WO2017034248A1 - Showerhead capable of using rotary tool - Google Patents

Abstract

The present invention relates to a showerhead capable of using a rotary tool and, more specifically, to a showerhead capable of rotating a rotary tool by using the hydraulic pressure of tap water. To this end, the showerhead of the present invention capable of using the rotary tool rotates a gear motor or a vane motor, mounted inside the showerhead, by the hydraulic pressure of the water flowing in from the outside, reduces speed by coupling a reduction gear to an output shaft of the motor, and increases rotational torque, thereby rotating the rotary tool connected to the end of the reduction gear. Therefore, the rotary tool connected to the showerhead rotates by using the water flowing in from the outside.

Description

Shower head with rotary tool

The present invention relates to a shower capable of using a rotary tool, and more particularly to a shower capable of rotating the rotary tool using the water pressure of tap water or industrially supplied water.

In the case of a bathroom, the inside of the bathroom is always a lot of water due to the shower, and this may cause the scale or mold, and it is necessary to periodically clean the bathroom to remove the scale or mold.

In order to clean the bathroom, there is always a brush that can be used easily in the bathroom.

In addition, in the case of using an electrically driven cleaning tool, the use of the cleaning tool in a wet bathroom is a risk of electric shock, so it is difficult to use an electrically driven general cleaning tool. Therefore, the cleaning of the bathroom is usually a hand rinsed in the scrubbing brush to clean the floor tile or bathroom, which is very uncomfortable and hygienic.

In addition, in countries with a culture that pushes the skin when taking a shower, it was very difficult and inconvenient because it was used to remove the soil using only the power of the hand, using a wheat flour towel or a milling tool with a towel formed at the end of a long rod. .

Looking at the related art related to this, the technique described in Korea Utility Model Model No. 20-0212720 as shown in Figures 1 and 2 is designed to turn the aberration (impeller) using the flow of water, that is, hydrodynamic fluid flow Since it is not a structure that can generate the rotational force desired by the user, practical rotational force cannot be obtained in a small space.

In addition, the technique described in Registration Utility Model No. 20-0212720 can be easily removed by installing a rotatable brush in the shower, it is possible to remove and wash at a time without the need to wash separately, There is a problem that the structure for rotating the brush is complicated and can be easily broken.

In detail, the shower proposed in the prior art may be partially showered using a rotatable brush, but may not provide sufficient rotational force to attach a tool to the work. That is, in order to perform a simple cleaning including the floor of the bathroom using a tool, a higher rotational torque is required than in the past. Accordingly, there is a need for the development of a multifunctional showerhead having a simple structure and providing sufficient rotational torque to perform a smooth operation.

The problem to be solved by the present invention is to propose a shower that provides a rotational force required by the user.

Another problem to be solved by the present invention is to propose a shower that provides a sufficient rotational force to perform the operation by using a rotary tool.

Another problem to be solved by the present invention is to propose a shower that can be utilized as a device for rotating a shower or rotating tool, if necessary.

Another problem to be solved by the present invention is to propose a shower that is easy to attach and detach the rotary tool.

Another problem to be solved by the present invention is to propose a shower that is easy to attach and detach the rotary tool of simple structure.

Another problem to be solved by the present invention is to propose a shower having a low cost washing function.

Another problem to be solved by the present invention is to propose a shower having a washing function having a size similar to the handle size of the existing shower.

Another problem to be solved by the present invention is to propose a shower having a washing function that can reduce wasted water.

