KR101161021B1 - Apparatus for supplying medicines automatically without sources of electricity - Google Patents

Abstract

Disclosed is a non-powered automatic drug supply device for supplying a chemical into the intake tank by receiving the rotational force generated by the rotation of the aberration by the water supplied. The tank receives the water flowing through the water pipe and supplies it to the water wheel. The drug exhaustion sensor detects whether the drug supply is exhausted. Intake tank discharge valve is installed in the water tank, based on the information detected from the drug exhaustion detection sensor, the drug is opened in the exhausted state, it is controlled not to be supplied to the water tank by bypassing the water flowing into the water intake tank. Accordingly, damage due to unnecessary operation of the medicine supply unit in the state that the medicine is exhausted can be prevented.

Description

Apparatus for supplying medicines automatically without sources of electricity}

The present invention relates to an automatic drug supply device, and more particularly, to a non-powered automatic drug supply device used to automatically supply a drug such as disinfectant in a liver abnormal water supply facilities without power.

Normally, the islands are operated in islands and valleys where water supply is not available. In the case of the Gansang water supply, a water intake tank is installed at a high place such as a mountain slope, and ground water or valley water is pumped up and stored in the water intake tank, and water is supplied to every house.

Such abnormal water supply is to be managed by local governments. However, it is difficult to manage all the abnormal water supply in the area with a limited manpower, so a part of it is delegated to a village representative or director who does not have expertise. In this case, lack of expertise may result in poor water quality management. In addition, if the interstitial water supply facility is installed in a mountainous remote area, it may be difficult to manage the water quality because the manager is not easy to access.

Due to the above-mentioned reasons, the automatic supply device for medicines may be installed in the liver water supply facilities. The automatic medicine supplying device automatically sterilizes a medicine, for example, a disinfectant, by supplying water to the water intake tank from the chemical supply unit at regular intervals.

By the way, the conventional chemical | medical agent automatic supply apparatus operated unnecessarily even if the chemical | medical agent was exhausted in the chemical | medical agent supply part. As a result, when the chemical supply unit is driven by the power source, there is a waste of power. In addition, when the chemical supply unit presses the flexible tube to transfer the chemical, there is a problem that the flexible tube is damaged by friction in the flexible tube.

On the other hand, when the valley water is always introduced into the intake tank, the water level of the intake tank exceeds the full water level, the water of the intake tank was discharged out through the over pipe. The water discharged to the outside of the intake tank is mixed with the drug, there was a problem that the drug was wasted.

An object of the present invention is to solve the above problems, to provide a non-powered automatic drug supply device that can prevent damage due to unnecessary operation of the drug supply unit in the state that the drug is exhausted, eliminating the waste of the drug.

The automatic power supply drug supply device according to the present invention for achieving the above object is to supply the chemical into the water intake tank receives the rotational force generated while the water wheel is rotated by the supplied water to supply the medicine into the intake tank, A water tank which receives water and supplies the water to the aberration; A drug exhaustion sensor for detecting whether the drug supply part is exhausted; And a water intake installed in the water tank and controlled based on the information detected from the drug exhaustion detection sensor, opened in a state in which the medicine is exhausted, and bypassing the water flowing into the water tank into the water intake tank so as not to be supplied to the aberration. And a valve for discharging the tank.

According to the present invention, in a state in which the chemicals are exhausted, water is not supplied by aberration, so that damage due to unnecessary operation of the chemicals supply part can be prevented.

According to the present invention, since the water of the intake tank is not discharged out, the medicine supplied to the intake tank may not be wasted. In addition, the water discharged by detouring from the tank to the outside of the intake tank is not mixed with the chemical, it can be used as agricultural water.

According to the present invention, since the medicine is automatically supplied into the water intake tank using hydraulic power, a power source such as a battery or a solar cell may not be used. And, by using a magnetic force to stop or rotate the aberration in a non-contact manner, the structure can be simplified, there is no mechanical wear parts.

According to the present invention, by adjusting the flow rate of water dispensed by the aberration, the rotation speed of the aberration can be adjusted. Therefore, the concentration of the chemical to the water supplied into the intake tank can be variably adjusted without the multi-stage transmission.

