KR20090088711A - Shower head - Google Patents

Abstract

A shower head is provided to generate the induced electromotive force in low water pressure and maintain the status of radiation. A shower head comprises: a head casing (110) which has an inflow hole of water into inside and front part is opened; a handle (120) which is connected with the head casing to connect to the inflow hole; a releasing cap (130) having plural holes for releasing; an impeller (140) which is installed inside head casing to rotate by water pressure; a rotor (150) which rotates with the impeller; a stator (160) which is fixed inside head casing and arranged in the circumference of rotor; and luminous unit (170).

Description

Shower head {Shower head}

The present invention relates to a shower head capable of emitting light using water pressure.

With the improvement of the standard of living, in the shower which is one of the bath facilities which are frequently used at home, the products which added various functions are developed and used. For example, a shower head that emits a ball while water is sprayed to feel aesthetics, or a shower head that visually recognizes a water temperature by emitting light of different colors according to a change in water temperature.

The shower heads of the above-described example use the principle that the light emitting diode emits light by induced electromotive force generated between the rotor and the stator while the rotor rotates by the water pressure of the incoming water.

However, in low pressure environments, the rotor may not rotate due to too low water pressure. Then, since no induced electromotive force is generated, the light emitting diode does not emit light.

Alternatively, the rotor can be rotated and stopped without rotating continuously. Then, since the induced electromotive force is intermittently generated, the light emitting diode does not continue to emit light. Therefore, there is a problem that the shower head does not properly exhibit the light emitting function.

An object of the present invention is to solve the above problems, to provide a shower head capable of generating an induced electromotive force even in a low-pressure environment and can emit light and maintain the light emission state.

Shower head according to the present invention for achieving the above object is, the inlet hole is formed so that water is introduced into the inner space, the front casing head opening; A handle formed to be narrower from an inlet passage to an outlet hole and connected to the head casing such that the outlet hole communicates with an inlet hole; A blowing cap coupled to the opened front of the head casing and having a plurality of ejection holes formed therein; An impeller installed in the head casing so as to be rotated by the water pressure of the water flowing through the inflow hole, the impeller having an impeller body and a plurality of wings protruding from the impeller body and being curved; A rotor fixed to the impeller and rotating together with the impeller; A stator fixed in the head casing and disposed around the rotor; And a light emitting unit that emits light by a power generation action between the rotor and the stator in the head casing, wherein the inflow hole is formed such that the inflow direction of the water is outside the center of rotation of the impeller and is directed toward the concave surface of the wing. It is characterized by.

According to the present invention, the induced electromotive force can be sufficiently generated even in a low-pressure environment, so that the light emitting unit not only emits light but also maintains the emitted state.

According to the present invention, since the drain passage is formed along the circumference of the shaft hole in the impeller, noise is not induced, and the impeller can smoothly rotate due to the decrease in the flow resistance. In addition, even if an external impact is applied to the impeller, the impact can be buffered due to the perforated space of the drain passage.

According to the present invention, since the front and rear surfaces of the ejection cap are formed to be concave and convex in a concentric waveform, since the light emitted from the light emitting unit can be diffused, the aesthetics can be further enhanced.

According to the present invention, since the functional filter can be built into the handle, it can help the user for skin, hair beauty, and the like.

According to the present invention, since a separate magnet support part is provided to support the permanent magnets, the permanent magnets can be arranged at regular intervals, and assembly convenience can be increased.

According to the present invention, since the light emitting pattern input unit for receiving the light emitting pattern from the outside is provided, it is possible to implement the desired light emitting pattern.

According to the present invention, since the light may be emitted in different colors or different patterns for each water temperature level, the user may feel aesthetics. In addition, the user can visually recognize the water temperature, and thus can cope with a sudden change in the water temperature.

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

1 is a perspective view of a shower head according to an embodiment of the present invention, Figure 2 is an exploded perspective view of FIG. 3 is a cross-sectional view taken along the line III-III in FIG. 1, and FIG. 4 is a cross-sectional view taken along the line IV-IV in FIG.

1 to 4, the shower head 100 includes a head casing 110, a handle 120, a blowing cap 130, an impeller 140, a rotor 150, The stator 160 and the light emitting unit 170 are configured.

