KR20020069978A - Apparatus for supplying water to flower port - Google Patents

Abstract

PURPOSE: Provided is an apparatus for supplying water to flower pot, which has various shapes such as rocks, mountain, a water mill and the like, and is mounted on the flower pot to gives good decoration effect. CONSTITUTION: The apparatus for supplying water to a flower pot comprises a case containing water thereinside, an air inlet to give atmospheric pressure to the surface of water contained in the case, a water outlet which discharges water contained in the case quantitatively by the atmospheric pressure.

Description

Pollen water supply device {APPARATUS FOR SUPPLYING WATER TO FLOWER PORT}

The present invention relates to a pollen moisture supply device, and more particularly, to a pollen moisture supply device capable of supplying moisture in a continuous quantity to a pot by storing water and spraying by a predetermined amount.

As society becomes more and more informational, various attempts have been made to decorate the declining indoor atmosphere into a more human and environmentally friendly atmosphere. Growing flowers indoors is one of these attempts. Today, most homes and offices grow plants by pots for ornamental or health purposes. In addition, the flower garden is cultivated on a large scale by a large amount of pollen. Therefore, the demand for pollen is rapidly increasing, and managing it has emerged as an important problem.

In the case of flowers, water must be supplied at regular intervals to benefit the growth of flowers. Of course, depending on the type of flower, some flowers need to supply a large amount of water, and vice versa.

However, continually supplying water to plants is a difficult task in reality. In particular, when going to play in the family unit during the holiday season, it is difficult to moisturize the flowers. Of course, it is possible to go to play with a lot of moisture at once, even in this case there is a problem that the flower is damaged due to a large amount of moisture.

In particular, in the case of a flower garden with a large pot, it is more difficult to periodically supply water to each flower.

Therefore, the present invention has been made to solve the above-mentioned problems, the object of the present invention is to supply water to the flowers by continuously supplying moisture to the flowers by storing water and ejecting by a predetermined amount to supply the moisture of the flowers that can be supplied even when there is no manager To provide a device.

In addition, another object of the present invention is to provide a water supply device of a stylish flower design by manufacturing the appearance of the water supply device in a model having the shape of rock, mountain, watermill, and the like.

1 is a perspective view showing that the pollen pollination device according to a preferred embodiment of the present invention is placed in a pot.

Figure 2 is a side view of the pollen moisture supply device shown in FIG.

Figure 3 is an enlarged side cross-sectional view showing a preferred embodiment of the pollen moisture supply device shown in FIG.

Figure 4 is a bottom view showing the bottom of the pollen moisture supply device shown in FIG.

Figure 5 is a side cross-sectional view showing another preferred embodiment of the pollen moisture supply device shown in FIG.

Figure 6 is a bottom view showing the bottom of the pollen moisture supply device shown in FIG.

Figure 7 is a side cross-sectional view showing another preferred embodiment of the pollen moisture supply device shown in FIG.

Figure 8 is a bottom view showing the bottom of the pollen moisture supply device shown in FIG.

Figure 9 is a side cross-sectional view showing another preferred embodiment of the pollen moisture supply device shown in FIG.

Figure 10 is an enlarged cross-sectional view showing another preferred embodiment of the pollen moisture supply device shown in FIG.

FIG. 11 is an enlarged view showing a portion "A" of the pollen water supply device shown in FIG.

12 is an enlarged cross-sectional view showing another preferred embodiment of the pollen moisture supply device shown in FIG.

Figure 13 is an enlarged cross-sectional view showing another preferred embodiment of the pollen moisture supply device shown in FIG.

14 is an enlarged cross-sectional view showing another preferred embodiment of the pollen moisture supply device shown in FIG.

In order to realize the object of the present invention, the present invention is to determine the case in which the water is stored therein, the air inlet port for the atmospheric pressure to act on the surface of the water contained in the case, and the water stored in the case by the atmospheric pressure And outlets for supplying the pots by outflow. Such a water supply device is manufactured in a model having a variety of shapes, such as rock, gravel, mountain, watermill, and can be used on a flowerpot to produce a sophisticated atmosphere in design.

Hereinafter, with reference to the accompanying drawings will be described in more detail the moisture supply device of a pot according to an embodiment of the present invention.

1 is a perspective view showing that the pollen moisture supply device according to a preferred embodiment of the present invention is placed in a pot, and FIG. 2 is a side view of the pollen moisture supply device shown in FIG. 1.