To this end, the shower of the present invention is formed in the housing, one end of the housing, is connected to the first nozzle fastening portion to which the external first nozzle is fastened, the first nozzle fastening portion, and water from the external first nozzle An inflow pipe for inflow of water, a clockwise or counterclockwise rotation, and a pipe connection valve formed with a channel through which water flows from the water inflow pipe, and located in a length direction of the housing within the housing; A first supply pipe supplied with water from a water formed in the pipe connecting valve in a state in which the pipe connecting valve is rotated in a first direction, which is either a clockwise or counterclockwise direction, in the housing in the longitudinal direction of the housing; And the pipe connecting valve is rotated in a second direction different from the first direction, which is either a clockwise or counterclockwise direction. A second supply pipe receiving water from the water formed in the pipe connection valve in one state; a first gear positioned in the longitudinal direction of the housing inside the housing and rotating by water pressure of the water supplied to the first supply pipe; The second gear is located in the longitudinal direction of the housing within the housing, the second gear that is rotated by the water pressure of the water supplied to the first supply pipe in the state engaged with the first gear, is fastened to the end of the first gear, the first gear A first bevel gear that rotates by rotation of the second bevel gear, a second bevel gear that has a threaded line for engaging a tool at the end, and a shower member receiving water from the second supply pipe; do.

To this end, the shower of the present invention is formed in the housing, one end of the housing, the nozzle fastening portion to which the external nozzle is fastened, is connected to the nozzle fastening portion, the inlet pipe in which water is introduced from the outside, the water from the inlet pipe The inflow hole, the first outflow hole and the second outflow hole is formed is formed, the vane does not rotate when the inflow of water outflow to the first outflow hole, if the incoming water outflow to the second outflow hole A vane motor in which the vane rotates, a first outflow pipe through which water flows out from the first outflow hole, a second outflow pipe through which water flows out from the second outflow hole, and the vane fixedly coupled to the vane And a second gear fixedly fastened to the rotation shaft of the motor, and a second gear meshed with the first gear and rotating, and having a screw thread or a tool fastening groove formed at an end thereof.

The shower tool capable of combining the rotary tool according to the present invention proposes a method of rotating the combined rotary tool using water pressure of water supplied from the outside. By rotating the rotary tool using the water pressure of the water, it is possible to fundamentally block the risk of electric shock caused when using the power tool.

In addition, the present invention can increase the torque for rotating the rotary tool can perform the desired work without difficulty. In addition, by using a valve to perform the original function of the shower in normal times, there is an advantage that can be used by fastening a variety of rotary tools by fastening the rotary tool using a screw thread or a tool fastening groove.

In addition, the shower according to the present invention by using the vane motor can be a shower having a size similar to the existing shower handle, in particular, there is an advantage that the manufacturing cost is relatively cheap compared to the conventional gear motor type.

In addition, the shower tool capable of coupling the rotary tool according to the present invention can prevent unnecessary waste of water by using it for cleaning, rather than discharging the water for rotating the rotary tool to the outside. In detail, the water is conventionally required to be used separately for washing, but the present invention has the advantage of being convenient because the user does not have to carry water separately by reusing the water rotated rotating tool.

1 is a view showing the structure of a conventional shower,

2 is also a view showing the structure of a conventional shower,

3 illustrates a shower according to an embodiment of the present invention.

4 is a view illustrating a movement path of water according to rotation of a pipe connection valve according to an exemplary embodiment of the present invention.

5 is a cross-sectional view of a housing of the shower according to an embodiment of the present invention.

Figure 6 shows a rotary tool that can be mounted to use in the shower according to an embodiment of the present invention.

7 illustrates a configuration of a shower using water pressure according to another embodiment of the present invention.

8 is a view illustrating a shape of a water quantity control valve according to another embodiment of the present invention.

9 illustrates a structure of a vane motor according to another embodiment of the present invention.

10 illustrates an operation of a push switch according to another embodiment of the present invention.

11 is a view illustrating a shower from the top according to another embodiment of the present invention.

12 illustrates an example in which a shower member is mounted in a shower according to another embodiment of the present invention.

13 is a view showing an example in which a rotary tool is mounted in a shower according to another embodiment of the present invention.

The foregoing and further aspects of the present invention will become more apparent through the preferred embodiments described with reference to the accompanying drawings. Hereinafter will be described in detail to enable those skilled in the art to easily understand and reproduce through this embodiment of the present invention.