The head casing 110 has an inner space and a shape of which the front side is opened. Here, the outer casing and the inner space of the head casing 110 may be formed in a substantially cylindrical shape. The head casing 110 is formed with an inflow hole 111 so that water flows into the inner space. The inflow hole 111 may be disposed on the side wall in the head casing 110.

As shown in detail in FIG. 3, the inflow hole 111 is formed such that the inflow direction of the water deviates from the center of rotation of the impeller 140. Here, the inflow direction of the water may be set so that the maximum pressure of the hydraulic pressure on the wing 146 under the same hydraulic conditions. In addition, the inflow hole 111 is formed such that the inflow direction of water is toward the concave surface of the wing 146 of the impeller 140.

The handle 120 has an inner flow passage 121 as shown in FIG. 3. The inner flow passage 121 is formed to be narrower from the inflow hole 121a to the outflow hole 121b. The diameter of the outlet hole 121b may be such that the water may be discharged at a flow rate such that the impeller 140 can be continuously rotated in a low water pressure environment to be used in consideration of the structure of the inlet hole 111 and the wing 146. Can be set.

The handle 120 is connected to the head casing 110 so that the water extraction hole 121b communicates with the inflow hole 111 of the head casing 110. Here, the handle 120 may be connected to the side of the head casing 110.

The jet cap 130 engages the open front of the head casing 110. The blowing cap 130 closes the opened front of the head casing 110 in a state where the impeller 140, the rotor 150, the stator 160, and the light emitting unit 170 are accommodated in the head casing 110. .

A plurality of jet holes 131 are formed in the jet cap 130. Here, the ejection holes 131 are formed such that water introduced into the head casing 110 may be ejected to the outside, as shown in FIG. 4. The packing member 136 may be installed between the jet cap 130 and the head casing 110 so that water does not leak from the coupling portion in a state where the jet cap 130 is coupled with the head casing 110.

The impeller 140 is installed in the head casing 110 to be rotated by the water pressure of the water flowing through the inlet hole 111. The impeller 140 has an impeller body 141 and a plurality of wings 146. The wings 146 protrude from the impeller body 141 and are formed to be curved. Here, the wings 146 may be spaced apart from each other at regular intervals, and may be disposed on the rear surface of the impeller body 141.

The rotor 150 is fixed to the impeller 140, as shown in FIG. 4. Accordingly, when the impeller 140 rotates by the water pressure of water introduced into the head casing 110, the rotor 150 rotates together with the impeller 140.

The stator 160 is fixed in the head casing 110, as shown in FIG. 4, and is disposed around the rotor 150. When the rotor 150 rotates with respect to the stator 160, a power generation action occurs between the stator 160 and the rotor 150. That is, induced electromotive force is generated between the stator 160 and the rotor 150, and the induced electromotive force acts as a power source for emitting the light emitting unit 170.

The light emitting unit 170 emits light in the head casing 110 by the power generation action between the rotor 150 and the stator 160 described above.

An operation example of the shower head 100 configured as described above will be described with reference to FIGS. 3 and 4.

When water flows into the inner passage 121 through the inlet hole 121a of the handle 120, the introduced water moves toward the outlet hole 121b along the inner passage 121 and then discharges to the inlet hole 111. do. In this process, since the inner flow passage 121 has a shape that becomes narrower from the inlet hole 121a to the outlet hole 121b, the inner flow passage 121 is discharged to the outlet hole 121b while gradually increasing the flow rate. At this time, the water discharged from the water extraction hole 121b has a flow rate enough to rotate the impeller 140 sufficiently continuously even in a low water pressure environment to be used.

The water having the flow rate flows into the head casing 110 through the inlet hole 111, and then moves to the impeller 140 to rotate the impeller 140. In this case, since the inflow direction of the water is formed outside the rotation center of the impeller 140, the inflow hole 111 has a water pressure applied to the wing 146 than the inflow direction of the water is formed toward the rotation center of the impeller 140. Can be increased.

In addition, since the wing 146 is formed to be curved in a concave shape with respect to the inflow direction of the water, the area in contact with the water may be increased, and the time for contact with the water may be longer than the wing 146 is formed in a straight shape. Accordingly, the initial starting time of the impeller 140 may be shortened, and the rotational force of the impeller 140 may be increased. Therefore, the impeller 140 may not only rotate more easily, but also rotate continuously.