As shown, the pollen pollination device 10 proposed by the present invention has a predetermined size and shape and is placed on the pollen 1 to supply moisture to the pollen 1. The external appearance of the pollen moisture supply device 10 is manufactured in various shapes, such as rocks, mountains, watermills, balls, and the size thereof has a size that can be placed on the pot. Of course, if the shape can be modeled in addition to the above shape is included. The outlet through which water flows out is formed to protrude in the lower portion of the pollen moisture supply device 10 to supply moisture to the soil 3 stored in the pollen 1.

Figure 3 shows one preferred embodiment of such a pollen moisture supply device. As shown, the pollen moisture supply device 10 has a predetermined shape such as a rock and a space is formed therein, the case 11 having water stored therein, and mounted at a lower portion of the case 11 and therein. Outflow means 12 for supplying to the pot by supplying the stored water to the outside by pressurizing the stored water by the atmospheric pressure, and an air passage 13 that serves as a passage of air introduced through the outlet means (12).

The case 11 is visually diversified by wearing an appropriate color. That is, in the case of the rock shape, the corresponding color is applied, and in the case of the mountain shape, the corresponding color is further increased to enhance the visual effect. Then, the transparent portion 27 is formed on one side of the case 11 so that the level of water stored therein can be known. If necessary, the water level of the water can be known more effectively by displaying a scale on the transparent portion 27. This case can be manufactured by the well-known blow molding method.

The outlet means 12 is supplied to the potted plant 1 by quantitatively outflowing the water stored in the case (11). Therefore, the user adjusts the inflow of air by appropriately adjusting the outflow means 12 to adjust the outflow of water.

The outlet means 12 is screwed to the rim 19 of the circular hole formed in the bottom of the case 11, the outer peripheral surface of the rim 19, the air inlet 21 and the water outlet 22 are respectively The cap part 18 is formed and communicates with the inside of the case, and the opening and closing member 25 is screwed to the cap part 18 to adjust the outflow amount of the water outlet 22.

In addition, the packing 20 is mounted on the inner circumferential surface of the edge portion 19 by an interference fit method to seal the space between the edge portion 19 and the cap portion 18 to prevent leakage of stored water to the outside. do.

The cap portion 18 includes a bottom portion 16, an edge portion 15 formed along the circumference of the bottom portion 16, and a protrusion portion in which the bottom portion 16 protrudes upward and bent into a predetermined shape ( 17). In addition, a screw thread is formed inside the edge portion 15 to be screwed to the screw thread formed on the edge portion 19 of the case 11. Thus, by rotating the cap portion 18 is integrally coupled to the bottom of the case (11).

Protruding portion 17 of the cap portion 18 having such a structure is formed with a through hole 29 on one side. The through-hole 29 has a wedge shape in its inner upper portion and communicates with the water outlet 22, a thread is formed on the inner circumferential surface thereof, and a space 26 having a predetermined length downward is formed on one side of the inner circumferential surface. . Therefore, the water stored in the case 11 flows out through the water outlet 22 and the space 26.

Then, the opening and closing member 25 is coupled to the cap portion 18 to adjust the amount of water outflow.

The opening and closing member 25 preferably includes a screw, the upper end 24 of the screw has a wedge shape, and the lower end 23 is formed with a head. The screw is screwed to the inner circumferential surface of the through hole 29, in which the upper end 24 of the wedge is integrally coupled to the inner upper part of the wedge of the through hole 29.

Accordingly, by rotating the opening and closing member 25 in the clockwise and counterclockwise directions, the opening and closing member 25 is moved up and down inside the through hole 29, and the upper end 24 of the wedge shape is the through hole 29. Will open and close the upper end of the wedge shape.

As a result, the water outlet 22 is opened or closed by rotating the opening / closing member 25, and the outflowed water flows out through the space 26 of the through hole 29, thereby controlling the outflow amount of the water.

In addition, an air inlet 21 is formed in the middle of the protrusion 17. The air inlet 21 has a diameter enough to allow outside air to flow therein and the air passage 13 is coupled to an upper end thereof.

The air passage 13 has a predetermined diameter and has a straw shape through which air can flow. Therefore, the outside air introduced through the air inlet 21 is collected at the upper part of the case 11 through the air passage 13. As a result, since the atmospheric pressure acts on the inside of the case 11, the stored water is pressurized downward to be discharged to the outside through the water outlet 22.

Meanwhile, numbers 28 may be imprinted on the bottom of the bottom portion 16 of the cap part 18 to facilitate the adjustment of the amount of water outflow, and arrows 27 may be formed on the bottom of the head 23 of the opening and closing member 25. ) Can be imprinted. Accordingly, as the opening / closing member 25 is rotated, the arrow 27 indicates one of the numbers 28. That is, when the opening and closing member 25 is rotated, the water outlet 22 is opened, and the degree of opening is recognized by the arrow 27 pointing to the number 28.

