KR20210012254A - Sterilizer - Google Patents

Abstract

The present disclosure relates to a sterilization apparatus which, in the sterilization apparatus coupled to a container, comprises: a case including a coupling part coupled to the container; a light emitting unit provided in the case, emitting light toward the inside of the container, and including a first semiconductor light emitting device emitting ultraviolet light; and a solar cell provided in the case, electrically connected to the light emitting unit, and supplying electric energy to the light emitting unit.

Description

Sterilizing device {STERILIZER}

The present disclosure relates generally to a sterilization device, and in particular to a portable sterilization device.

Here, a background technology related to the present disclosure is provided, and these do not necessarily mean a known technology (This section provides background information related to the present disclosure which is not necessarily prior art).

1 is a view showing an example of a sterilizable container presented in Korean Patent Publication No. 10-1875681, wherein the sterilizable container includes a body part 10, a stopper 20, a power supply part 30, and an ultraviolet lamp 40 , A packing unit 50, and a display unit 60.

The stopper 20 is provided on the upper part of the body part 10, and the power supply part 30 is provided under the body part 10. The power supply unit 30 provides power to the ultraviolet lamp 40. The ultraviolet lamp 40 is provided inside the body portion 10 and sterilizes beverages accommodated in the body portion 10. The packing part 50 is provided between the power supply part 30 and the ultraviolet lamp 40, and the packing part 50 prevents foreign substances of the body part 10 from moving to the power supply part 30. The display unit 60 is provided outside the body unit 10.

2 is a view showing an example of an ultraviolet sterilizer baby bottle overcap presented in Korean Utility Model Publication No. 20-0380993, and reference numerals have been changed for convenience of explanation.

The UV sterilizer baby bottle overcap (2) includes an electronic circuit board cap (7), a solar cell (5), a rechargeable battery (8), a power switch (6), an electronic circuit board (9), and an ultraviolet lamp (4). Equipped. The cap 7 on the electronic circuit board is provided on the electronic circuit board 9, and a solar cell 5 and a power switch 6 are provided on the cap 7 on the electronic circuit board. In addition, the rechargeable battery 8 is provided on the electronic circuit board 9. The ultraviolet lamp 4 is provided between the baby bottle overcap 2 and the cap 7 on the battery circuit board.

The ultraviolet lamp 40 of FIG. 1 is provided under the container. The packing part 50 is provided between the power supply unit 30 and the ultraviolet lamp 40 to prevent foreign substances from entering the power supply unit 30. However, as the packing unit 50 is used, there is a problem that foreign substances may enter the power supply unit 30 when the packing unit 50 is aged and stretched.

The UV sterilizer baby bottle overcap (2) of FIG. 2 is provided on the baby bottle (3) and the nipple (1). The UV sterilizer baby bottle overcap (2) disinfects the baby bottle (3) and the nipple (1), and does not disinfect the contents, so the electronic circuit board (9) is not waterproof and must be separated and washed.

This will be described later in the'Specific Contents for the Implementation of the Invention'.

Here, a summary of the present disclosure is provided, and this section provides a general summary of the disclosure and is not a comprehensive disclosure of its full scope or all of its features).

According to one aspect according to the present disclosure (According to one aspect of the present disclosure), in the sterilization device coupled to the container, the case including a coupling portion coupled to the container; A light-emitting unit provided in the case and including a first semiconductor light-emitting device emitting light toward the interior of the container and emitting ultraviolet rays; In addition, a sterilization device including a solar cell provided in the case, electrically connected to the light emitting unit, and supplying electric energy to the light emitting unit is provided.

This will be described later in the'Specific Contents for the Implementation of the Invention'.

1 is a view showing an example of a sterilizable container presented in Korean Patent Registration No. 10-1875681,
2 is a view showing an example of an ultraviolet sterilizer baby bottle overcap presented in Korean Utility Model Publication No. 20-0380993,
3 is a view showing a conceptual diagram of a sterilization device according to the present disclosure,
4 to 5 are views showing an example of a sterilization device according to the present disclosure,
6 is a view showing another example of the sterilization device according to the present disclosure.