According to the present invention, since the pressure of the water flowing into the water tank may be dispersed by the decompression wall in the water tank, the water surface may be calm, and thus the water supplied by the water wheel may be quantitatively metered. Accordingly, the drug supply of the medicine supply can be supplied in a fixed amount into the water intake tank.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a side cross-sectional view illustrating an example of an automatic power supplyless chemical supply device according to an embodiment of the present invention installed in a water intake tank, and FIG. 2 is a perspective view illustrating an automatic power supplyless chemical supply device of FIG. 1. 3 is an exploded perspective view of FIG. 2, and FIG. 4 is a side cross-sectional view of FIG. 2.

1 to 4, the non-powered automatic drug supply device 100, the drug supply unit 120 receives the rotational force generated while the water wheel 110 rotates by the water supplied into the intake tank 10. Supplying the medicine, it comprises a water tank 130, the drug exhaustion sensor 121, and the intake tank discharge valve 140.

The aberration 130 is rotatably installed in the water intake tank 10. The intake tank 10 receives ground water or valley water through a water pipe and stores the water, and then the stored water can be supplied to each house. The medicine supplied by the medicine supply unit 120 may be a disinfectant for disinfecting water. As another example, the aberration 110 may be installed in an outdoor box outside the intake tank 10. Hereinafter, the description that the aberration 110 is installed in the intake tank 10 is exemplary, and is not necessarily limited thereto.

Water tank 130 is for receiving the water flowing through the water pipe to supply to the aberration (110). The drug exhaustion detection sensor 121 is for detecting whether the drug is exhausted stored in the drug supply unit 120. Drug exhaustion sensor 121 may be installed in the medicine barrel (122). In this case, the drug exhaustion detection sensor 121 may detect the level of the drug stored in the drug container 122, and may detect whether the drug is exhausted.

Intake tank discharge valve 140 is installed in the water tank (130). The intake tank discharge valve 140 may be installed to open and close the intake tank discharge hole 131a of the water tank 130 by the first valve driver 141. As the first valve driving unit 141, a conventional actuator may be used in a category capable of opening and closing the intake tank discharge valve 140.

The intake tank discharge hole 131a is not shown, but is connected to the intake tank 10 by the intake tank discharge bypass, or is directly connected to the intake tank 10, the water flowing into the water tank 130 Bypass to the intake tank 10 so that it is not supplied to the aberration (110). The intake tank discharge hole 131a may be formed at the bottom of the water tank 130.

The first valve driver 141 may be controlled by the controller 101. The controller 101 receives the information detected by the drug exhaustion sensor 121. If it is determined that the medicine is exhausted, the control unit 101 controls the first valve driving unit 141 to open the intake tank discharge valve 140 from a state in which the intake tank discharge hole 131a is closed. When the intake tank discharge hole 131a is opened, the water flowing into the water tank 130 is not supplied to the aberration 110 but is bypassed and discharged to the intake tank 10 through the intake tank discharge hole 131a. .

In such a state that the drug is exhausted, the water is not supplied to the aberration 110, the rotational force of the aberration 110 may not be transmitted to the chemical supply unit 120. Therefore, when the drug supply unit 120 transfers the drug using the flexible tube 123, as in the example described below, the softness according to the friction in the flexible tube 123 in the process of transferring the drug from the flexible tube 123 Damage to the tube 123 can be prevented.

If the medicine is replenished, the controller 101 controls the first valve driving unit 141 so that the water tank discharge valve 140 closes the water tank discharge hole 131a. Accordingly, the water flowing into the water tank 130 may be supplied to the aberration 110, and the medicine may be supplied from the chemical supply unit 120 to the intake tank 10.

On the other hand, when the valley water is constantly introduced into the water tank 130 through the water pipe, the water level of the intake tank 10 exceeds the full water level, the water in the intake tank 10 through the over pipe (not shown), etc. Emissions from outside may occur. The water discharged to the outside of the intake tank 10 is mixed with the drug, there may be a problem that the drug is wasted.