Thus, the user can flow the desired amount of water by rotating the opening and closing member 25 in accordance with the number (28). For example, if you want to drain only a small amount of water, set the arrow of the screw to 1, and if you want to drain more water, 2, if you want to drain the maximum amount of water in this way, By fitting to 6, you can drain the desired amount of water. Of course, this number can be increased or decreased.

In the above-described embodiment, when the water is filled in the case 11, the cap part 18 is rotated to be separated from the edge portion 19 of the case 11, and then the water is filled.

On the other hand, Figure 5 shows another preferred embodiment of the cap portion. This embodiment has the same structure as the above-described embodiment, but there is a difference in the cap portion (31). In the case of the embodiment is a method of adjusting the water outlet, in this embodiment is a method of adjusting the air inlet. That is, in the present embodiment, the through hole 33 is formed in the protruding portion 32 of the cap portion 31, and the air inlet 34 is formed in the upper end thereof. Then, the opening and closing member 35 is screwed to the through hole 33. At this time, the upper portion of the opening and closing member 35 is in the shape of a wedge, thereby controlling the amount of air introduced through the air inlet 34 by opening and closing the air inlet 34 appropriately.

On the other hand, the water outlet 36 may be one or more holes, and is formed without a separate opening and closing member at a position spaced apart from the air inlet 34 by a predetermined distance. Accordingly, water stored in the water supply device 30 can always be discharged through the water outlet 36, but since the diameter of the water outlet 36 is small, the water outlet 36 does not flow out unless proper atmospheric pressure is applied.

As a result, when external air is injected into the water supply device 30 by rotating the opening / closing member 35 of the air inlet 34, the atmospheric pressure acts, and the atmospheric pressure pressurizes the stored water, It flows out through the water outlet 36. At this time, as shown in Figure 6, the bottom surface of the cap portion 31, the number is imprinted as in the case of the embodiment, the head portion 37 of the opening and closing member 35 is also stamped with an arrow 38. . Thus, the user can adjust the water outflow amount by looking at the number indicated by the arrow 38 to recognize the air inflow amount.

On the other hand, Figure 7 shows another preferred embodiment of the present invention. The other embodiment has the same structure as the above-described embodiment, but there is a difference in the cap portion (41). That is, the other embodiments adjust the outflow amount of water or air by the screw method, in this embodiment is controlled by the valve method.

In the cap part 41 according to the present embodiment, the opening and closing member 42 is rotatably mounted in the coupling hole 47 formed in the horizontal direction in the bottom part 43 of the cap part 41. In addition, the opening and closing member 42 has a cylindrical shape, and an auxiliary outlet 44 is formed at a predetermined position, and the auxiliary outlet 44 corresponds to the water outlet 46 formed in the cap part 41. Therefore, when the user rotates the opening and closing member 42 by a predetermined angle, the auxiliary outlet 44 corresponds to the water outlet 46 so that water flows out through the auxiliary outlet 44. In addition, by adjusting the rotation angle of the opening and closing member 42, the outlet amount of the water may be adjusted by adjusting the area where the auxiliary outlet 44 and the water outlet 46 contact each other. At this time, the outside air is introduced into the interior through the air inlet 45 formed in the middle portion of the cap portion 41.

9 is shown a pollen moisture supply device according to another preferred embodiment of the present invention. As shown, the pollen moisture supply device 100 has a difference that the air inlet 102 is formed on the upper portion of the case 101 compared to the above embodiments. That is, the stopper 103 is mounted on the upper portion of the case 101, the water is introduced and stored through the stopper 103, and the air inlet 102 is formed in the stopper 103. Therefore, the outside air flows into the case 101 through the air inlet 102, so that atmospheric pressure acts on the inside of the case 101.

In addition, only the water outlet 104 is formed in the outlet means 106 mounted to the lower portion of the case 101 without the air inlet. That is, a wedge-shaped through hole 105 is formed in the middle portion 111 of the cap portion 112, and the opening and closing member 109 having a wedge-shaped upper end portion 107 is screwed into the through hole 105. The water outlet 104 is opened and closed. Therefore, when moving downwards by rotating the opening and closing member 109, the water inside the case 101 flows out through the water outlet 104 and the space 110.

At this time, in the same manner as in the above embodiment, by marking the arrow on the head portion 108 of the opening and closing member 109 and the number on the bottom surface of the middle portion 111 of the cap 112 can be adjusted the amount of water outflow. .