Hereinafter, the present disclosure will now be described in detail with reference to the accompanying drawing(s)).

3 is a view showing a conceptual diagram of a sterilization device according to the present disclosure.

The sterilization device 100 coupled to the container 200 includes a case 110, a light emitting unit 120 and a solar cell 130.

The case 110 includes a coupling portion 111, and the coupling portion 111 may be formed with a thread. The coupling part 111 may be provided in the lower surface direction of the case 110.

The light L of the light emitting unit 120 faces the inside of the container 200 and is provided inside the case 110. The light-emitting unit 120 includes a first semiconductor light-emitting device 121 (FIG. 5), and the first semiconductor light-emitting device 121 emits ultraviolet rays. Ultraviolet light can kill microbes such as bacteria. The first semiconductor light emitting device 121 may emit UVC in ultraviolet rays.

The solar cell 130 is provided in the case 110 and may be provided in the upper surface direction of the case 110. The solar cell 130 receives light and generates electric energy. The width (a) of the solar cell 130 may be formed to be wider than the width (b) of the coupling portion 111. The solar cell 130 has a different size of electric energy produced according to the width (a) and size of the solar cell 130. Accordingly, it is preferable that the width (a) of the solar cell 130 is formed to be wider than the width (b) of the coupling part 111 in order to generate electric energy so that the light emitting part 120 is operable.

The coupling part 111 of the sterilizing device 100 is coupled to the inlet 201 of the container 200. The inlet 201 of the container 200 is inserted into the coupling part 111. The light-emitting unit 120 emits light toward the entrance 201 of the container 200. The solar cell 130 is electrically connected to the light emitting unit 120 (171), and the solar cell 130 uses electric energy (eg, voltage) generated by the solar cell 130 to allow the light emitting unit 120 to operate. Make it possible. The voltage of the solar cell 130 is preferably 1V or more and 5V or less than the driving voltage of the first semiconductor light emitting device 121 of the light emitting unit 120. This is because it is preferable for the solar cell 130 to directly supply a voltage to the light emitting unit 120 without a booster in order to minimize power loss. In addition, when the driving voltage of the first semiconductor light emitting device 121 is set to be 1V or more higher than the driving voltage of the first semiconductor light emitting device 121, since the voltage generated by the solar cell 130 varies depending on the weather, a spare voltage is required. Even if it is higher than the driving voltage of 121), the size of the portable solar cell 130 is small and there is a limit of the generated current, so it is not a problem. However, if the voltage of the solar cell 130 is lower than the driving voltage of the first semiconductor light emitting device 121, the first semiconductor light emitting device 121 is not turned on, so the first semiconductor light emitting device 121 does not operate without a booster. . The setting of 5V or less than the driving voltage of the first semiconductor light emitting device 121 is for the convenience of manufacturing the solar cell 130, and in general, a voltage of about 0.5V is generated per cell in a silicon solar cell. For example, in order to make a solar cell voltage of 8V, 16 cells must be connected in series, which complicates the manufacturing process. Moreover, for the application of a portable sterilizer as in the present disclosure, the size of the product should be small, so it is necessary to use as small solar cells as possible, and it is a very difficult process to mount a large number of cells in a small area. Therefore, making the solar cell 130 unnecessarily higher than the driving voltage of the first semiconductor light emitting device 121 by 5V or more may increase process defects and cost.

In general, the container 200 is formed such that the width of the inlet 201 is narrower than the width of the lower portion of the container 200. For example, the container 200 may be a PET bottle or a beverage bottle. PET bottles are easy to obtain, and since the size of the inlet 201 of the PET bottle is common and the size is constant, it can be coupled to the coupling part 111 if it is a PET bottle. In addition, PET bottles are suitable for use because they do not pass ultraviolet rays.

4 to 5 are views showing an example of a sterilization device according to the present disclosure.

FIG. 4 is a view showing an example of a perspective view of the sterilizing device 100, and FIG. 5 is a view showing a cross section AA′ of the sterilizing device 100 of FIG. 4.