3 shows a shower using water pressure according to an embodiment of the present invention. Hereinafter, the shower using water pressure according to an embodiment of the present invention will be described in detail with reference to FIG. 3.

According to FIG. 3, the shower 100 using water pressure includes a housing 105, a first nozzle coupling part 110, a second nozzle coupling part 115, a pipe connecting valve 120, an inlet pipe 125, and 1 supply pipe 130, second supply pipe 135, outlet pipe 140, the first gear 145, the second gear 150, the first bevel gear 155, the second bevel gear 160, shower Member 165. Of course, in addition to the above-described configuration may be included in the shower proposed in the present invention. As an example, the shower of the present invention has a bearing formed in the housing in which the gear is built so that the gear can easily rotate.

The housing 105 is a main body constituting the shower, and parts constituting the shower of the present invention are mounted inside or outside. The housing 105 is composed of a bar type having a predetermined length as a whole. The housing 105 may be configured in the form of a cylinder or an ellipse column, or may be configured in various forms.

At one end of the housing 105, a first nozzle coupling part 110 and a second nozzle coupling part 115 are formed. The first nozzle fastening part 110 is fastened to an external first nozzle, and the second nozzle fastening part 115 is fastened to an external second nozzle. Of course, the first nozzle fastening part 110 may be fastened with an external first nozzle, whereas the second nozzle fastening part 115 may not be fastened with an external second nozzle. The first nozzle supplies water supplied from the outside to the first nozzle coupling part 110, and the second nozzle receives water from the second nozzle coupling part 115. Therefore, the second nozzle fastening part 115 may maintain a state in which the second nozzle fastening part 115 is not fastened to a separate second nozzle.

Inlet pipe 125 is one side is connected to the first nozzle fastening portion 110, the other side is connected to the pipe connection valve 120. That is, the water introduced into the inlet pipe 125 through the first nozzle coupling part 110 is supplied to the pipe connection valve 120.

The pipe connecting valve 120 is connected to the inlet pipe 125 and supplies water supplied from the inlet pipe 125 to one of the first supply pipe 130 and the second supply pipe 135. For example, when the pipe connecting valve 120 is rotated in the counterclockwise direction, the supplied water is supplied to the first supply pipe 130, and when the pipe connecting valve 120 is rotated in the clockwise direction, the supplied water is supplied to the second supply pipe ( 135). To this end, the pipe connection valve 120 is formed with a water channel through which water moves, and the other side of the water channel is connected to the first supply pipe 130 or the second supply pipe 135 according to the rotation of the pipe connection valve 120. do.

4 is a view illustrating a flow path of water introduced by rotation of a pipe connection valve according to an exemplary embodiment of the present invention. Hereinafter, a flow path of water introduced by rotation of a pipe connection valve according to an embodiment of the present invention will be described with reference to FIG. 4.

As described above, the water introduced by the rotation of the pipe connecting valve 120 is supplied to one of the first supply pipe 130 and the second supply pipe 135.

First, FIG. 4 (a) illustrates an example in which the introduced water is supplied to the second supply pipe 135. The water supplied to the second supply pipe 135 is supplied to the shower member 165. According to FIG. 4 (a), the pipe connecting valve 120 has a water channel for supplying water supplied from the inlet pipe 125 to one of the first supply pipe 130 and the second supply pipe 135. do. Inlet pipe 125 is a pipe connection valve 120 so that when the pipe connection valve 120 is rotated in a clockwise or counterclockwise direction, the supplied water can be supplied to the first supply pipe 130 or the second pipe 135. ) And the diameter of the part to be fastened to form relatively larger than the other parts. As a result, the water flowing into the inlet pipe 125 is transferred to the first supply pipe 130 or the second supply pipe 135 even when the pipe connecting valve 120 is rotated in the clockwise direction as well as the counterclockwise rotation. Supplied. That is, the diameter of the inlet pipe 125 is larger than that of other parts so that the diameter of the inlet pipe 125 can be connected to the inlet pipe 120 even when the channel is rotated as much as possible in consideration of the rotation angle of the channel formed in the pipe connecting valve 120. Form. According to FIG. 4A, the pipe connecting valve 120 rotates in a clockwise direction, thereby supplying the water supplied to the second supply pipe 135.

