KR100775747B1 - Airsole injecting device having container lifting means - Google Patents

Abstract

An aerosol injecting device having a container lifting unit is provided to enable the solution inside an aerosol vessel to be sprayed upwardly by ascending the aerosol container inside the aerosol injecting device. An aerosol injecting device having a container lifting unit includes a body portion(300), a cover portion(400), a container lifting unit, and an aerosol container(7). The cover portion is coupled to an upper part of the body portion to form a space in which the aerosol container is disposed. An injection hole coupling recess(400a) is formed on the cover portion. The aerosol container is disposed on the upper surface of the body portion, and is ascended by the container lifting unit to press a nozzle part(7a) to inject the aerosol in the state that the ascending of a nozzle part(7a) is restrained by the cover portion.

Description

Aerosol injecting device having container lifting means

1 is a cross-sectional view showing a conventional aerosol injector

Figure 2 is a perspective view of another conventional aerosol injector

3 is a perspective view of an aerosol injection device provided with a container lifting means according to an embodiment of the present invention

4 is a cross-sectional view showing a rotation means of the container lifting means of FIG.

5 is a perspective view of a driven cam and a drive cam of the container lifting means of FIG.

Figure 6 is a cross-sectional view showing the operation of the drive cam of the container lifting means of Figure 3 lifting / lowering

7 is a perspective view showing the supporter of the container lifting means of FIG.

<Description of the symbols for the main parts of the drawings>

300: body 400: cover 500: rotation means

600: driven cam 700: drive cam 800: supporter

The present invention relates to an aerosol injector having a container elevating means, and more particularly, to enable the upward spraying of the solution inside the aerosol container through the elevating means, and pressurizes the nozzle of the aerosol container on the top of the aerosol container. It is possible to miniaturize the aerosol injector by eliminating a separate device, thereby relates to an aerosol injector equipped with a container lifting means to implement a variety of design regardless of size.

In general, an aerosol injector is a device for injecting a solution inside an aerosol container such as a fragrance by pressing the nozzle portion of the aerosol container automatically according to a time set in a state in which the aerosol container, which stores the fragrance, etc. is fastened inside or outside. In the related art, a device using a large gear and a device using a tangential cam are largely divided. Referring to FIGS. 1 and 2, the structure of a conventional aerosol injection apparatus is as follows.

In the conventional aerosol injector using the recreation gear 35, as shown in Figure 1, the motor 20 is fixed to the press 10, the motor gear 31 is attached to the motor shaft, The reduction gear 1 (32) is engaged with the gear 31, the reduction gear 2 (33) is engaged with the reduction gear 1 (32), thereby increasing the gear ratio, and the reduction gear 2 (33) is a drive gear By engaging with 35) and descending in the vertical direction, it is a structure for pressing the nozzle portion 9 of the liquid bottle to spray the internal solution, a conventional aerosol injector using a tangential cam 260, as shown in Figure 2, The motor 220 is fixed to the press material 240, the motor gear 231 is attached to the motor shaft, the reduction gear 232 is meshed with the motor gear 231, thereby increasing the gear ratio, deceleration The gear 232 is meshed with the gear of the tangential cam 260 to rotate the tangential cam 260, thereby spherical To press the tooth 251 to spray the internal solution. At this time, the stopper 263 of the tangential cam 260 is caught by the stopper shaft 264 to stop the operation due to an overcurrent check. 7) The nozzle 9 pushes the spherical switch 251 upwards by the spring inside, which causes the tangential cam 260 to return to the position before the injection and finish the single injection.

However, in the conventional structure as described above, since a separate device for pressurizing the nozzle of the aerosol container at the top of the aerosol container, such as a liquid bottle, must be configured, it is impossible to inject the aerosol container solution such as a fragrance into the scent and thus the injection efficiency. In addition to the reduction, the volume of the entire injector is increased due to the separate pressurization device, which not only reduces the production efficiency but also makes it impossible to apply various designs.