On the other hand, the air inlet 102, that is, the air inlet 102, as applied to the present embodiment is formed in the stopper 103, the structure in which the stopper 103 is mounted on top of the case 101 is implemented Of course, it can be selectively applied to all embodiments other than the example.

10 to 11 show a water supply apparatus according to another preferred embodiment of the present invention. As shown, the present embodiment has the same structure as the above embodiments, but there is a difference in the shape of the outlet means 51.

That is, in the present embodiment, the outlet means 51 protrudes from the bottom of the case 52, and has a protruding jaw 53 with a wedge-shaped through hole 54 formed therein, and the protruding jaw 53 It includes a cap portion 55 that is integrally coupled to the screw coupling method).

The cap portion 55 has a cylindrical shape, and the opening and closing member 57 protrudes upward from the bottom portion 56. The upper end 58 of the opening and closing member 57 has a wedge shape and is coupled to the through hole 54 of the protruding jaw 53. In addition, an auxiliary outlet 59 is formed at an adjacent position of the protruding jaw 53. Therefore, as the cap part 55 rotates, the opening / closing member 57 moves downward. At this time, the water flowing out through the water outlet 54a is the secondary outlet 59 of the cap part 55. Outflow through the outside.

When the cap part 55 is rotated in the opposite direction, the cap part 55 is moved upward, so that the upper end 58 of the opening and closing member 57 closes the water outlet 54a to prevent the outflow of water.

In this way, by adjusting the rotation of the cap portion 55 to adjust the amount of water outflow. The cap part 55 may be mounted on one or two bottoms of the water supply device 50.

In addition, a plug 91 having the same shape as the plug shown in FIG. 9 is mounted on the case 52. Accordingly, atmospheric pressure acts by introducing external air into the case 52 through the air inlet 92 formed in the stopper 91.

Meanwhile, another embodiment of the present invention is shown in FIG. That is, the water outflow using the fibrous wick member 64. Also in the present embodiment, having a water supply device 60 having the same structure as the above embodiments, there is a difference in using the wick member 64 in the outlet means (61).

That is, the outlet means 61 according to the present embodiment has a rim portion 62 protruding downward on the bottom of the case and a cap portion integrally coupled to the outer surface of the rim portion 62 by a screwing method ( 63) and a wick member 64 fixed to the cap 63 to allow water to flow out by capillary action.

In addition, the support member 65 is inserted and fixed inside the edge portion 62, and the support member 65 has a through hole 66 formed therein, and the wicking member 65 is inserted therein. . At this time, the through hole 66 corresponds to the hole (not shown) formed in the cap portion 63 so that the wick member 65 is inserted into the water supply device 60 from the inside. Therefore, the stored water flows out through the wick member 65. And, it is, of course, that one or more outlet means 61 provided with the wick member 65 can be installed.

Figure 13 shows another embodiment of a moisture supply device using such a wick. That is, the hose member 71 is installed on one side of the water supply device 70, and the fiber wick member 74 is inserted through the hose member 71.

The hose member 71 has a predetermined diameter, one end portion (71a) is located inside the case 72, the other end portion (71b) protrudes a predetermined distance to the outside of the case 72. Then, the fiber wick member 74 is inserted into the hose member 71. At this time, one end 75 of the wick member 74 is in contact with the inner bottom of the case 72, the other end 76 is preferably protruded to the outside of the hose member (71). Therefore, the stored water flows out through the wick member 74.

On the other hand, Figure 14 also shows another embodiment of a water supply apparatus using such a wick. The water supply device 80 according to the present embodiment is provided in a movable manner without being placed on the pot 81. That is, the water supply device 80 is inserted into the case 82, the hose 83 is connected to the case 82 and drawn out to the outside, the water is stored therein, A wick 84 for moving water outward.

One end 83a of the hose 83 is in contact with the inside of the case 82, and the other end 83b is positioned in the flower pot 81. Therefore, water in the case 82 flows out through the wick 84.

Unlike the water supply device shown in the above embodiments, the water supply device 80 may supply water at a predetermined distance away from the flower pot 81. That is, when the hose 83 is fixed to the desired pot 81, the water is automatically supplied.

As such, the water supply device according to a preferred embodiment of the present invention has the advantage that can be produced by designing a model having a variety of shapes, such as rock, gravel, acid, watermill, placed on a flowerpot to create a stylish atmosphere in design .

In addition, since the water can be periodically supplied to the pot in a certain amount, there is an advantage that the flower management is easy when traveling or going out.

