KR20100134603A - Aerosol dispenser - Google Patents

Abstract

An aerosol dispenser includes a dispensing head (1) adapted to attach to an aerosol container (2). The dispensing head (1) includes an enablement mechanism (8) and a docking mechanism (9) and the container (2) includes an enablement projection (3) and a docking projection (10). The docking mechanism (9) releasably engages the docking projection (10) to attach the dispensing head (1) to the container (2) such that the enablement projection (3) engages the enablement mechanism (8) to place the aerosol dispenser into an operable condition.

Description

Aerosol Dispenser {AEROSOL DISPENSER}

The present invention relates to an aerosol dispenser and, more particularly, to an aerosol dispenser which is selectively activated so that aerosol injection is automatic.

Aerosol dispensers are known in various forms. International Publication No. WO 95/19304, for example, describes an automatic aerosol dispenser for discharging a flowing substance provided in liquid form, such as an insect repellent, an air freshener or an odor neutralizer. Typically, such dispensers have at least two portions corresponding to the discharge head and the refill container for storing the flowing material.

When such an aerosol dispenser is activated, the fluid is intermittently discharged as a spray until it is deactivated, powered off or the fluid material is used up.

However, when activated, the discharge mechanism will be activated periodically regardless of whether or not the refill container is attached to the discharge head. This may occur when the activating means (eg a switch or button) is pressed suddenly. This wears out the discharge mechanism over time and creates the need to replace the entire unit only in contrast to the refillable container.

It is an object of the present invention to provide an aerosol dispenser that overcomes or ameliorates some of the above mentioned disadvantages and at least provides a useful choice to the public.

Other objects of the present invention will become apparent from the following detailed description, which is given only by way of example.

In a broad sense, one aspect of the present invention includes a discharge head suitable for cooperating or connecting with a pressurized vessel fitted with a collar to place an automatic aerosol dispenser in an operational state, wherein the discharge head may be activated.

In a broad sense, one aspect of the invention includes the pressurized vessel attached to the discharge head to provide pressurized contents from the pressurized vessel. The container includes an ejection head docking projection and an enablement projection.

The discharge head docking projection extends from the top surface of the container where contents can be discharged or discharged under the control of the discharge head when docked and activated into the container.

The implementation projection extends from the upper surface of the vessel and operates the enablement mechanism of the ejection head and is in operation or activated with another control input when the contents of the vessel are released from the vessel through the ejection head. To be discharged.

In one embodiment, the docking projection protrudes from the upper surface of the container and mates with the complementary opening of the docking mechanism of the discharge head. Advantageously, said complementary opening of said docking mechanism comprises a threaded component. More preferably, the docking projection includes a valve.

In one embodiment, the implementation projection at least partially surrounds the docking projection. Advantageously, said implementation projection completely surrounds said docking projection. More preferably, the implementation projection surrounds the docking projection in a contoured manner.

In one embodiment, the implementation projection is integrally formed with the valve cap.

In one embodiment, the implementation projection is fitted onto the upper surface of the pressure vessel. Preferably, the implementation projection is fixed to a position next to the docking projection. More preferably, the implementation projection is fixed onto the upper surface of the pressure vessel next to the docking projection.

In one embodiment, the implementation mechanism contacts the implementation projection directly or indirectly when the pressure vessel is fully docked with the discharge head. Advantageously, said docking produces a displacement of said implementation mechanism, whereby said discharge head is positioned in an operational state. More preferably, the actuation mechanism comprises a cam and operates the switch to position the discharge head in an operational state when displacement occurs.

In one embodiment, the implementation mechanism switch is connected directly or indirectly to the printed circuit board. Here, the displacement of the cam according to the docking of the pressure vessel displaces the implementation mechanism switch transversely to position the discharge head in an operating state. Preferably, the cam is biased downwards. More preferably, the spring causes the cam to deflect downward.

In one embodiment, the discharge head is activated by a switch, button or lever separate from the implementation mechanism. Preferably, the activation of the discharge head is via a switch.

In a broad sense, one aspect of the invention includes an assembly, combination or kit, a discharge head with a docking mechanism and a fluid passageway disposed through the docking mechanism to control the ejection of flow material. The pressurized vessel may be docked with the docking mechanism or docked with the docking mechanism for discharging flowable material from the vessel when activated. The discharge head and vessel start from the docking projection to effect direct discharge or to interact with the discharge head providing discharge from the discharge head of the fluid material from the vessel with another control input to the discharge head. Has an interactive feature set out.