The present invention is to solve the above-mentioned problems, in particular, the present invention constitutes a container lifting means for lifting the aerosol container on the upper surface of the body portion of the aerosol injector by lifting the aerosol container itself in the device, In addition to enabling upward spraying of the solution inside the container, a separate device for pressurizing the nozzle of the aerosol container at the top of the aerosol container can be eliminated, resulting in miniaturization of the aerosol injector, resulting in various designs regardless of size. An object of the present invention is to provide an aerosol injection device having a container lifting means to be implemented.

Features of the present invention for achieving the above object, the body portion; A cover portion formed at an upper portion of the body portion to form a space in which the aerosol container can be positioned, and formed with an injection hole binding groove in which one end of the injection hole into which the internal solution of the aerosol container is injected is formed; A container lifting means configured on an upper portion of the body part to lift / lower the aerosol container; Located in the upper surface of the container elevating means, the lifting by the container elevating means in the state in which the rise of the nozzle portion is suppressed by the lid portion is pressed by the nozzle, the internal solution of the aerosol container is injected from the nozzle of the nozzle An aerosol injector having a container lifting means including an aerosol container.

Container lifting means according to a feature of the present invention, the rotating means for rotating the driven cam is located on the upper surface of the body portion; A driven cam that rotates by the rotation means, the gear part is coupled to the rotation means to transmit a rotational force to a lower part, and a lift / lowering induction part configured to induce a lifting / lowering operation of the drive cam on the upper part; It is fastened to the upper portion of the driven cam, the lower and lower portion is bound with the lifting / lowering induction portion is configured to move up / down in response to the rotation of the lifting / lowering induction portion, the container support for supporting the aerosol container on the top A drive cam having a surface formed thereon; And a supporter part for supporting the drive cam to prevent the separation during the rotational movement of the drive cam, and for allowing the aerosol container to be easily seated on the upper surface of the container cam of the drive cam. Can be.

In the above embodiment, the rotation means includes: a motor gear connected to the motor through the motor shaft to transmit rotational power of the motor to the reduction gear; One end is coupled to the motor gear, the other end is coupled to the gear portion of the driven cam may comprise an embodiment comprising a reduction gear for transmitting the rotational force of the motor gear to the gear portion of the driven cam.

Further, in the above embodiment, the lifting / lowering induction part of the driven cam includes two lowering parts in the horizontal direction on the same line as the upper surface of the gear part of the driven cam, and two vertically at positions higher than the upper surface of the gear part. The lifting unit is configured, an inclined surface that can reach the lifting unit from the lowering portion is formed, it can be configured an embodiment in which the lowering unit and the lifting unit is connected by the inclined surface.

In addition, in the above embodiment, the up / down driving part of the driving cam includes one or two moving parts in a horizontal or vertical direction at a position extending downward from the lower surface of the container supporting surface of the driving cam, wherein the container is supported. The inclined surface that can reach the moving portion from the surface is formed, the container can be configured by the inclined surface and the lower surface and the moving portion is configured to be configured.

In addition, the drive cam in the above embodiment, when the drive cam is moving up / down, a plurality of guide ribs are configured on the side surface of the container holding surface of the drive cam can be configured to be an embodiment that can be firmly supported by the supporter portion have

In addition, in the above embodiment, the supporter part may configure an embodiment in which a support groove in an oblique direction corresponding to the rising / falling copper wire of the guide rib according to the lifting / lowering operation of the driving cam is configured.

In each of the above embodiments, the driving cam is moved in a state in which the driving cam is attached to the upper portion of the driven cam, that is, the driven cam is rotated 1/2 in a state where the moving part of the driving cam is located at the lower portion of the driven cam. In this case, the moving part of the driving cam reaches the lifting part along the inclined surface connecting the lowering part and the lifting part of the lifting / lowering induction part of the driven cam, and the driving cam moves up and down, and the driving cam is lifted up and down. That is, when the driven cam is rotated 1/2 turn while the moving part of the driving cam is located at the lifting part of the driven cam, the moving part of the driving cam connects the lifting part and the lower part among the lifting / lowering induction parts of the driven cam. As it reaches the lower portion, it can be configured an embodiment in which the drive cam is lowered operation.