When the impeller 140 rotates, the rotor 150 fixed to the impeller 140 rotates. At this time, since the impeller 140 continuously rotates even in a low pressure environment, the rotor 150 also rotates continuously. Accordingly, induced electromotive force can be continuously generated between the rotor 150 and the stator 160. Therefore, not only the light emitting unit 170 may emit light by the induced electromotive force, but also the light emitting unit 170 may continue to emit light.

Meanwhile, the handle 120 may include a handle body 122 and a funnel member 123. The handle body 122 is connected to the head casing 110. Here, the handle body 122 may be manufactured integrally with the head casing 110. The handle body 122 has an interior space to accommodate the funnel member 123.

The internal passage 121 is formed in the funnel member 123. When the inner space of the handle body 122 has a constant diameter and the funnel member 123 is manufactured to have a certain thickness, a plurality of ribs 124 are formed on the outer surface of the funnel member 123.

The ribs 124 are formed to be in contact with the inner surface of the handle body 122 while the funnel member 123 is accommodated in the inner space of the handle body 122. Accordingly, the funnel member 123 may maintain a state accommodated in the inner space of the handle main body 122.

Meanwhile, the handle 120 may further include a handle extension 125. The handle extension 125 has a storage space 126 in which the functional filter 127 is accommodated. The functional filter 127 may be a vitamin C filter. Water introduced into the handle extension 125 passes through the vitamin C filter, and chlorine in the water may be removed. In addition, the vitamin C component may be contained in the water.

When the water passed through the vitamin C filter is supplied to the user through the head casing 110, it may help the user with skin, hair beauty, and the like. The handle extension 125 may be detachably coupled to the handle body 122 to facilitate replacement of the functional filter 127.

A foreign material removal filter 128 may be further provided between the handle body 122 and the handle extension 125. The foreign substance removal filter 128 removes foreign substances contained in the water before the water flows into the head casing 110, thereby preventing foreign substances from entering the head casing 110.

On the other hand, the jet cap 130 may be formed of a transparent material so that the light emitted from the light emitting unit 170 can be transmitted. As shown in FIG. 4, the jet cap 130 may be formed to have concave and convex front and rear surfaces to diffuse light emitted from the light emitting unit 170. Accordingly, the aesthetics can be increased.

Preferably, the ejection holes 131 are disposed in the convex portions of the ejection cap 130. Then, as light is diffused through the convex portion of the jet cap 130, the water stems ejected from the jet holes 131 may be taken out, thereby increasing the aesthetics.

The blowing cap 130 may have a through hole 132 formed at the center thereof. The jet cap 130 may be fixed to the head casing 110 by the fixing member 133 being screwed to the rotation shaft 180 through the through hole 132 from the outside of the through hole 132.

Meanwhile, as illustrated in FIGS. 3 and 5, the shaft hole 142 may be formed in the impeller body 141 so that the rotation shaft 180 installed in the head casing 110 is fitted. Accordingly, the impeller body 141 can be stably rotated in a state of being fitted to the rotation shaft 180. In addition, the impeller body 141 may have a structure having an inner space and an open front side thereof to accommodate the rotor 150.

Side surfaces of the impeller body 141 are spaced apart from the inner surface of the magnet support 162 to be described later at regular intervals. The water introduced from the inflow hole 111 may be rotated through the space between the impeller body 141 and the magnet support 162 after rotating the wing 146.

In addition, a drain passage 143 may be formed in the impeller body 141 along the circumference of the shaft hole 142. In this case, the wings 146 are each formed such that one end is located at the edge of the impeller body 141 and the other end is adjacent to the drain passage 143. The wings 146 may be manufactured integrally with the impeller body 141.

The water rotated by the wing 146 may be drained through the space between the impeller body 141 and the magnet support 162 as well as to the drain passage 143. Thus, the water rotated by the blade 146 can be drained smoothly without remaining between the blades (146). As a result, the noise is not induced, the flow resistance is reduced, the impeller 140 can be smoothly rotated.

In addition, when the drain passage 143 is formed along the circumference of the shaft hole 142, even if an external impact such as the shower head 100 falls, the impeller 140 may be caused by the perforated space of the drain passage 143. The shock may be cushioned. The impeller 140 may be made of a material having strong wear resistance, for example, polyoxymethylene (POM) material.