To prevent this, the water intake tank 10 is provided with a water level sensor 102 for detecting whether the water level of the water intake tank 10 is full water level, the water tank 130 is provided with an external discharge valve 150 Can be. The external discharge valve 150 may be installed to open and close the external discharge hole 131b of the water tank 130 by the second valve driver 151.

The external discharge hole 131b is not shown, but is connected to the overpipe by an external discharge bypass pipe, and bypasses the water flowing into the water tank 130 to the outside of the intake tank 10 to take the intake tank 10. Do not let the water level exceed the full water level. The external discharge hole 131b may be formed at the bottom of the water tank 130.

The second valve driver 151 may be controlled by the controller 101. The controller 101 is provided with the information detected from the water level sensor 102. If it is determined that the water level of the water intake tank 10 is full, the control unit 101 controls the second valve driving unit 151 to open the external discharge valve 150 from the closed state of the external discharge hole 131b. do. When the external discharge hole 131b is opened, the water flowing into the water tank 130 is bypassed and discharged to the outside of the intake tank 10 through the external discharge hole 131b, whereby the water level of the intake tank 10 is increased. May not exceed the full water level.

Therefore, since the water in the intake tank 10 is not discharged out, the chemical supplied to the intake tank 10 may not be wasted. In addition, the water discharged to the outside of the intake tank 10 through the external discharge hole (131b) is not mixed with the chemical, it can be used as agricultural water.

The water tank 130 may receive water introduced through the water pipe, and guide the water received directly to the aberration 110 and the intake tank 10, respectively. The aberration supply hole 131c is formed in the water tank 130 so that water may be supplied to the aberration 110.

The water tank 130 may be provided with a flow distribution controller 160. 5 and 6 together, the flow distribution controller 160 directly transfers a part of the total water received in the water tank 130 to the water wheel 110 through the water supply hole 131c, while the remaining water is aberration. Distribute so that it is sent directly to the intake tank (10) without passing through (110).

The flow rate distribution controller 160 adjusts the chemical concentration of the water intake in the intake tank 10 by adjusting the flow rate of the water distributed in the aberration 110 with respect to the flow rate of the water distributed in the intake tank 10. To be adjustable.

That is, the water supplied to the aberration 110 acts to supply the medicine to the intake tank 10 from the chemical supply unit 120, and the intake tank from the chemical supply unit 120 according to the amount of water supplied to the aberration 110 The amount of drug supplied to (10) is variable. Therefore, when the flow rate of the water distributed in the aberration 110 is adjusted, the chemical concentration in the intake tank 10 can be adjusted.

The flow distribution regulator 160 may include a fixed partition 161, a movable partition 162, and a dial lever 163. The fixed partition 161 is fixed to the aberration 110 such that a part of the water flowing into the water tank 130 is guided toward the aberration supply hole 131c. The fixed partition 161 has a structure bent at 90 degrees, and may be positioned outside the aberration supply hole 131c.

The movable partition 162 adjusts the open area of the aberration supply hole 131c as it moves so as to be close to or spaced apart from the fixed partition 161. The movable partition 162 is positioned parallel to one side of the fixed partition 161, and one end thereof may be sealed by the other side of the fixed partition 161 and the sealing member.

Accordingly, the movable partition 162 is operated with respect to the fixed partition 161 in a state where only the water flowing in the space separated from the fixed partition 161 is opened, thereby allowing the water to flow into the aberration supply hole 131c. Both may be guided and supplied to the aberration 110. In addition, the fixed partition 161 and the movable partition 162 to pre-distribute the water flowing into the water tank 130 to measure the water supplied to the aberration 110, so that accurate metering is made of water to the aberration 110 Can be supplied.

The dial lever 163 is for adjusting the movable distance of the movable partition 162. The dial lever 163 may be screwed to the movable partition 162 through the fixed partition 161 from the outside of the water tank 130. As the dial lever 163 rotates forward and reverse, the movable partition 162 may move to be close to or spaced from the fixed partition 161.