The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and effect of the preferred embodiment of the present invention.

Figure 3 is a perspective view of an aerosol injector equipped with a container lifting means according to an embodiment of the present invention, showing the overall configuration of the present invention. That is, the aerosol injector provided with the container lifting means of the present invention, comprising a body portion 300, the cover 400, and the container lifting means, the aerosol container at the top of the body portion 300 Forming a space in which the (7) can be located and the cover portion 400 is coupled, of the nozzle (7a) portion of the aerosol container (7) to the injection hole binding groove (400a) formed on the cover portion 400, In a state where one end of the injection hole 7b through which the internal solution of the aerosol container 7 is injected is bound and combined,

When the aerosol container 7 is raised and lowered by the container lifting means configured on the upper surface of the body portion 300, the nozzle 7a portion of the aerosol container 7 is suppressed by the cover portion 400 at the same time. The aerosol container 7 is continuously raised to pressurize the nozzle 7a so that the internal solution of the aerosol container 7 is injected from the injection port 7b of the nozzle 7a.

4 is a cross-sectional view showing a rotation means of the container lifting means for lifting the aerosol container, Figure 5 is a perspective view of the driven cam and the drive cam of the container lifting means of Figure 3, Figure 6 is a container of Figure 3 Fig. 7 is a sectional view showing the lifting / lowering operation state of the driving cam of the lifting means, and Fig. 7 is a perspective view showing the supporter of the container lifting means of Fig. 3, showing the container lifting means of the present invention and its operation principle. That is, the container lifting means of the present invention comprises a rotating means 500, driven cam 600, drive cam 700, and the supporter portion 800.

The rotating means 500 is for rotating the driven cam 600 to be described later, as shown in Figure 4, the motor gear 51 is connected to the motor 50 through the motor shaft of the motor 50 When the rotational power is transmitted to the reduction gear 52, the reduction gear 52 having one end coupled to the motor gear 51 and the other end coupled to the gear portion 60a of the driven cam 600 is the motor gear ( By transmitting the rotational force of 51 to the gear portion 60a of the driven cam 600, the driven cam 600 is rotated,

The driven cam 600 is rotated by the rotating means 500, and the driving cam 700 to be described later is capable of lifting / lowering, as shown in FIG. The gear unit 60a is coupled to the 500 to transmit the rotational force, and a lift / fall induction unit 60b is configured to induce a lift / lower operation of the drive cam 700 at an upper portion thereof.

The lifting / lowering induction part 60b of the driven cam 600 induces easy lifting / lowering operation of the driving cam 700 to be described later, and the upper surface of the gear part 60a of the driven cam 600. Two lowering portions 60d are formed in the horizontal direction on the same line, and two lifting portions 60c are configured in the vertical direction at a position higher than the upper surface of the gear portion 60a. An inclined surface capable of reaching the lifting unit 60c is formed, and the lowering unit 60d and the lifting unit 60c are connected by the inclined surface.

The driving cam 700 is coupled to an upper portion of the driven cam 600 to operate in response to the rotation of the lifting / lowering induction part 60b of the driven cam 600, as shown in FIG. 5. As described above, the lifting / lowering driving part 70a that is engaged with the lifting / lowering induction part 60b is configured at the lower part, and the container supporting surface 70b is configured to support the aerosol container 7 at the upper part.

The driving cam 700 of the driving cam 700 in response to rotation of the lifting / falling induction part 60b in a state of being bound to the raising / lowering induction part 60b of the driven cam 600 is driven. In order to allow the 700 to move up and down, two moving parts 70c are formed in a horizontal or vertical direction at a position extending downward from the lower surface of the vessel supporting surface 70b of the drive cam 700. However, an inclined surface that can reach the moving portion 70c from the container supporting surface 70b is formed, and the lower surface of the container supporting surface 70b and the moving portion 70c are connected by the inclined surface.

The operation principle of the lift / fall induction part 60b of the driven cam 600 configured as described above and the lift / fall driver 70a of the drive cam 700 will be described with reference to FIGS. 5 and 6 as follows.