Meanwhile, the rotation shaft 180 may be protected by the shaft protection member 181 as shown in FIG. 4. The shaft protection member 181 surrounds the circumference of the rotation shaft 180 and is formed to fit in the shaft hole 142 of the impeller body 141. The shaft protection member 181 protects the rotation shaft 180 when an external impact is applied, and guides the impeller 140 to rotate smoothly.

The shaft protection member 181 may be fixed to the head casing 110 so as not to damage the rotation shaft 180 by rotating about the rotation shaft 180. The shaft protection member 181 may be fixed by fitting to the head casing 110. The shaft protection member 181 may be made of polyoxymethylene or the like.

The rotor 150 may include a coil 151, a bobbin 152 on which the coil 151 is wound, and cover members 153a and 153b surrounding the bobbin 152. Both ends of the coil 151 are connected to the light emitting unit 170. The cover members 153a and 153b preferably have a structure capable of maximizing induced electromotive force by minimizing leakage magnetic flux. For example, as shown in FIGS. 2 and 4, the cover members 153a and 153b are fitted with each other in a sawtooth shape to surround the outer circumferential surface of the bobbin 152, and overlap to cover the inner circumferential surface of the bobbin 152. It may be made of a structure. A buffer member 156 may be installed between the rotor 150 and the impeller 140 to cushion an external shock.

The stator 160 may include a plurality of permanent magnets 161. The permanent magnets 161 are arranged to face each other along the circumference of the rotor 150, and the N and S poles are alternately arranged. The permanent magnets 161 may be supported by the magnet support 162.

The magnet support 162 may be formed in a ring shape so that the impeller 140 is inserted into the center thereof. In addition, the permanent magnets 161 may be inserted into support one by one at regular intervals along the circumference of the ring so that the insertion grooves 163 may be formed. Accordingly, the permanent magnets 161 may be arranged at regular intervals, and the assembly may be convenient. The magnet support 162 may be fixed to the head casing 110 so as not to rotate by fitting. In this case, the above-described inflow hole 111 may be formed in the magnet support 162.

The light emitting unit 170 may include a printed circuit board 171, red, green, and blue light emitting diodes 176, and a controller (not shown). The printed circuit board 171 may be fixed to the impeller 140 to rotate together with the impeller 140. Here, the printed circuit board 171 is preferably disposed in front of the rotor 150 such that the light emitting diodes 176 are located close to the ejection cap 130. The printed circuit board 171 is circuitally connected to the rotor 150 to receive the induced electromotive force generated between the rotor 150 and the stator 160.

The light emitting diodes 176 are circuitly connected to the printed circuit board 171. The light emitting diodes 176 are disposed toward the jet cap 130 so that the emitted light can be delivered to the jet cap 130. Here, the light emitting diodes 176 may be arranged to implement various desired light emitting patterns.

The control unit is configured in a circuit on the printed circuit board 171. The controller receives the induced electromotive force from the rotor 150 to control the light emission of the light emitting diodes 176.

As shown in FIG. 4, the light emitting unit 170 includes a reflective film 172 formed on a surface of the printed circuit board 171 on which the light emitting diodes 176 are disposed, and a transparent waterproof film 173 formed on the reflective film 172. It may be further provided. The reflective film 172 may reflect light traveling toward the printed circuit board 171 toward the ejection cap 130 to increase the luminous efficiency. The waterproof film 173 protects the light emitting diodes 176 from being connected to the printed circuit board 171 or prevents water from entering into the circuit pattern.

On the other hand, the printed circuit board 171 may further include a light emitting pattern input unit for receiving a light emitting pattern from the outside in a circuit. The light emission pattern input unit may include an input terminal 174 to be connected to an external connector.

The controller controls light emission of the light emitting diodes 176 according to the light emission pattern received from the light emission pattern input unit. In this case, the controller controls the light emitting diodes 176 on and off individually so that the light emitting pattern can be implemented. The emission pattern may vary in a circular band shape, a letter, or the like.

On the other hand, the water temperature sensor 177 for measuring the temperature of the water flowing into the head casing 110 may be further provided. As the water temperature sensor 177, a thermocouple or the like may be used. The controller may control light emission of the light emitting diodes 176 to display different colors for each water temperature level based on the water temperature value received from the water temperature sensor 177. Alternatively, the controller may control the light emission of the light emitting diodes 176 to display different patterns for each water temperature level.