Ruler 164 may be provided so that the user can accurately adjust the amount of the chemical supply according to the flow rate of the water supplied to the aberration 110 while the user visually checks. The ruler 164 may be installed to indicate a position where the movable partition 162 is spaced from the fixed partition 161 in the flow distribution regulator 160.

The scale of the ruler 164 supplies water to the aberration 110 by the flow rate of the total water which combined the water supplied to the intake tank 10 via the aberration 110, and the water directly sent to the intake tank 10, and how much water is supplied to the aberration 110. It should be calculated that the concentration of the drug is within the set value, and can be engraved in 0.01 ppm units. Accordingly, anyone can easily adjust the concentration of the drug. As another example, the scale may be formed along the handle circumference of the dial lever 163.

If the water tank 130 is provided with a storage chamber 132 and a waterway portion 133 which will be described later, and the inclined surface 137 is formed at the boundary between the storage chamber 132 and the waterway portion 133, the fixed partition 161 And the movable partition 162 may distribute the water contained in the water tank 130 in advance to supply to the aberration 110 and the water intake tank (10).

That is, the fixed partition 161 and the movable partition 162 extend from the channel portion 133 to the length that can be drawn into the storage chamber 132 via the inclined surface 137. Accordingly, when water flows into the water passage part 133 while the water is filled in the storage chamber 132, water may be guided in advance by the fixed partition 161 and the movable partition 162 from the beginning of the inclined surface 137. As such, water can be accurately distributed to the aberration 110.

As such, when the amount of water distributed to the aberration 110 is adjusted, under the same conditions as the amount of water discharged into the intake tank 10, the rotation speed of the aberration 110 can be adjusted. Accordingly, the concentration of the drug to the water supplied into the water intake tank 10 can be variably adjusted. Therefore, it is not necessary to be provided with a multi-stage transmission to adjust the concentration of the drug, it can be simplified in structure. In addition, it may be applicable to take the groundwater with a high water pressure, or the valley water with a low water pressure or a small amount.

In addition, since only a part of the total water flowing into the water tank 130 is distributed and supplied to the aberration 110, the size of the aberration 110 may be reduced as compared with supplying the entire water to the aberration 110. In addition, in measuring the water supplied to the aberration 110, more accurate metering can be made because there is less water to meter. Accordingly, the drug supply can be made in a quantitative manner.

In addition, the water tank 130 may include a storage chamber 132, a water channel unit 133, and a compartment 134. The receiving chamber 132 is formed with a water inlet 131d through which water is introduced from the water pipe at the bottom, and the water flowing through the water inlet 131d is filled. The water intake tank discharge hole 131a and the external discharge hole 131b may be formed at both sides of the water inlet 131d.

The water supply portion 133 has a water supply hole 131c formed at a bottom thereof, and when the water level of the accommodation chamber 132 is higher than the bottom height of the water passage portion 133, the water in the accommodation chamber 132 is supplied with the water supply hole for the aberration. It extends horizontally from the accommodation chamber 132 to flow toward 131c and the water intake tank 10. A damping part supply hole 131e may be formed at a bottom of the water channel part 133 to supply a portion of the water directly sent to the water intake tank 10 to the rotary damping part 176 which will be described later. The water channel 133 may be inclined downward toward the intake tank 10 to guide water flowing along the water channel 133 to naturally fall into the water intake tank 10. The storage chamber 132 and the channel part 133 can also be covered by a cover.

The compartment 134 forms a separate space surrounding the area including the water inlet 131d in the accommodation chamber 132. Compartment 134 may be composed of a pressure reducing wall 135 and a top plate 136. The pressure reducing wall 135 is disposed in the storage chamber 132 in a state in which it is disposed in the direction of the central axis of rotation of the aberration 110, and both ends and the lower end thereof are fixed to the inner wall and the bottom of the storage chamber 132 by a bracket. Can be. The top plate 136 is bent from the pressure reducing wall 135 to cover the upper region of the compartment 134 and fixed to the inner wall of the receiving chamber 132. The upper plate 136 may be positioned lower than the bottom of the water channel 133.