In one embodiment, the docking projection of the vessel is docked with the discharge head in complementary interaction. Preferably, the pressurized container and the dockable projection and the discharge head docking mechanism are docked through complementary screw connections.

In one embodiment, the projection from the upper surface of the pressurized container is paired with the corresponding feature of the discharge head. Preferably, the implementation projection partially or wholly surrounds the docking mechanism of the discharge head and contacts the implementation mechanism of the discharge head directly or indirectly. More preferably, the implementation projection causes a displacement upward of the implementation mechanism when the pressure vessel is docked with the discharge head.

In one embodiment, the docking of the pressure vessel and the discharge head results in contact of the interaction features of the discharge head and the pressure vessel to place the assembly in operation.

In one embodiment, the implementing mechanism is a moving switch. When the discharge head is docked with the pressure vessel, the switch is displaced upward by the real projection of the pressure vessel. Preferably, the implementation mechanism is biased downwards (preferably by a spring). More preferably, the implementation mechanism comprises a cam and a switch.

In one embodiment, the actuation mechanism is a cam and an activation switch. The displacement of the cam due to the docking of the pressurizing vessel and the discharge head causes the displacement of the cam to be caused upward by the implementation projection, whereby the switch is laterally displaced and the assembly is placed in an operating state. Preferably, the switch comprises a displacement member connected with the printed circuit board. More preferably, the cam is in contact with the switch and displaces the switch laterally when displacement occurs.

In a broad sense, one aspect of the invention includes the docking feature of a complementary pressure vessel. The docking feature can guide the liquid discharged from the docked vessel under control of the discharge head. At least one embodiment feature is provided in the pressurized container, which feature is contoured to surround the docking feature of the container and relies on interaction with a portion of the discharge head.

In a broad sense, one aspect of the invention includes a method for directing liquid material from a pressurized vessel into the atmosphere. The method includes the following steps.

1. Docking or starting with a discharge head comprising a docking mechanism, a fluid passageway and an actuation mechanism together with a pressurized vessel containing a flow material and comprising a docking projection and an execution projection;

2. contacting the implementation projection directly or indirectly with the implementation mechanism such that displacement of the implementation mechanism in an upward direction occurs when the discharge head and the pressure vessel are docked;

3. activating a switch to position the discharge head in an operational state by displacement of the actuation mechanism in the upward direction; And

4. activating said discharge head such that spraying of said liquid substance out of said discharge head via said fluid passage.

In one embodiment, the implementing mechanism comprises a cam for activating the switch. Preferably, the cam causes the switch to be transversely displaced. More preferably, the cam is in direct contact with the implementation projection. In one embodiment, the discharge head and the pressure vessel are docked together using threaded parts.

In one embodiment, the upward displacement of the cam produces a transverse displacement of the switch in connection with a printed circuit board. The transverse displacement of the switch positions the discharge head in an operational state. In one embodiment, the pressurized container merely places the discharge head in operation when the pressurized container is fully docked with the discharge head. Preferably, complete docking occurs when the pressure vessel is fully screwed into the discharge head via the docking projection and the docking mechanism.

In one embodiment, the cam is biased downwards. Preferably, the deflection is mediated by spring action.

Other aspects of the present invention will become apparent from the detailed description given in an exemplary manner with reference to the accompanying drawings.

Here, "and / or" means "and", "or" or both.

Here, "(s)" following the word means a word in the plural and / or singular form.

"Comprises" is used herein in the sense of "consisting of at least a portion". When in the present description such words, features and the present specification containing the words are to be interpreted, all need to be presented but other features may also be presented. Related words such as "include" and "included" are interpreted in the same manner.

The invention broadly also includes parts, components, and features, individually or collectively, referenced and indicated in the specification of this application, including any two or more combinations of any two or more of the parts, components, or features, It is to be understood that certain integers known as equivalents in the art relating to the present invention are mentioned, and the known equivalents presented are considered to be incorporated into the present invention.

