operation period 32 is released, and the second support 71 fixed to the discharge pipe 10 and the second support 71 are rotated. It consists of a second hook mechanism (73) which is possibly connected.

The lower limit control section 80 is connected to the reverse line 81, one side of which is connected to the second hanger 73, and the lower limit level (L-lower limit) information connected to the lower end of the reverse line 81 through the reverse line 81. The second hanger 73 is delivered to the weight portion 82 is provided. The weight portion 82 pulls the reverse line 81 down by gravity when the lower limit water level is reached in addition to the weight of the lower limit control portion 80. When the water level is high, the gravity of the weight portion 82 is canceled by the buoyancy of the lower limit control section 80.

As shown, in one embodiment of the present invention, the first operation 31 and the second operation 32 of the operation 30 are perpendicular to each other, and the operation 30 is the boundary portion 33. When rotating in the forward direction (Fig. 4-reference clockwise) with respect to the center, the first operation section 31 enters from the bottom toward the first holding unit 50 and is held by the first holding unit 50. .

When the inter-operation 30 rotates in the reverse direction (Fig. 9-reference counterclockwise) about the boundary portion 33, the second inter-operation 32 enters from the bottom upwards toward the second gripper 70. The second gripping portion 70 is held.

As shown, the extension rod 34 extends inclined outwardly in a direction away from the first operation period 31. Therefore, as shown in FIG. 10, in the state in which the operation period 30 is gripped by the first holding part 50, the restoring buoy 40 submerged in water when released by the upper limit water level is subjected to buoyancy for a long time. This buoyancy force strongly rotates the operation section 30 counterclockwise (based on FIG. 10), so that the operation section 30 passes through the second hook hole 73 and is gripped by the second holding unit 70. will be.

If the extension rod 34 extends while inclining inward, which is a direction close to the first operation period 31, the object of the present invention will not be achieved.

As shown, the first gripper 50 is a support 51, which is fixed by welding to the discharge pipe 10, the insertion groove 51a is formed between the operation at the bottom, and the upper side of the support 51 Is fastened to the rotatable hook portion 53 and includes a rotatable.

 It is a detailed block diagram of a hook mechanism. As shown in FIG. 12, the hook tool 53 includes a lower taper portion 56 extending from the lower side of the hook body 54 and an upper extension 55 extending from the upper side of the hook body 54. ), And a holding groove 57 formed by the lower taper portion 56 and the upper extension portion 55.

 The lower taper portion 56 of the first gripping portion 50 forms a taper by its inclined surface 56a being inclined upwardly relative to the hanger body 54, so that the outer surface 56a of the lower tapered portion 56 is formed. It is easy to enter the operation 30 to enter while hitting ().

When the first operation section 31 enters from the bottom toward the first holding part 50 in the canceled state, the first operation section 31 strikes the outer surface 56a of the hooking port 53, and thus As a result, the hook hole 53 reversely rotates (see FIG. 11 -clockwise), and the first operation part 31 enters the gripping groove 57, so that the first gripping part 50 moves between the first operation parts 31. ).

The configuration of the second gripper 70 includes a support 71 and a hook 73 that are the same as or similar to the first gripper 50. However, unlike the first gripping portion 50, the end of the hook (73) is connected by a reverse line. The second gripping portion 70 is fixed to the discharge pipe 10 by welding, and a support 71 formed with an insertion groove 71a therebetween at the lower portion, and one side of the upper portion is fastened to the support 71 to support the support. And a hanger 73 which is rotatable relative to the 71. The hanger 73 is, like the hanger 53 of the first gripping portion 50, a lower taper portion extending from the lower side of the hanger body, an upper extension portion extending from the upper side of the hanger body, and It comprises a gripping groove formed by the lower tapered portion and the upper extension portion.

As illustrated in FIG. 8 and the like, the first gripper 50 includes a lever 61 to which the upper limit control section 60 is coupled, and a buoyancy force of the upper limit control section 60 connected to the lever 61. It can be configured to include a link (63) to pass to the sphere (53). As shown in FIG. 10, when the water level rises to the upper limit level in the gripping state, the water generates buoyancy to the upper limit control float 60 to raise the upper limit control float 60, and the upper limit control float 60 is When the lever 61 is connected to the upper limit control section 60, the lever 61 is raised, and when the lever 61 is raised, the link 63 rotates the hook hole 53 to reverse the first grip portion 50. Terminates the first operation 31 that was held.

Hereinafter will be described the operation according to the configuration of the non-power level controller of the present invention. 10 is an operating state diagram showing the state of the non-power level controller of the present invention to switch from the discharge pipe closing mode (water supply mode) to the discharge pipe opening mode (discharge mode) by reaching the upper limit water level.