On the contrary, in FIG. 4B, the pipe connecting valve 120 is rotated by a counterclockwise angle. In this case, the channel formed in the pipe connecting valve 120 has the first supply pipe 130 or the second supply pipe 135. ), The pipe connection valve 120 is unable to supply the supplied water to the first supply pipe 130 or the second supply pipe (135).

4 (c), the channel of the pipe connecting valve 120 is connected to the first supply pipe 130, and thus, the pipe connecting valve 120 supplies the supplied water to the first supply pipe 130. Of course, the water supplied to the first supply pipe 130 flows out through the outlet pipe 140 after rotating the first gear 145 and the second gear 150 therein.

The first gear 145 and the second gear 150 are mounted in the housing 105, the first gear 145 and the second gear 150 has a predetermined length, the first gear 145 and the first gear One end of the second gear 150 is fastened to one side of the housing 105, and the other end of the first gear 145 and the second gear 150 is fastened to the other side of the housing 105. In addition, as described above, in the housing 105 to which the first gear 145 or the second gear 150 is fastened, a bearing is formed to facilitate rotation of the first gear 145 or the second gear 150. That is, a bearing is formed between the first gear 145 and the housing 105, and between the second gear 150 and the housing 105, and the first gear 145 and the second gear 150 are formed by the formed bearing. Rotates with at least frictional force inside the housing 105.

5 is a cross-sectional view A-A 'of a housing in which a first gear and a second gear are formed according to an embodiment of the present invention. Hereinafter, a cross section of a housing in which the first gear and the second gear are formed according to an embodiment of the present invention will be described in detail with reference to FIG. 5.

According to FIG. 5, the cross section of the housing 105 includes a first gear 145, a second gear 150, a first supply pipe 130, a second supply pipe 135, and an outlet pipe 140.

As shown in FIG. 5, the cross section of the housing 105 has an ellipse shape, and the first gear 145 and the second gear 150 are embedded in the ellipse shape. In addition, the first supply pipe 130 is located on one side of the first gear 145 and the second gear 150, and the outflow pipe 140 is located on the opposite side.

The water supplied to the first supply pipe 130 rotates the first gear 145 and the second gear 150 by hydraulic pressure. According to FIG. 5, the first gear 145 and the second gear 150 are rotatable about a rotation axis, and are arranged such that a plurality of gears extending in a predetermined length in the longitudinal direction of the housing are engaged with each other outside the rotation axis. do. That is, the water supplied to the first supply pipe 130 pressurizes the gears formed on the first gear 145 and the second gear 150, and the first gear 145 and the second gear 150 by the pressurized force. ) Rotates. In particular, the first gear 145 rotates clockwise by the water pressure of the water supplied to the first supply pipe 130, and the second gear 150 engaged with the first gear 145 rotates counterclockwise. . Water rotated by the first gear 145 and the second gear 150 flows out through the outlet pipe 140. As such, the present invention rotates the first gear 145 and the second gear 150 through the water supplied to the first supply pipe 130, and rotates the first gear 145 and the second gear 150. Water flows out through the outlet pipe 140. The second supply pipe 135 is also located inside the housing 105, and the water supplied to the second supply pipe 135 is supplied to the shower member 165. That is, the water supplied to the second supply pipe 135 is supplied to the shower member 165, not used to rotate the first gear 145 and the second gear 150.