An aerosol dispenser is disclosed that operates only when a correctly configured aerosol container is fully mounted therein. The aerosol dispenser remains inoperable in the absence of an aerosol container, thereby reducing energy use and restricting the wear of the dispenser mechanism from additional wear.

It will be apparent to those skilled in the art that many modifications may be made to the invention in light of the detailed description. Accordingly, this specification should be understood to be illustrative only and discloses the best embodiments to enable those skilled in the art to make and use the invention. Exclusive rights to all modifications are expressly intended within the scope of the claims set out below. All patents, patent publications and applications, and other references are incorporated herein by reference in their entirety.

The invention will be described in an illustrative manner only with reference to the drawings.
1a is a perspective view of a pressurized container according to the prior art,
1B is a perspective view according to one embodiment of the pressure vessel,
2 is a schematic view showing a partial cross section of one embodiment of a discharge head docked with a pressurized container according to one embodiment;
3 is a schematic view showing a partial cross section of the discharge head of FIG. 2 docked with a pressure vessel according to another embodiment;
4 is a schematic view showing a partial cross section of the discharge head of FIG. 2 connected to a pressure docking according to another embodiment;
5 is a schematic view showing a partial cross section of another embodiment of a discharge head docked with the pressure vessel of FIG. 2, FIG.
6A is a schematic diagram showing implementation mechanism and implementation projection in an inoperative state;
6B is a schematic diagram showing implementation mechanism and implementation projection in an operational state.

Broadly speaking, a discharge head 1 suitable for cooperating with or associated with a pressurized container 2 fitted with an enablement projection 3 such as a collar activated to position the discharge head 1 in an operative state is provided. Are described.

The pressurized container 2 described here is attached with a discharge head 1 for discharging the pressurized contents from the container 2. The container 2 comprises a discharge head docking projection 10 and an implementation projection 3.

The discharge head docking projection 10 is top surface 6 of the container 2 through which contents can be discharged or discharged under the control of the discharge head 1 when docked and activated by the pressure vessel 2. ).

The implementation projection 3 extends from the upper surface 6 of the pressurized vessel 2 capable of operating or operating an enablement mechanism 8 of the discharge head 1, in an operational state. Alternatively, when there is another control input, when activated, the contents of the container 2 can be discharged from the container 2 via the discharge head 1.

In one embodiment, the docking projection 10 protrudes from the upper surface 6 of the container 2 and mates with the complementary docking mechanism 9 of the discharge head 1. Preferably, the complementary docking mechanism 9 is a screw part. More preferably, the docking mechanism 9 comprises a valve 4.

In one embodiment, the implementation projection 3 at least partially surrounds the docking projection 10. Preferably, the implementation projection 3 completely surrounds the docking projection 10. More preferably, the implementation projection 3 surrounds the docking projection 10 in a contoured manner.

In one embodiment, the implementation projection 3 is fitted onto the upper surface 6 of the pressure vessel 2. Preferably, the implementation projection 3 is fixed at a position next to the docking projection 10. More preferably, the implementation projection 3 is fitted onto the upper surface 6 of the pressure vessel 2 next to the docking projection 10.

In one embodiment, the implementation projection 3 is integrally formed with the valve cap 16.

In one embodiment, the implementation mechanism 8 is in direct or indirect contact with the implementation projection 3 when the pressure vessel 2 is fully docked with the discharge head 1. Preferably, the docking produces a displacement of the implementation mechanism 8, whereby the discharge head 1 is placed in an operating state. More preferably, the implementation mechanism 8 comprises a cam 5 and operates the switch 11 to position the discharge head 1 in an operational state when displacement occurs.

In one embodiment, the implementation mechanism switch 11 is connected directly or indirectly to the printed circuit board 12. Here, the displacement of the cam 5 according to the docking of the pressure vessel 2 displaces the implementation mechanism switch 11 transversely to position the discharge head 1 in an operating state. Preferably, the cam 5 is deflected downwards. More preferably, a spring (not shown) causes the cam 5 to deflect downward.

In one embodiment, the discharge head 1 is activated by a switch, button or lever 13 or the like which is separate from that of the implementation mechanism 8. Preferably, activation of the discharge head 1 takes place via the switch 13.