The pressure reducing wall 135 has a plurality of through holes 135a formed at the lower side thereof. The through holes 135a allow the water introduced into the compartment 134 through the water inlet 131d to be discharged into the accommodation chamber 132 outside the compartment 134. The decompression wall 135 allows the pressure to be dispersed as the incoming water collides when water is introduced from the water inlet 131d. The water dispersed in the pressure by the decompression wall 135 exits through the through holes 135a of the decompression wall 135 into the storage chamber 132 outside the compartment 134, further reducing the swelling of the water and further dispersing the pressure. .

In this state, when the water fills the storage chamber 132, the water surface may be calm. When the remaining water is supplied to the aberration 110, the water can be quantitatively metered, rather than being supplied to the aberration 110, so that the chemicals can also be supplied to the intake tank 10 in a quantitative manner. Will be.

An inclined surface 137 may be formed at a boundary portion at which water flows from the accommodation chamber 132 to the water channel 133. The inclined surface 137 may have a form inclined toward the waterway portion 133 so that water in the accommodation chamber 132 smoothly flows into the waterway portion 133.

As shown in FIG. 7 and FIG. 8, the aberration 110 may be installed in the intake tank 10 to be rotatable continuously in one direction. For example, the aberration 110 may protrude from the rotation shafts 111 at both sides, and the rotation shafts 111 may be rotatably supported by the support frame 103. In addition, the support frame 103 may be fixed to the intake tank 10. A bearing for smoothly rotating the aberration 110 may be installed on at least one of the rotation shafts 111 of the aberration 110.

The aberration 110 has a plurality of metering bins 112 arranged along the direction of rotation. The dike barrels 112 are each formed in the same shape, and are arranged at regular intervals along the rotation center axis of the aberration 110. For example, the measuring barrels 112 may be formed by fixing the wing portions 113 at regular intervals around the central axis of rotation, and the discs 114 fixed to both sides of the wing portions 113. The wing parts 113 may be formed in a bent structure to define a space capable of holding water, respectively, in the state in which the discs 114 are fixed at both sides.

Since the aberration 110 may automatically supply the medicine into the intake tank 10 by using the rotational force generated while rotating by hydraulic power, a power source such as a battery or a solar cell may not be used to supply the medicine. Thus, unlike the battery used, there is no need to charge or replace the battery when the battery is discharged. In addition, unlike solar cells are used, it is possible to supply the medicine smoothly without being affected by environmental factors such as lack of sunshine in the rainy season or snow in winter.

The aberration 110 may repeat the rotation and stop operation by the aberration stop unit 170. The aberration stop unit 170 keeps the aberration 110 substantially stopped by magnetic force until one of the weighing vessels 112 has a predetermined amount of water, and if it exceeds the set amount, the weight of the contained water As a result, the aberration 110 rotates to discharge the water.

That is, the aberration stop unit 170 maintains the state in which the aberration 110 is stopped by magnetic force when all the measuring barrels 112 are empty. In this state, water is contained in any one of the metering bins 112. At this time, the aberration stop unit 170 maintains the stopped state of the aberration 110 until the amount of water contained in the metering bin 112 reaches a set amount.

As the water contained in the weighing container 112 exceeds the set amount and the weight of the water is greater than the magnetic force, the aberration 110 is rotated, and the water contained in the weighing container 112 is inverted accordingly. The water intake tank 10 is discharged by a set amount. When the water is completely discharged from the metering bin 112, the aberration 110 is stopped again by the magnetic force.

Subsequent processes are the same as the above-described process, so that water may be discharged by a set amount into the intake tank 10. That is, the aberration stop 170 is to be able to accurately measure the amount of water contained in the metering bin (112). The set amount of water is a portion that is set according to the set concentration of the chemical with respect to the amount of water supplied into the intake tank (10).

The aberration stop 170 may stop or rotate the aberration 110 in a non-contact manner by using magnetic force, thereby eliminating mechanical wear. Therefore, durability can be sufficiently secured even for long term use.