For example, the controller may divide the water temperature into a high temperature region, a medium temperature region, and a low temperature region to control light emission of the light emitting diodes 176 to display different colors or different patterns for each temperature region. Accordingly, the user can not only feel the aesthetic sense but also visually recognize the water temperature, and thus can cope with a sudden change in the water temperature.

The present invention can be applied to a shower having a light emitting function.

1 is a perspective view of a shower head according to an embodiment of the present invention.

2 is an exploded perspective view of FIG. 1.

3 is a cross-sectional view taken along the line III-III in FIG. 1;

4 is a cross-sectional view taken along the line IV-IV in FIG. 1;

FIG. 5 is a perspective view of the impeller in FIG. 2; FIG.

<Brief description of the major symbols in the drawings>

110. Head casing 111. Inlet hole

120. Handle 121. Inner flow path

130..Ejector cap 140..Impeller

141. Impeller body 143. Drainage passage

146..wing 150..rotor

160 stator 170 luminous unit

Claims (12)

An inlet hole is formed to allow water to flow into the inner space, and a head casing having a front opening; A handle formed to be narrower from an inlet passage to an outlet hole and connected to the head casing such that the outlet hole communicates with an inlet hole; A blowing cap coupled to the opened front of the head casing and having a plurality of ejection holes formed therein; An impeller installed in the head casing so as to be rotated by the water pressure of the water flowing through the inflow hole, the impeller having an impeller body and a plurality of wings protruding from the impeller body and being curved; A rotor fixed to the impeller and rotating together with the impeller; A stator fixed in the head casing and disposed around the rotor; And And a light emitting unit emitting light by a power generation action between the rotor and the stator in the head casing. The inlet hole is formed so that the inflow direction of the water out of the rotation center of the impeller, the shower head, characterized in that it is formed toward the concave surface of the wing. The method of claim 1, The handle is, A handle body connected to the head casing; And And a funnel member having the inner flow path formed therein and having a plurality of ribs formed on an outer surface thereof so as to maintain a state accommodated in the handle main body. The method of claim 2, The handle is, And a handle extension part detachably coupled to the handle body and having a storage space for storing a functional filter. The method of claim 3, wherein Shower head, characterized in that further comprising a foreign matter removal filter between the handle body and the handle extension. The method of claim 1, A shaft hole is formed in the impeller body so that a rotating shaft installed in the head casing is fitted, and a drain passage is formed along the circumference of the shaft hole. The wings are shower head, characterized in that the one end is formed on the edge of the impeller body and the other end is located adjacent to the drain passage. The method of claim 5, And a shaft protection member fixed to the head casing to surround and protect the circumference of the rotating shaft. The method of claim 1, The light emitting unit, A printed circuit board fixed to the impeller and circuitally connected to the rotor; Red, green, and blue light emitting diodes disposed toward the ejection cap and circuitally connected to the printed circuit board; And And a controller configured circuitry on the printed circuit board to receive induction electromotive force from the rotor to control light emission of the light emitting diodes. The method of claim 7, wherein The light emitting unit, A reflective film formed on a surface of the printed circuit board on which the light emitting diodes are disposed; And Shower head, characterized in that it further comprises; a transparent waterproof film formed on the reflective film. The method of claim 7, wherein The printed circuit board further includes a light emitting pattern input unit configured to circuitly receive a light emitting pattern from the outside; The control unit is a showerhead, characterized in that for controlling the light emission of the light emitting diodes according to the light emission pattern received from the light emission pattern input unit. The method of claim 7, wherein A water temperature sensor for measuring the temperature of the water flowing into the head casing is further provided; The controller according to claim 1, wherein the controller controls light emission of the light emitting diodes such that different colors are displayed or different patterns are displayed for each water temperature level based on the water temperature value input from the water temperature sensor. The method of claim 1, The spray cap is formed of a transparent material, the front and rear is formed to be concave-convex in a concentric wave shape so as to diffuse the light emitted from the light emitting unit, the shower head, characterized in that the ejection holes are arranged in the convex portions. The method of claim 1, The stator has a plurality of permanent magnets, And the permanent magnets are inserted into and supported by insertion grooves formed at regular intervals on the magnet support.

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