The first bevel gear 155 is fastened to the other end of the first gear 145. One end of the first bevel gear 155 is fastened to the other end of the first gear 145, and the other end of the first bevel gear 155 forms a gear. A second bevel gear 160 is formed at the other end of the first bevel gear 155. The second bevel gear 160 also rotates by the rotation of the first bevel gear 155. In addition, the second bevel gear 160 is different from the number of rotations of the first bevel gear 155 and the number of rotations of the second bevel gear 160 to form a relatively high torque. That is, the number of teeth formed in the first bevel gear 155 is formed to be relatively smaller than the number of teeth formed in the second bevel gear 160. By doing so, while the first bevel gear 155 rotates, the second bevel gear 160 rotates relatively less than the first bevel gear 155, thereby increasing the torque of the second bevel gear 160. do. The end of the rotating shaft of the second bevel gear 160 forms a screw thread, and fastens various rotating tools to the screw thread formed on the rotating shaft.

5 illustrates the bevel gear, but is not limited thereto. That is, any reduction gear that can reduce the rotation speed can be used in place of the bevel gear proposed in the present invention.

The shower member 165 is connected to the second supply pipe 135, and the water supplied through the second supply pipe 135 flows out through the shower nozzle. As described above, the present invention provides a rotational force for rotating the rotary tool using water pressure when the water channel formed in the pipe connection valve 120 is connected to the first supply pipe 130, and the second supply pipe 135. If connected to the can be used as a general shower.

Figure 6 shows a rotary tool that can be mounted in the shower according to an embodiment of the present invention. According to FIG. 6, the rotating tool includes a brush brush, a grind member, and a cleaning tool (eg, an automobile car washing tool) including a fastening nut. Of course, in addition to the above-described rotary tool, it is also possible to use other tools attached to the shower. In addition, the end of the second bevel gear may be a screw thread or a tool fastening groove portion in addition to the screw thread so that the rotary tool can be fastened.

Hereinafter, a showerhead having a size similar to that of a handle of a model showerhead and having a washing function to reduce wasted water will be described.

7 illustrates a configuration of a shower using water pressure according to another embodiment of the present invention. Hereinafter, the configuration of the shower using water pressure according to another embodiment of the present invention will be described in detail with reference to FIG. 7.

According to FIG. 7, the shower 700 using water pressure includes a housing, a nozzle coupling part, an inlet pipe, a vane motor, a first outlet pipe, a second outlet pipe, a first gear, a second gear, an outlet, a water volume control valve, and a rotation. Control valve. Of course, other configuration in addition to the above-described configuration may be included in the shower using the water pressure proposed in the present invention.

The housing 705 is a main body constituting the shower, and parts constituting the shower of the present invention are mounted inside or outside. The housing 705 is composed of a bar type having a predetermined length as a whole. The housing 705 may be configured in the form of a cylinder or an ellipse column, or may be configured in various forms.

The nozzle coupling part 710 is formed at one end of the housing 705. The nozzle fastening unit 710 is fastened to the nozzle for supplying water. As such, the present invention proposes one nozzle coupling part 710.

Inlet pipe 715 is one side is connected to the nozzle coupling portion 710, the other side is connected to the inlet hole (725a) formed in the vane motor 725. That is, the water introduced into the inlet pipe 715 is supplied to the inlet hole 725a formed in the vane motor 725.

On the inlet pipe 715, a water control valve 720, in particular, the water control hole 720a of FIG. That is, the quantity control valve 720 adjusts the quantity of water flowing in the inlet pipe 715.

8 shows the shape of the water quantity control valve. According to FIG. 8, the amount of water flowing through the inlet pipe is adjusted according to the rotation angle. In detail, the water quantity regulating valve includes a rotary knob 720b and a water quantity adjusting hole 720a, and the rotary knob 720b rotates the water quantity regulating valve 720 clockwise or counterclockwise. If the direction of the water quantity adjustment hole (720a) and the direction of the water flowing through the inlet pipe (715) is the same, the amount of water flowing through the water quantity adjustment hole (720a) increases, the direction of the water quantity adjustment hole (720a) and the inflow pipe (715) If the direction of the water is vertical, the water introduced into the inlet pipe 715 is unable to pass through the water quantity adjustment hole (720a).