For example, the aberration stop 170 may include a first magnet 171 and a plurality of second magnets 173. The first magnet 171 may be installed in the support frame 101 supporting the rotation of the aberration 110. In addition, the plurality of second magnets 173 may be radially installed to correspond to the aberration 110, for example, the disc 114, one for each of the weighing bins 112. Here, the second magnets 173 are respectively installed so as to face different types of poles so that the attraction force with the first magnet 171 is generated in the state in which the measuring barrels 112 are sequentially moved toward the first magnet 171. .

Two first magnets 171 may be provided, one to each of the support frames 101 that support rotation on both sides of the aberration 110. Correspondingly, two second magnets 173 may be installed at each side of the weighing container 112, one at each side of the weighing container 112. Accordingly, by pulling both sides of the aberration 110 with the same force in a state where the aberration 110 is stopped, the aberration 110 can maintain a balanced posture without biasing to one side.

In addition, the first magnet 171 may be installed to adjust the distance from the second magnet 173. For example, the first magnet 171 may be fixed to the screw adjustment lever 172. Here, the screw adjustment lever 172 may be screwed to the support frame 101 so that the first magnet 171 is close to or spaced apart from the second magnet 173 according to the rotation direction.

As the distance between the first magnet 171 and the second magnet 173 gets closer, the magnetic force increases, and the further the magnetic force decreases as the distance increases. Therefore, according to the adjustment of the distance between the first magnet 171 and the second magnet 173, the amount of water to be metered by the metering can 112 can be adjusted.

As another example, the aberration 110 may be made of a metal material in which a portion corresponding to the first magnet 171 may adhere to the magnetic force. For example, the discs 114 provided on both sides of the aberration 110 may be made of a metal material that can adhere to the magnetic force.

The rotational force of the aberration 110 may be attenuated by the rotational force damping unit 176. Referring to FIG. 7 together with FIG. 4, the rotation force damping unit 176 contains water so that the aberration 110 may be partially locked, and attenuates the rotational force of the aberration 110 by the resistance of the water, thereby causing the aberration 110 by magnetic force. In the process of stopping), make sure to stop exactly at the next stop position. Accordingly, when the medicine supply unit 120 supplies the medicine to the intake tank 10 by the rotational force of the aberration 110, it is possible to supply to the intake tank 10 in a fixed amount.

In order to increase the damping effect by the rotation damping unit 176, a bent portion 113a may be formed at the end of the wing 113 of the aberration 110. Rotation force damping unit 176 is supplied to the water discharged from the measuring tank 112, or a portion of the water directly sent to the intake tank 10 is also supplied through the supply hole for the damping portion 131e formed in the bottom of the water channel portion 133 I can receive it.

The chemical supply unit 120 is configured to accurately supply chemicals in proportion to the rotational speed of the aberration 110, that is, the amount of water supplied into the intake tank 10. For example, as illustrated in FIGS. 8 and 9, the chemical supply unit 120 may include a pump casing 124, a roller support plate 125, a pump shaft 126, and a plurality of pressure rollers 127. It can be configured to include. The pump casing 124 has an inner space, and the inlet 124a may be formed at one side.

A flexible tube 123 is disposed in the pump casing 124. Here, the flexible tube 123 may be installed to enter through the inlet 124a of the pump casing 124, wound along the inner surface of the pump casing 124, and then exit through the inlet 124a of the pump casing 124. have. The flexible tube 123 is introduced into the intake tank 10 through the inlet 123a and the chemical is introduced from the chemical storage container 122 through the discharge unit 123b.

The roller support plate 125 is for supporting the pressure rollers 127 and is accommodated in the pump casing 124. The roller support plate 125 may be formed in a triangular plate shape, and the pressure rollers 127 may be installed at vertex portions of the flexible tube 123, respectively. The pump shaft 126 is coupled to the rotation shaft 111 of the aberration 110 to receive the rotational force of the aberration 110, thereby rotating the roller support plate 125.