The lifting operation of the driving cam 700 is a state in which the driving cam 700 is attached to an upper portion of the driven cam 600, that is, the moving part 70c of the driving cam 700 moves downward of the driven cam 600. When the driven cam 600 rotates 1/2 in the state of being positioned at 60d, the moving part 70c of the driving cam 700 moves up / down inducing part 60b of the driven cam 600, and the lowering part ( Reach to the lifting unit 60c along the inclined surface connecting 60d) and the lifting unit 60c, the drive cam 700 is moved up and down,

The lowering operation of the drive cam 700 is a state in which the drive cam 700 is lifted, that is, in a state in which the moving part 70c of the drive cam 700 is located at the lifting part 60c of the driven cam 600. When the driven cam 600 rotates 1/2, the moving part 70c of the driving cam 700 moves up and down the induction part 60b of the driven cam 600, and the lifting part 60c and the lowering part ( Along the inclined surface connecting the 60d) to reach the lower portion (60d), the drive cam 700 is lowered.

That is, the aerosol container 7 is raised and lowered once by one rotation of the driven cam 600, thereby allowing the internal solution of the aerosol container 7 to be injected once.

Meanwhile, as shown in FIGS. 5 and 6, the moving part 70c of the driving cam 700 and the lifting part 60c of the driven cam 600 may be manufactured in an angular shape having an end thereof at an angle. In consideration of wear and rotation of the mobile unit 70c and the lifting unit 60c, smoothness of rotation, durability, and the like, it is also possible to produce a curved shape having a gentle arc.

In addition, as the drive cam 700 moves up and down as described above, as shown in FIG. 5, a plurality of guide ribs 70d are formed at the side of the container supporting surface 70b of the drive cam 700. By being fastened to the support groove 80a of the supporter part 800 which will be described later, the drive cam 700 is firmly supported by the supporter part 800 and can move up / down.

The supporter part 800 supports the driving cam 700 to prevent its departure during the rotational movement of the driving cam 700, and the aerosol container 7 supports the container support surface 70b of the driving cam 700. As shown in FIG. 7, the copper wire of the guide rib 70d generated according to the lifting / lowering operation of the driving cam 700, that is, the guide rib 70d may be easily mounted on the upper part. The support groove 80a in an oblique direction corresponding to the rising / falling copper wire of the driving cam 700 can be easily lifted / lowered.

The aerosol injector provided with the container elevating means of the present invention having the above structure, the aerosol container (7) without a separate device for pressing the nozzle (7a) portion of the aerosol container (7) from the upper end of the aerosol container (7) By elevating itself to pressurize the nozzle 7a portion and thereby spraying the internal solution of the aerosol container 7, not only enables the upward spraying of the internal solution of the aerosol container 7 but also the size of the device can be miniaturized. Allows the design to be implemented.

In addition to the present invention, the aerosol injector provided with the container lifting means can be variously modified, and the embodiments to be modified should all be included in the scope of the present invention without departing from the scope of the present invention. .

According to the present invention, by elevating the aerosol container itself, not only enables the upward injection of the solution inside the aerosol container, but also eliminates a separate device for pressurizing the nozzle of the aerosol container at the top of the aerosol container, miniaturizing the aerosol injection device This gives you the benefits of being able to implement a variety of designs of any size.

Claims (8)