The vane motor 725 has a vane 725d formed therein, the vane rotates by the introduced water, and the rotation shaft of the vane motor also rotates by the vane rotation.

9 illustrates a structure of a vane motor according to an embodiment of the present invention. Hereinafter, the structure of the vane motor according to an embodiment of the present invention will be described in detail with reference to FIG. 9.

Referring to FIG. 9, the vane motor 725 includes a rotor 725e, a vane 725d, an inlet hole 725a, a first outlet hole 725b, and a second outlet hole 725c. Of course, in addition to the above-described configuration may be included in the vane motor proposed in the present invention.

The inlet hole 725a is connected to the inlet pipe 715 and water is supplied from the inlet pipe 715. The first outlet hole 725b and the second outlet hole 725c are passages through which water introduced from the inlet hole 725a flows out. In particular, the first outlet hole 725b is connected to the first outlet pipe 730. The second outlet hole 725c is connected to the second outlet pipe 735.

The rotor 725e is located inside the vane motor 725, and a rotation shaft 725f is formed at the center thereof. As shown in FIG. 9, the rotation shaft 725f of the vane motor is eccentric. According to the figure (a), when the water flowing into the inlet hole (725a) is discharged to the second outlet hole (725c), the vane (725d) of the vane motor rotates, accordingly, the rotary shaft (725f) also rotates. On the contrary, according to the drawing (b), when the water flowing into the inlet hole 725a flows out into the first outlet hole 725b, the vane 725d of the vane motor does not rotate, and thus, the rotation shaft 725f also rotates. I never do that.

Thus, the present invention can reduce the size of the cross-sectional area of the shower knob handle portion by using the vane motor, in particular it is possible to produce a cross-sectional area in a circular form by using a single motor.

The first outlet pipe 725b and the second outlet pipe 725c are connected to the discharge pipe 745, and one side of the discharge pipe 745 is connected to the first outlet pipe 725b and the second outlet pipe 725c. The other side is connected to the shower nozzle of the shower member. In other words, the discharge pipe discharges the introduced water to the outside.

In particular, the present invention forms a push switch 740 on one side of the discharge pipe 745 connected to the first outlet pipe 730 and the second outlet pipe 735. The push switch 740 moves up and down by an external pressure. When the push switch 740 moves up, the second outlet pipe 735 and the discharge pipe are connected to each other while the first outlet pipe 730 and the discharge pipe 745 are connected. (745) Disconnect the connection. In addition, when the push switch 740 is operated in a downward direction, the second outlet pipe 735 and the discharge pipe 745 are connected to each other and the first outlet pipe 730 and the discharge pipe 745 are disconnected.

This is illustrated in FIG. 10. 10 illustrates an operation of a push switch according to an embodiment of the present invention. As shown in FIG. 10, the discharge pipe 745 is connected to the first outlet pipe 730 or the second outlet pipe 735 according to the operation of the push switch 740.

In detail, when the push switch 740 blocks the first outlet pipe 730, water does not flow into the first outlet hole 725b, but water flows into the second outlet hole 725c. When water flows out to the second outflow hole 725c, the rotation shaft 725f of the vane motor 725 rotates. In contrast, when the push switch 740 blocks the second outlet pipe 735, the water does not flow into the second outlet hole 725c, but the water flows out of the first outlet hole 725b. When water flows out to the second outflow hole 725c, the rotation shaft 725f of the vane motor does not rotate.