The plurality of pressure rollers 127 are installed at the vertex portion of the roller support plate 125 and are arranged radially. When the roller support plate 125 is rotated by the pump shaft 126, the pressure rollers 127 push the chemical in the flexible tube 123 toward the discharge part 123b while pressing the flexible tube 123 to discharge the discharge part 123b. Through) allows to discharge into the intake tank (10). Therefore, the chemicals can be accurately supplied into the water intake tank 10 in proportion to the rotational speed of the aberration 110.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

1 is a side cross-sectional view showing an example of a non-powered automatic drug supply device according to an embodiment of the present invention installed in the intake tank.

Figure 2 is a perspective view showing an extract of the automatic power supply drug supply of FIG.

3 is an exploded perspective view of FIG. 2;

4 is a side cross-sectional view of FIG. 2.

FIG. 5 is a plan view of the flow distribution regulator of FIG. 2; FIG.

6 is a perspective view for explaining a process in which water is distributed in the flow distribution controller of FIG.

FIG. 7 is an exploded perspective view showing a configuration and installation example of aberration in FIG. 2; FIG.

8 is a plan sectional view of the aberration and the medicine supply unit in FIG.

FIG. 9 is a front sectional view of the medicine supply unit of FIG. 8. FIG.

<Brief description of the major symbols in the drawings>

102. Water level sensor 110. Aberration

120. Chemical supply 121. Chemical exhaust sensor

130..water tank 135..decompression wall

140 .. Intake valve discharge valve 150 .. External discharge valve

160..Flow distribution regulator 170..Aberration stop

Claims (5)

The chemical supply unit receives the rotational force generated when the aberration rotates by the water supplied, and supplies the chemical into the intake tank. A water tank receiving water introduced through a water pipe and supplied to the aberration, and having a water tank discharge hole communicating with the water tank; A drug exhaustion sensor for detecting whether the drug supply part is exhausted; A water intake tank discharge valve installed to open and close the water intake tank discharge hole of the water tank; A first valve driving unit which opens and closes the intake tank discharge valve; And If it is determined that the medicine is exhausted based on the information detected from the drug exhaustion detection sensor, by controlling the first valve drive unit to open the water intake tank discharge hole by the water intake tank discharge valve, A control unit to prevent the water flowing into the intake tank from being supplied to the aberration; Non-powered drug automatic supply comprising a. The method of claim 1, A water level sensor for detecting whether the water level of the intake tank is full level; And On the basis of the information detected from the water level sensor, the water level is opened in the state of full water level, the external discharge valve is controlled so that the water flowing into the water tank to the outside of the intake tank is controlled so that the water level does not exceed the full water level. Non-powered drug automatic supply device comprising a. The method according to claim 1 or 2, The tank, A portion of the entire water received through the water pipe is directly sent to the aberration through the aberration supply hole, and the remaining water is directly distributed to the intake tank without passing the aberration; Opening of the water supply hole for adjusting the flow rate of the water to be distributed to the aberration, the fixed partition fixed to the aberration so that the water is guided toward the aberration supply hole, and to move closer to or spaced from the fixed partition. And a flow distribution regulator having a movable partition for adjusting an area and a dial lever for adjusting a movable distance of the movable partition. The method of claim 3, The tank, A water inlet formed at a bottom of the water inlet through which the water flows in, and the water inflowing through the water inlet is filled; A water supply portion formed at a bottom of the aberration supply hole, and extending horizontally from the accommodation chamber so that water in the accommodation chamber flows toward the aberration supply hole and the water intake tank; And A compartment having a decompression wall having a plurality of through holes formed at a lower side thereof to form a separate space surrounding the area including the water inlet, and to disperse the pressure of the water flowing from the water inlet to be discharged out of the space; Include, The non-powered chemical automatic supply device, characterized in that the inclined surface is formed so that the water flows smoothly in the boundary portion that the water flows from the storage chamber to the waterway portion. The method according to claim 1 or 2, The aberration is rotatably installed in one direction in the intake tank, and has a plurality of metering barrels arranged along the rotational direction; The aberration is substantially stopped by magnetic force until the water supplied to the aberration is contained in one of the weighing barrels by a set amount, and when the amount exceeds the set amount, the aberration is rotated by the weight of the contained water. Automatic supply apparatus for a non-powered drug, characterized in that it comprises an aberration stop for discharging water into the intake tank.

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