In FIG. 10, the water is released from the first gripping portion 50 by the water level rise by the water supply to the water tank in the water supply mode (drain valve valve closing, water supply to the water supply pipe and the disinfectant injector, and the first gripping portion holding state). The operating tool 30 is strongly rotated by the lifting force of the restoring tool 40 deeply immersed in water, enters the second holding part 70, and the second operating part 32 is driven by the second holding part 70. Is shown to be gripped by the second gripping portion (70).

That is, in this process, the operation section 30 is released from the first holding unit 50 and is rotated by the second holding unit 70 by rotating 980 degrees in the counterclockwise direction. In this process, the valve 20 changes from the closed state (water supply mode) to the open state (discharge mode). In this process, the restoration buoy 40 deeply immersed in the water provides the rotational force by buoyancy, the restoration buoy 40 is locked in the lower portion of the water tank in the upper limit water level (full water level) state, it continues for a predetermined time when rising The buoyancy of the restoration sphere is buoyant to accelerate (angular acceleration) strongly between the operation (30). The operation angle 30 in which the rotational angular velocity is increased enters and is gripped by the second gripping portion 70 while surmounting the gravity of the weight 42.

Thereafter, the valve 20 is opened (second gripping portion, surplus water discharge mode) and there is no water entering the water tank. The level of the water tank gradually decreases by the use of the user's disinfectant water.

Eventually, the water tank level, which has only been in demand and has no water supply, will continue to fall. 11 is an operating state diagram showing the state of the non-power level controller of the present invention to switch from the discharge pipe opening mode (discharge mode) to the discharge pipe closing mode (water supply mode) by reaching the lower limit water level.

The weight portion 82 supported by the buoyancy force of the lower limit control portion 80 descends together with the lower limit control portion 80 by reaching the lower limit level in the discharge mode (discharge pipe valve opening, second gripping portion holding state). , The reverse line 81 is pulled down, the reverse line 81 is swept up the end of the second hanger 73, the second operation period 32 is released from the second gripping portion (70). The canceled operation section 30 is strongly rotated in the clockwise direction by the gravity of the weight 42, the first operation section 31 by the strong rotational force to push the hook (53) momentarily The first gripper 50 enters and is gripped.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, the scope of the present invention is not limited to these embodiments, and the scope of the present invention is defined by the following claims, and equivalent scope of the present invention. It will include various modifications and variations belonging to. The reference numerals set forth in the claims below are merely to aid the understanding of the present invention, not to affect the interpretation of the scope of the claims, and the scope of the claims should not be construed narrowly.

1 is an overall configuration of the automatic chlorine dosing apparatus according to an embodiment of the present invention.

Figure 2 is a perspective view of the impeller of the automatic chlorine dosing apparatus according to an embodiment of the present invention.

3 is a view for explaining the operation flow of the automatic chlorine dosing apparatus according to an embodiment of the present invention.

Figure 4 is a block diagram of the automatic chlorine dosing device according to an embodiment of the present invention.

5 is a perspective view of an impeller and a locking device according to an embodiment of the present invention.

6 is a front view of the impeller and the locking device according to an embodiment of the present invention.

7 is a front view of the impeller and the locking device according to the second embodiment of the present invention.

8 is a perspective view of a non-power level controller of the present invention.

9 is a front view of the non-power level controller of the present invention.

Figure 10 is an operating state showing the state of the non-power level controller of the present invention to switch from the discharge pipe closing mode (water supply mode) to the discharge pipe opening mode (discharge mode) by reaching the upper limit water level.

Figure 11 is an operating state showing the state of the non-power level controller of the present invention to switch from the discharge pipe opening mode (discharge mode) to the discharge pipe closing mode (water supply mode) by reaching the lower limit water level.

Figure 12 is a hanger structure diagram of the present invention.

13 is a tube linked pump configuration

14 is a block diagram of a conventional disinfectant input device

<Description of the symbols for the main parts of the drawings>

3: water tank 200: chlorine automatic feeder

5: supply pipe 6: water supply pipe

10: discharge pipe 22: operating shaft

30: Between operations 31: Between first operations

32: Between 2nd operation 33: Boundary part

34: extension rod 40: restoration section

42: first weight 50: first gripping portion

51: support 53: hanger

54: hanger body 55: upper extension

56: lower tapered portion 56a: lower tapered portion outer surface

570: Gripping groove 60: Upper limit control section

61: lever 63: link

70: grip portion 71: second support

73: 2nd hook fixture 80: Lower limit control section

81: reverse line 82: parts by weight

201: Diesel tank 202: Second supply pipe

203: working water pipe 210: impeller

220: impeller shaft 230: wing

232: tank 234: float ball

235: buoy 300: locking device

320: blow rod 330: hit rod

340: first gear 350: second gear

360: operation lever 370: stopper

371: support 400: reducer

500: tube linked pump

Claims (10)