The first gear 750 is connected to the rotary shaft 725f of the vane motor, and the first gear 750 also rotates by the rotation of the rotary shaft 725f. The second gear 755 is coupled to the first gear 750, and the second gear 755 also rotates by the rotation of the first gear 750. The axis of rotation of the second gear 755 is configured to form an empty through hole, and the discharge pipe 745 penetrates. That is, the water flowing out through the discharge pipe 745 flows out through the inside of the second gear 755. A second fastening member 760 is formed at the end of the discharge tube 745 so that the shower member or the rotary tool can be coupled, and the fastening member 760 is fixedly fastened to the second gear 755 while the discharge tube 745 is fixed. ) Is not fixed. In FIG. 7, a fastening member 760 having a threaded line is illustrated. The water flowing out of the discharge pipe 745 is discharged to the outside through the shower member or the rotating tool coupled thereto.

In addition, as described above, when the rotation shaft 725f of the vane motor rotates, the first gear 750 also rotates, and the second gear 755 also rotates by the rotation of the first gear 750, and the second The rotary tool coupled with the second gear 755 by the rotation of the gear 755 also rotates.

7 illustrates the shape of the gear in the form of a bevel gear, but is not limited thereto. That is, all gears capable of forming a relatively high torque by using a reduction gear correspond to this. Hereinafter, it will be described once again on the assumption that the shape of the gear is configured in the form of a bevel gear.

The first bevel gear 750 is engaged with the rotation shaft 725f. One end of the first bevel gear 750 is coupled to the rotation shaft 725f, and the other end of the first bevel gear 750 forms a gear. A second bevel gear 755 is formed at the other end of the first bevel gear 750. The second bevel gear 755 also rotates by the rotation of the first bevel gear 750. In addition, the second bevel gear 755 is different from the number of rotations of the first bevel gear 750 and the number of rotations of the second bevel gear 755 to form a relatively high torque. That is, the number of teeth formed in the first bevel gear 750 is relatively smaller than the number of teeth formed in the second bevel gear 755. By doing so, the second bevel gear 755 rotates relatively less than the first bevel gear 750 while the first bevel gear 750 rotates, thereby increasing the torque of the second bevel gear 755. do. The end of the rotating shaft of the second bevel gear 755 forms a screw thread, and fastens various rotating tools to the screw thread formed on the rotating shaft. In addition, the end of the second bevel gear may be a screw thread or a tool fastening groove portion in addition to the screw thread so that the rotary tool can be fastened.

11 is a view illustrating a shower from the top according to an embodiment of the present invention. According to FIG. 11, the discharge pipe is connected to the first outlet pipe or the second outlet pipe by using the rotation control member.

12 illustrates an example in which a shower member is mounted in a shower according to an embodiment of the present invention. When the shower member is mounted in the shower, the vane of the vane motor is not rotated by using the rotation control member. That is, the first outlet pipe and the discharge pipe are connected, and the connection of the second outlet pipe and the discharge pipe is blocked.

Figure 13 shows an example of mounting the rotary tool in the shower according to an embodiment of the present invention. The rotating tool includes a cleaning tool including a brush brush, a grinding member and a fastening nut. Of course, in addition to the above-described rotary tool, it is also possible to use other tools attached to the shower. When the rotary tool is mounted in the shower, the vane of the vane motor is rotated using the rotation control member. That is, the second outlet pipe and the discharge pipe are connected, and the connection of the first outlet pipe and the discharge pipe is blocked.

In particular, the shower of the present invention is discharged to the outside through the discharge port both when performing the shower function and when performing the washing function. Therefore, when performing the cleaning function, the water leaked through the discharge port is discharged to the outside through the brush brush. That is, the water discharged to the outside through the brush brush can be used in the washing process to prevent unnecessary waste of water.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. .

The present invention relates to a shower capable of using a rotary tool, and more particularly to a shower capable of rotating the rotary tool using the water pressure of tap water or industrially supplied water.

Shower according to the present invention by using a small rod-shaped vane motor or gear motor built in the handle portion can be a shower having a size similar to the conventional shower handle.