The light-emitting unit 120 further includes a second semiconductor light-emitting device 122, and the second semiconductor light-emitting device 122 emits visible light. Since ultraviolet rays emitted by the first semiconductor light-emitting device 121 are not visible, a user from the outside cannot know whether the first semiconductor light-emitting device 121 is turned on. The second semiconductor light emitting device 122 is turned on while the second semiconductor light emitting device 122 is turned on in order to allow the user to recognize whether the first semiconductor light emitting device 121 is turned on. In addition, the light emitting unit 120 may be formed of a semiconductor light emitting device structure (not shown) in which the first semiconductor light emitting device 121 and the second semiconductor light emitting device 122 are provided together.

The sterilization device 100 further includes a window 140, a control unit 150, a reflective unit 160, a switch 170, an elastic body 180, and a fixing unit 190.

The window 140 is provided between the light emitting unit 120 and the coupling unit 111, and is formed to be transparent so that the light from the light emitting unit 120 can exit toward the container 200 (FIG. 3). In particular, it is preferable to be formed of a material (eg, quartz) through which ultraviolet rays can pass among the light of the light emitting unit 120. The window 140 protects the light emitting part 120 from liquid contained in the container 200.

The control unit 150 is electrically connected to the solar cell 130 and the light emitting unit 120, and the control unit 150 transmits electric energy supplied to the first semiconductor light emitting device 121 and the second semiconductor light emitting device 122. Control each. At the same time, the control unit 150 supplies electric energy to the second semiconductor light emitting device 122 when the first semiconductor light emitting device 121 is turned on, and the second semiconductor light emitting device when the first semiconductor light emitting device 121 is turned off. Control not to supply electrical energy to (122). The first semiconductor light emitting device 121 is constantly supplied with electrical energy, and the second semiconductor light emitting device 122 is periodically supplied with electrical energy. That is, the first semiconductor light emitting device 121 is continuously turned on, and the second semiconductor light emitting device 122 may flicker. Because, since the first semiconductor light emitting device 121 has an ultraviolet sterilization function, it is preferable to be continuously turned on. The second semiconductor light emitting device 122 may be difficult for the user to notice whether the second semiconductor light emitting device 122 is turned on if the second semiconductor light emitting device 122 is continuously turned on when the sun is intense or external light is bright. . To prevent this, the second semiconductor light emitting device 122 may be flashed so that the user can easily recognize that the second semiconductor light emitting device 122 is turned on. In addition, the control unit 150 controls the electrical energy supplied to the second semiconductor light emitting device 122 to blink (eg, supplying a pulse) to save a part of the electrical energy for turning on the second semiconductor light emitting device 122. . In addition, when the second semiconductor light-emitting device 122 flashes, if the amount of electric energy received by the second semiconductor light-emitting device 122 is increased, the user can recognize it better because it shines brighter than when the second semiconductor light-emitting device 122 flashes. The second semiconductor light emitting device 122 blinks in order to save electric energy generated from the solar cell 130. As the size of the solar cell 130 increases, the size of the electric energy may increase. However, since the size of the solar cell 130 is limited, it is desirable to save electric energy.

The reflector 160 surrounds the light-emitting part 120 and reflects light exiting the side of the light-emitting part 120 to induce it to go out toward the entrance 201 (FIG. 3) of the container 200. It is preferable that the width of the reflective part 160 is formed to be narrower than the width of the inlet 201 of the container 200. It is to sterilize the liquid contained in the container 200 without light hitting the inlet 201. Since the width of the inlet 201 of the container 200 is narrower than the width of the lower part of the container 200, it is important to send light from the first semiconductor light emitting device 121 toward the lower part of the container 200. In general, light from a semiconductor light emitting device has a wide radiation angle of 120 degrees or more, so that a lot of light moves to the lower portion of the container 200, causing loss. Unlike normal visible light, UVC light is mostly absorbed when hitting plastic. Therefore, in order to increase the sterilizing power, it is important to allow the light of the first semiconductor light emitting device 121 to emit light toward the bottom of the container 200 without hitting the container 200. To this end, a reflective unit 160 is provided around the first semiconductor light emitting device 121, and the reflective unit 160 is formed of a material having a high reflectance of UVC. For example, the reflective part 160 may be formed of aluminum or Teflon. It is preferable that the reflective part 160 is made of aluminum which is easy to form and inexpensive.