Described here is an assembly, combination or kit comprising a discharge head 1 with a docking mechanism 9 and a fluid passageway therefrom arranged for controlled flow of the discharged material. The pressurized vessel 2 may be docked with the docking mechanism 9 or docked with the docking mechanism 9 for discharging the flowing material from the vessel 2 when activated. The discharge head 1 and the vessel 2 carry out the discharge of the flowing material from the discharge head 1 from the vessel 2 with the implementation of direct discharge or with another control input to the discharge head 1. Has an interaction feature set out from the docking projection 10 to interact with the discharge head 1 providing.

In one embodiment, the docking projection 10 is docked with the discharge head 1 in a complementary interaction. Preferably, the pressurized vessel and the dockable projection 10 and the discharge head docking mechanism 9 are docked via complementary threaded parts connections.

In one embodiment, the interaction feature comprises an implementation projection 3 extending from the upper surface 6 of the pressure vessel 2 and mating with the discharge head 1. Preferably, the implementation projection 3 in direct or indirect contact with the docking mechanism 9 of the discharge head 1 surrounds the docking projection 10 in part or in whole. More preferably, the implementation projection 3 causes a displacement upward of the implementation mechanism 8 when the pressure vessel 2 is docked with the discharge head 1.

In one embodiment, the docking of the pressurized container 2 and the discharge head 1 results in contact of the interaction features of the discharge head 1 and the pressurized container 2 to place the assembly in operation. .

In one embodiment, the discharge head implementation mechanism 8 is displaced upward by the implementation projection 3 of the pressure vessel 2 when the discharge head 1 together with the pressure vessel 2 is docked. It is a transfer switch. Preferably, the actuation mechanism 8 is deflected downwards (preferably by a spring). More preferably, the implementation mechanism 8 comprises a cam 5 and a switch 11.

In one embodiment, the implementation mechanism 8 of the discharge head 1 is a cam 5 and an activation switch 11. The displacement of the cam 5 due to the docking of the pressurized container 2 and the discharge head 1 causes the displacement of the cam 5 to be generated upward by the implementation projection 3, thereby The switch 11 is laterally displaced and the assembly is placed in an operating state. Preferably, the switch 11 comprises a displacement member connected to the printed circuit board 12. More preferably, the cam 5 is brought into contact with the switch 11 and displaces the switch 11 laterally when displacement occurs.

Described here is a docking projection 10 of a pressurized vessel 2, such as a docking projection 10, which can duct liquid discharged from such as a docked vessel under the control of a discharge head 1. The discharge head 1 comprises at least one docking mechanism 9. The pressurized container 2 depends on the interaction with the part of the discharge head 1 by the contour part around the dockable feature 10 of the container.

Described herein is a method for spraying inducible material from a pressurized vessel to the environment, the method comprising the following steps.

1. a pressurized vessel containing a discharge head 1 comprising a docking mechanism 9, a fluid passageway (not shown) and an implementation mechanism 8 and a flow material and comprising a docking projection 10 and an implementation projection 3 Docking or starting with (2) together;

2. When the discharge head 1 and the pressure vessel 2 are docked, the implementation projection 3 directly or indirectly with the implementation mechanism 8 such that displacement of the implementation mechanism 8 occurs in an upward direction. Contacting;

3. activating a switch (11) such that the discharge head (1) is in an operational state by the displacement of the actuation mechanism (8) in the upward direction; And

4. activating the discharge head (1) such that discharge of the flow material out of the discharge head (1) occurs through the fluid passage.

In one embodiment, the implementation mechanism 8 comprises a cam 5 for activating the switch 11. Preferably, the cam 5 causes the switch 11 to be laterally displaced. More preferably, the cam 5 is in direct contact with the implementation projection 3. In one embodiment, the discharge head 1 and the pressure vessel 2 are docked together using threaded parts.

In one embodiment, the upward displacement of the cam 5 generates a transverse displacement of the switch 11 in connection with the printed circuit board 12. The transverse displacement of the switch 11 positions the discharge head 1 in an operating state.

In one embodiment, the pressurized container 2 only places the discharge head 1 in operation when the pressurized container 2 is fully docked with the discharge head 1. Preferably, complete docking occurs when the pressurized container 2 is fully screwed into the discharge head 1 via the docking projection 10 and the docking mechanism 9.

In one embodiment, the cam 5 is deflected downwards. Preferably, the deflection is by spring action.