In addition, the shower proposed in the present invention can be produced by varying the thickness and length according to the use of the head portion or the handle portion, in particular can be used for washing parts required for various industries by increasing the rotational force. The water rotated by the rotating tool can be used as a shower water or reused for cleaning to prevent unnecessary waste of water.

Claims (8)

1. housing;

   A first nozzle coupling part formed at one end of the housing and to which an external first nozzle is coupled;

   A water inlet pipe connected to the first nozzle coupling part and into which water is introduced from an external first nozzle;

   A pipe connection valve which rotates by an angle set in a clockwise or counterclockwise direction and has a water channel through which water introduced from the water inlet pipe moves;

   Located in the housing in the longitudinal direction of the housing, receiving the water from the water formed in the pipe connecting valve in a state in which the pipe connecting valve is rotated in the first direction of either the clockwise or counterclockwise direction A first supply pipe;

   A number formed in the pipe connecting valve in a state in which the pipe connecting valve is rotated in a second direction different from a first direction which is either one of a clockwise or counterclockwise direction. A second supply pipe receiving water from the second supply pipe;

   A first gear positioned inside the housing in a longitudinal direction of the housing and rotating by water pressure of water supplied to the first supply pipe;

   A second gear positioned inside the housing in the longitudinal direction of the housing and rotating by water pressure of water supplied to the first supply pipe while being engaged with the first gear;

   A first reduction gear coupled to an end of the first gear and rotating by rotation of the first gear;

   A second reduction gear meshed with the first reduction gear to rotate and having a screw thread or a tool engagement groove for fastening a tool to an end thereof; And

   And a shower member receiving water from the second supply pipe.
2. The method of claim 1,

   Located in the longitudinal direction of the housing in the housing, the shower, characterized in that it comprises an outlet pipe for outflow of water supplied to the first supply pipe.
3. According to claim 2, It is formed on one end of the housing, characterized in that it comprises a second nozzle fastening portion to which the external second nozzle is fastened so that it can be supplied to the external second nozzle flowing through the outlet pipe. Shower.
4. According to claim 1, wherein the number of teeth formed in the second reduction gear is relatively larger than the number of teeth formed in the first reduction gear, the second reduction gear is reduced in rotation speed compared to the first reduction gear and the rotation torque is increased Shower, characterized in that.
5. housing;

   A nozzle coupling part formed at one end of the housing and to which an external nozzle is coupled;

   An inlet pipe connected to the nozzle coupling part and into which water is introduced from the outside;

   An inlet hole through which water is introduced from the inlet pipe, a first outlet hole and a second outlet hole through which the inflowed water flows out is formed, and when the inflowed water flows out into the first outlet hole, the vane does not rotate, and the inflowed water is removed. A vane motor, wherein the vane rotates when it is discharged into an outlet hole;

   A first outlet pipe for introducing the water discharged from the first outlet hole;

   A second outlet pipe into which the water discharged from the second outlet hole flows;

   A first gear fixed to the rotary shaft of the vane motor fixed to the vane;

   A second gear that meshes with the first gear and rotates;

   One side of the second gear is meshed with the first gear, the other side is a shower, characterized in that the screw thread or tool fastening groove portion to which the tool is fastened.
6. The method of claim 5, wherein the first gear and the second gear is a reduction gear,

   The number of teeth of the tooth formed in the second gear is relatively larger than the number of teeth formed in the first gear, the second gear is a rotation speed compared to the first gear, the shower torque, characterized in that the rotation torque increases.
7. The method of claim 5,

   The showerhead is formed on the inlet pipe, characterized in that it comprises a water volume control valve for adjusting the water inflow from the inlet pipe.
8. The method of claim 5,

   One side is connected to the first outlet pipe and the second outlet pipe, and includes a discharge pipe passing through the central axis of the second gear,

   One side of the discharge pipe is a push switch is located,

   The push switch is a shower, characterized in that for blocking the connection of any one of the first outlet pipe or the second outlet pipe and the discharge pipe.

Images