The switch 170 electrically connects 171 between the light emitting unit 120 and the solar cell 130 between the light emitting unit 120 and the solar cell 130 (Fig. 3), and the switch 170 is ON/OFF During operation, the electrical connection 171 is connected or disconnected. When the switch 170 is turned on (ON), the light emitting unit 120 and the solar cell 130 are electrically connected 171 to supply electric energy generated from the solar cell 130 to the light emitting unit 120 120 is turned on. In addition, when the switch 170 is turned off, the electrical connection 171 between the light emitting unit 120 and the solar cell 130 is disconnected, so that the electric energy generated from the solar cell 130 is not supplied to the light emitting unit 120, the light emitting unit ( 120) turns off.

The elastic body 180 is provided between the coupling part 111 and the container 200, is formed along the inlet 201 of the container 200, and the case 110 is formed by the elastic body 180 and the window 140. Can be sealed. The elastic body 180 and the window 140 prevent the liquid contained in the container 200 from flowing into the case 110. The elastic body 180 may be made of an elastic material such as silicone or rubber.

The fixing part 190 contacts the elastic body 180 and the window 140, and fixes the elastic body 180 and the window 140. In addition, the fixing part 190 has a hole 191 through which the elastic body 180 can contact the switch 170.

The first semiconductor light-emitting device 121 of the light-emitting unit 120 emits UVC, and in the case of UVC, if directly exposed to the eye or the human body, the eye or the human body may be damaged. Therefore, the light emitting unit 120 must be operated while the container 200 is coupled to the coupling unit 111. Therefore, the elastic body 180 and the switch 170 are positioned in contact with each other, and when the container 200 is mounted on the sterilization device 100 along the coupling part 111, the inlet 201 of the container 200 As the elastic body 180 is pressed, the elastic body 180 presses the switch 170 so that the switch 170 is in a connected state (ON). In addition, when the container 200 is released and the elastic body 180 and the inlet 201 of the container 200 are separated, the inlet 201 of the container 200 loses the force pressing the elastic body 180 and the switch 170 Is turned off. The fixing part 190 located between the elastic body 180 and the switch 170 includes a hole 191, and the elastic body 180 and the switch 170 contact through the hole 191 of the fixing part 190 do. For example, a part of the elastic body 180 may pass through the hole 191 to contact the switch 170, and a part of the switch 180 may pass through the hole 191 to contact the elastic body 180. have. That is, even if the solar cell 130 receives light to generate electric energy, if the container 200 and the coupling unit 111 are not coupled, the light emitting unit 120 does not operate and can be used safely.

In addition, the case 110 further includes a connection part 113, and the connection part 113 may be formed to penetrate a part of the case 110. Thin and thin objects such as strings, strings, and threads can be passed through the connection part 113. Through this, the sterilization device 100 can be easily carried, and a string or the like can be used as a necklace or a holder that can be hung on a bag or portable item. The connection part 113 is formed at the corner of the case 110 when the case 110 is square, and when worn as a necklace by connecting a string or the like to the connection part 113, the case 110 is located in a dry hair shape so that the user can stably use it. have.

The case 110 may further include a timer (not shown), and the timer may be electrically connected between the light emitting unit 120 and the solar cell 130. The timer may cut off the voltage after allowing a voltage to flow between the light emitting unit 120 and the solar cell 130 for a predetermined time. After the switch 170 is turned on, a voltage may be supplied to the light emitting unit 120 for a predetermined period of time, and then a timer may cut off the voltage.

6 is a view showing another example of the sterilization device according to the present disclosure.

6 shows an example of a rear view of the sterilizing device 100. The case 110 is provided with a coupling portion 111 in the lower surface direction, and the coupling portion 111 is formed on the inner side of the case 110. When the user carries the sterilization device 100, the coupling part 111 and the light emitting part 120 (FIG. 5) are provided inside the case 110 so that there is no part protruding to the outside, so that the coupling part 111 ) And the light-emitting unit 120 may be protected.