delete A water supply pipe 5 into which water is introduced, a water supply pipe 6 branched upwardly from the supply pipe 5, a discharge pipe 10 branched from the supply pipe 5, and a non-power level controller 100, are provided to discharge excess water. ), And the water tank (3) in which the water of the water supply pipe (6) is dropped through the chlorine automatic feeder (200), The chlorine automatic dosing machine 200, A light oil tank 201 in which water flows from the water supply pipe 6 and is ejected and dropped; A second supply pipe 202 configured at the bottom of the diesel tank 201, An operating water pipe 203 configured at the bottom of the diesel tank 201, An impeller 210 formed at a lower portion of the hydraulic water pipe 203 and having the impeller shaft 220 rotated by water falling from the hydraulic water pipe 203; A reducer 400 which slows down the rotation of the impeller 210, A tube linked pump (500) for receiving power from the reducer (400) to discharge the disinfectant into the water tank (3); The impeller 210 is composed of four wings 230, evenly configured at an interval of 90 degrees to the impeller shaft 220, each of the wings 230 is composed of a water tank 232, the water tank ( 232 therein is provided with a float ball 234, one end of the float ball 234 is provided with a float 235; The locking device 300 provided adjacent to the impeller 210 captures the rising signal of the sub-ball 235 to release the locked impeller 210, and after the release, the impeller 210 rotates a predetermined angle again. Redeem and lock (220); The lock device 300, The blow rod 320 rising by the buoy 235, A first gear 340 provided with the hit rod 330 hit by the hit rod 320; A second gear 350 provided to be engaged with a lower portion of the first gear 340; Chlorine automatic dosing device, characterized in that it comprises an operating lever 360 connected to the second gear 350 and configured to rotate with the second gear 350 and to support the lower portion of the water tank 232. . delete The method of claim 2, The first gear 340 is provided with a stopper 370, The stopper 370 is in contact with the support 371, the automatic chlorine injection device, characterized in that for setting the counterclockwise rotation (reference to Fig. 6) of the first gear (340). The method of claim 2, When the float 235 rises due to the water level increase, the blow rod 320 rises, The hitting rod 320 hits the hit rod 330, The hit rod 330 rotates the first gear 340 in a clockwise direction, When the first gear 340 is rotated in the clockwise direction, the second gear 350 is rotated in the counterclockwise direction to rotate the operating lever 360 in the counterclockwise direction, even if the water level increases due to the operating lever Chlorine automatic dosing device, characterized in that the water tank 232 was stopped by (360) 1/4 turn. The method of claim 2, The non-power level controller 100, A discharge pipe 10 branching from the supply pipe 5 and discharging excess water; A valve (20) provided inside the discharge pipe (10) for opening and closing the discharge pipe (10), and opening and closing by rotating the operating shaft (22); An extension of the shape extending while inclining outwardly from the first operation period 31, the second operation period 32 bent from the first operation period 31, and the second operation period 32; An operation rod 30 including a rod 34 and a boundary portion 33 of the first operation 31 and the second operation 32 coupled to the operation shaft 22; A first weight weight 42 and a restoring portion 40 installed at an end of the extension rod 34 of the operation period 30; The first operation section 31 is provided on one side of the discharge pipe 10 based on the operation shaft 22 to grip the first operation section 31, and when the water in the water tank reaches the upper limit level, the first operation section 31 is provided. A first holding part (50) comprising a support (51) fixed to the discharge pipe (10) and a hook (53) rotatably connected to the support (51); An upper limit control section 60 for transmitting an upper limit water level ((L-upper limit)) signal to the hooking port 53 of the first holding part 50 and connected to the first holding part 50; The second operating interval 32 is provided on the discharge pipe 10 on the opposite side of the first gripper 50 on the basis of the operation shaft 22 to grip the water, and the water in the water tank has a lower limit level (L−). Lower end) when the operation between the operation 32 is terminated, and the second support (71) fixed to the discharge pipe 10 and the second hook (22) rotatably connected to the second support (71) A gripping portion 70 made of 73; One side is connected to the reverse line 81 connected to the second hanger 73, and the lower hook (L-lower limit) information connected to the lower end of the reverse line 81 through the reverse line 81 to the second hook ( 73) and the lower limit control portion 80 is provided with a weight portion 82; automatic chlorine injection device characterized in that it comprises a. In the non-power level controller 100 of claim 6, The first gripping portion 50 is fixed to the discharge pipe 10 by welding and the support groove 51 is formed with the insertion groove 51a between the lower operation, and the upper side of one side is fastened to the support 51 and the Including a hook (53) rotatable relative to the support (51), The hook mechanism 53 includes a lower taper portion 56 extending from the lower side of the hook body 54, an upper extension portion 55 extending from the upper side of the hook body 54, and the lower taper portion. Chlorine injection device characterized in that it comprises a 56 and the gripping groove (57) formed by the upper extension (55). delete delete delete

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