In addition, the amount of rotation of the opening and closing member mounted on the water supply device may be recognized by the number, thereby easily controlling the amount of outflow of water.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications can be made within the scope of the claims, the detailed description of the invention, and the scope of the accompanying drawings. It goes without saying that it belongs to the scope of the present invention.

Claims (18)

And a case in which water is stored therein, an air inlet port through which atmospheric pressure acts on the surface of the water contained in the case, and an outlet port for quantitatively supplying water stored in the case by the atmospheric pressure to the flower pot. Water supply. The water supply apparatus of claim 1, wherein the case is formed by selectively modeling shapes of rocks, gravel, mountains, and the like. According to claim 1, The bottom portion of the case is separable and the cap portion is formed in the air inlet and the water outlet, respectively, the opening and closing member for opening and closing the water outlet by screwing the cap portion, and the case and the cap And a packing member inserted between the parts to prevent leakage of the stored water to the outside. According to claim 3, wherein the cap portion includes a bottom portion on which the opening and closing member is mounted, an edge portion formed along the circumference of the bottom portion, and the middle portion of the bottom portion protrudes upwards and a protrusion formed with an air inlet and a water outlet, respectively Moisture supply. The water supply apparatus of claim 4, wherein a through hole is formed at one side of the protrusion to communicate with the water outlet, and the opening and closing member is coupled to the through hole to control the amount of water outflow by opening and closing the outlet. The water supply apparatus of claim 4, wherein a through hole is formed at one side of the protrusion to communicate with the air inlet, and the opening and closing member is coupled to the through hole to control the amount of water outflow by opening and closing the air inlet. The water supply system of claim 4, wherein a through hole is formed at one side of the protrusion to communicate with the water outlet, and the opening and closing member is rotatably coupled to the bottom in a horizontal direction to control the amount of water outflow by opening and closing the through hole. Feeder. The method of claim 7, wherein the opening and closing member is cylindrical having an auxiliary outlet is formed, rotatably mounted in the coupling hole formed in the horizontal direction in the bottom portion, the water is discharged by the auxiliary outlet is in communication with the through hole during rotation Water supply. According to claim 1, wherein the outlet is a cap portion screwed to the outer peripheral surface of the rim portion of the circular hole formed in the bottom of the case, a support member inserted into the rim portion, and inserted through the support member and the cap portion And a wicking member which discharges the water stored inside the case to the outside by a capillary phenomenon. The wick member according to claim 1, wherein the outlet port is fixed to one side of the case and extends to the outside, and a wick member inserted into the hose member to discharge water stored in the case to the outside by capillary action. Moisture supply device comprising a. A case in which water is stored therein, a lake member installed to extend a predetermined length from the case to the outside, and inserted into the hose member to drain water stored inside the case by capillary action to the outside Water supply device capable of supplying water from adjacent locations. A case in which water is stored therein, an air inlet through which an atmospheric pressure acts on the surface of the water contained in the case, and a stopper formed on the surface of the case, and the water stored in the case by the atmospheric pressure A water supply device comprising an outlet for outflow and supply to the pot. The method of claim 12, wherein the outlet is protruding in the bottom of the case, a wedge-shaped through-hole is formed therein and the protruding jaw communicated with the water outlet, and integrally coupled to the protruding jaw by a screwing method And a cap part configured to control the amount of water outflow by opening and closing the through hole during vertical movement. 15. The method of claim 13, wherein the cap portion is formed in the auxiliary outlet is formed in the bottom portion, the rim portion protruding in the circumferential direction of the bottom portion screwed to the outer circumferential surface of the projection jaw, and protruding upwardly formed on the upper surface of the bottom portion Water supply device comprising an opening and closing member coupled to the through hole. A case in which water is stored therein, an air inlet through which an atmospheric pressure acts on the surface of the water contained in the case, and a stopper formed on the surface of the case, and the water stored in the case by the atmospheric pressure A water supply device comprising an outlet for outflow and supply to the pot. The cap part of claim 15, wherein the outlet port is coupled to an edge portion protruding from the bottom of the case, and a wedge-shaped through hole is formed at an intermediate portion thereof, and a water outlet is formed at an upper end portion of the through hole. A water supply device comprising an opening and closing member for opening and closing the water outlet is screwed to the through-hole of the part. 17. The method of claim 5, 6, 14, 16, wherein the opening and closing member comprises a screw threaded to the through hole, the upper portion of the wedge shape by having a wedge shape Moisture supply unit coupled to the through hole. The water supply apparatus of claim 17, wherein an arrow is imprinted on the head of the opening and closing member, and a number is also stamped on the bottom of the bottom of the cap to recognize the water flow rate.