In the aerosol injector, Body 300; An injection hole is formed in the upper portion of the body portion 300 to form a space in which the aerosol container 7 can be located, and the internal solution of the aerosol container 7 is injected among the nozzles 7a of the aerosol container 7. A cover portion 400 in which an injection hole binding groove 400a at which one end of the 7b is fixed is formed; A container lifting means configured at an upper portion of the body part 300 to lift / lower the aerosol container 7; Located in the upper surface of the container elevating means, by raising and lowering by the container elevating means in the state in which the rise of the nozzle 7a portion is suppressed by the lid 400, the nozzle 7a is pressed, thereby the nozzle 7a An aerosol injector equipped with a container elevating means, characterized in that it comprises an aerosol container (7) in which the internal solution is injected from the injection port (7b) of. The container lifting means is according to claim 1, Rotating means 500 is located on the upper surface of the body portion 300 to rotate the driven cam 600; Is rotated by the rotating means 500, the lower portion is coupled to the rotating means 500, the gear portion 60a for transmitting a rotational force is configured, the driving cam 700 to induce the lifting / lowering operation A driven cam 600 configured to have a lifting / lowering induction part 60b; The lift / fall driving part 70a, which is fastened to the upper portion of the driven cam 600 and bound to the lift / fall induction part 60b at the lower part, corresponds to the rotation of the lift / fall induction part 60b. A drive cam 700 having a container supporting surface 70b configured to support an aerosol container 7 thereon; During the rotational movement of the drive cam 700, the drive cam 700 is supported to prevent the separation, and the aerosol container 7 can be easily seated on the vessel supporting surface 70b of the drive cam 700. An aerosol injection device provided with a container lifting means comprising a; supporter portion 800 to ensure. The method of claim 2, wherein the rotating means 500, A motor gear 51 connected to the motor 50 through a motor shaft to transfer rotational power of the motor 50 to the reduction gear 52; One end is fastened to the motor gear 51 and the other end is fastened to the gear part 60a of the driven cam 600 to transfer the rotational force of the motor gear 51 to the gear part 60a of the driven cam 600. An aerosol injection device provided with a container lifting means, characterized in that it comprises a reduction gear (52). The method of claim 2, wherein the rising / falling induction part 60b of the driven cam 600, Two lowering portions 60d are formed in the horizontal direction on the same line as the upper surface of the gear portion 60a of the driven cam 600, and two lifting portions are vertically lifted at a position higher than the upper surface of the gear portion 60a. The unit 60c is configured, but the inclined surface that can reach the lifting unit 60c from the lowering unit 60d is formed, and the lowering unit 60d and the lifting unit 60c are connected by the inclined surface. An aerosol injection device provided with a container lifting means, characterized in that. According to claim 2, The driving cam 700, the lifting / lowering driving portion 70a, One or two moving parts 70c are formed in a horizontal or vertical direction at a position extending downward from a lower surface of the container supporting surface 70b of the drive cam 700, and the container supporting surface 70b An inclined surface capable of reaching the moving part 70c is formed, and the lower surface of the container supporting surface 70b and the moving part 70c are connected to each other by the inclined surface. Device. The method of claim 2, wherein the drive cam 700, When the driving cam 700 moves up and down, a plurality of guide ribs 70d are formed on the side of the container supporting surface 70b of the driving cam 700 so as to be firmly supported by the supporter 800. An aerosol injection device provided with a container lifting means, characterized in that. The method of claim 4 or 5, wherein the driving cam 700 of the lifting / lowering operation, The driving cam 700 is attached to the upper portion of the driven cam 600, that is, the moving cam 70c of the driving cam 700 is located in the lower portion 60d of the driven cam 600. When 600 is rotated 1/2, the moving part 70c of the driving cam 700 connects the lowering part 60d and the lifting part 60c among the lifting / lowering induction parts 60b of the driven cam 600. Reach to the lifting unit 60c along the inclined surface, the drive cam 700 is a lifting operation, In the state where the driving cam 700 is lifted, that is, the moving part 70c of the driving cam 700 is located at the lifting part 60c of the driven cam 600, the driven cam 600 is 1/2. When it rotates, the moving part 70c of the drive cam 700 descends along the inclined surface which connects the lifting part 60c and the lowering part 60d among the lifting / lowering induction parts 60b of the driven cam 600. 60d, the aerosol injection device provided with the container lifting means, characterized in that the drive cam 700 is lowered operation. The method of claim 6, wherein the supporter portion 800, The aerosol injector provided with the container lifting means, characterized in that the support groove (80a) in the diagonal direction corresponding to the lifting / lowering copper wire of the guide rib 70d according to the lifting / lowering operation of the drive cam 700 is configured. .

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