When viewed from the lower surface of the case 110, the coupling portion 111, the elastic body 180, and the window 140 are exposed. The elastic body 180 is provided to surround the window 140. A fixing part 190 fixing each other is provided between the elastic body 180 and the window 140.

Hereinafter, various embodiments of the present disclosure will be described.

(1) A sterilization device coupled to a container, comprising: a case including a coupling portion coupled to the container; A light-emitting unit provided in the case and including a first semiconductor light-emitting device emitting light toward the interior of the container and emitting ultraviolet rays; And, a solar cell provided in the case, electrically connected to the light-emitting unit, and supplying electric energy to the light-emitting unit.

(2) A sterilization device in which the coupling part is concave from the bottom of the case to the inside of the case.

(3) A sterilizing device formed on the inner side of the coupling part.

(4) An elastic body provided in the case and pressed by the container.

(5) A switch that connects or disconnects the electric connection between the light emitting unit and the solar cell.

(6) an elastic body provided in the case and pressed by the container; And, a switch connecting or disconnecting the electrical connection between the light emitting unit and the solar cell; including, the switch is operated by the container, the elastic body pushed by the container pushes the switch to operate the switch.

(7) an elastic body provided in the case and pressed by the container; And, a switch connecting or disconnecting the electrical connection between the light emitting unit and the solar cell; including, a sterilization device in which the switch and the elastic body are in contact.

(8) A sterilizing device that maintains the connected state of the switch by fastening the joint and the container.

(9) A sterilizing device further comprising a; window provided in a direction in which light of the light emitting unit exits.

(10) A sterilization device further comprising a; reflective wall surrounding the light-emitting unit and collecting light so that the light of the light-emitting unit is directed to the interior of the container.

According to one sterilizing device according to the present disclosure, it can be easily portable.

According to another sterilization device according to the present disclosure, it is possible to sterilize the container without requiring a separate supply of electricity.

100: sterilization device 110: case 111: coupling portion 120: light emitting portion
121: first semiconductor light emitting device 122: second semiconductor light emitting device 130: solar cell 140: window 150: control unit 160: reflection unit 170: switch
171: electrical connection 180: elastic body 190: fixed part 191: hole

Claims (10)

In the sterilization device coupled to the container,
A case including a coupling portion coupled to the container;
A light emitting unit provided in the case, emitting light toward the inside of the container, and including a first semiconductor light emitting device emitting ultraviolet rays; And,
A sterilization device comprising a; solar cell provided in the case, electrically connected to the light emitting unit, and supplying electric energy to the light emitting unit. The method according to claim 1,
A sterilizing device in which the coupling part is concavely formed from the lower surface of the case to the inside of the case. The method according to claim 2,
A sterilizing device formed on the inner side of the coupling portion. The method of claim 3,
Sterilizing device including; an elastic body provided in the case and pressed by the container. The method of claim 4,
Sterilizing device comprising a; switch connecting or disconnecting the electrical connection between the light emitting unit and the solar cell. The method according to claim 1,
An elastic body provided in the case and pressed by the container; And,
Includes; a switch connecting or disconnecting the electrical connection between the light emitting unit and the solar cell,
A sterilizing device in which a switch is operated by a container and an elastic body pushed against the container pushes the switch. The method according to claim 1,
An elastic body provided in the case and pressed by the container; And,
Includes; a switch connecting or disconnecting the electrical connection between the light emitting unit and the solar cell,
A sterilization device in which the switch and the elastic body come into contact. The method of claim 7,
A sterilization device that maintains the connected state of the switch by fastening the joint and the container. The method according to claim 1,
A sterilizing device further comprising a; window provided in a direction in which light of the light emitting unit exits. The method according to claim 1,
A sterilizing device further comprising a; reflective wall surrounding the light emitting portion and collecting light so that the light of the light emitting portion is directed toward the interior of the container.

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