One of the advantages of the present invention is to ensure that the pressurized container 2 which is not fitted with the implementation projection 3 does not activate the discharge head 1. It also allows the discharge head 1 to only operate when the pressure vessel 2 is correctly fitted and does not inadvertently and inadvertently operate without the pressure vessel 2 to which the discharge head 1 is connected. A pressurized vessel 2 specially formed with an implementation projection 3 can be used in combination with the discharge head 1 to protect the discharge head 1 from chemical reactions or mechanical damage.

2 shows a discharge head 1 and a pressure vessel 2 according to an embodiment of the invention. As shown in FIG. 1B, the pressurized vessel 2 comprises an implementation projection 3 in the form of a collar located on the upper surface 6 of the vessel 2.

As shown in FIG. 1B, the implementation projection 3 may be located near the vessel valve 4. It is to be appreciated that unlike the collar depicted, other mechanisms may be used to activate the implementation mechanism 8. For example, partial surround or cradle, ramp or projection and the like.

2 shows a partial cross-sectional view of the discharge head 1 fitted into and connected to a pressurized container 2 comprising an implementation projection 3. 2 further shows the actuation mechanism 8 for the discharge head 1.

The implementation mechanism 8 is depicted as cam action in FIGS. 2 to 6. However, it should be recognized that this is only one embodiment for practicing the present invention. Another implementation mechanism 8 is said implementation projection which directly activates said switch 11 by contacting said switch 11 or by said switch 11 attached directly to said implementation projection 3. It includes 3).

As shown in FIGS. 2 to 6, the implementation mechanism 8 comprises a cam 5 biased to a downward position, for example by a spring. The cam 5 is displaced upwards when the pressure vessel 2 is attached to the discharge head 1. One method of attachment is to use threaded parts. An upward displacement of the cam 5 generates a lateral displacement of the switch 11. The cam 5 is designed to displace the switch 11 while the cam 5 is displaced. When the switch 11 is displaced inwards, the switch 11 activates an electrical circuit board 12 to electrically supply the automatic dispenser solenoid valve 14 and, in turn, the spray nozzle 15 ) Allows the contents of the container 2 to flow into the atmosphere as a spray or spray.

3 shows a partial cross-sectional view of the cap 16 fitted into the top of the pressure vessel 2. The cap 16 is designed with a simulated implementation projection 3 which activates the implementation mechanism 8 to position the discharge head 1 in an operational state.

4 shows a partial cross-sectional view of an alternative embodiment of the invention, wherein the implementation projection 3 is integrally formed with the container 2. The implementation projection 3 also activates the implementation mechanism 8 and places the discharge head 1 in operation.

5 shows a partial cross-sectional view of an alternative switch mechanism, in which the cam 5 is normally displaced upwardly with respect to the switch 11 so that the discharge head 1 is placed in an operating state.

6 is a schematic diagram for describing the effect of the operation of the implementation projection 3 on the implementation mechanism 8. In FIG. 6A, the pressurized container 2 is not fully screwed into the discharge head 1 and the implementation projection 3 does not activate the switch 11. In FIG. 6B, the pressurized container 2 is completely screwed into the discharge head 1 and the implementation projection 3 is displaced upwards to activate the switch 11 now.

Each pressurized vessel 2 has an opening through which the flowing material can pass. In one embodiment, the valve 4 of the pressure vessel 2 is fitted outside the opening and fixed onto the pressure vessel 2 by a pressing process.

When activated, the discharge head 1 can automatically repeat the spraying process, thereby allowing a continuous flow of liquid from the pressurized vessel 2 to the discharge head 1.

The present invention provides the user with a number of advantages, either independently of one another or simultaneously.

1. The automatic dispenser will not operate without the presence of the container 2. Without the present invention, the automatic dispenser can continue to operate without the container 2 connected and offers no benefit to the user. Therefore, it uses battery energy unnecessarily and generates additional and unnecessary wear of the dispenser mechanism.

2. Operation of the dispenser also requires that the container 2 is screwed accurately and completely into the discharge head 1. If the container 2 is not completely connected to the discharge head 1, there is a possibility that the container 2 does not fit correctly and the contents of the container 2 leak into the atmosphere.

3. The present invention limits the possibility of inserting an unauthorized aerosol with the automatic aerosol dispenser. The contents of unauthorized aerosols may be damaging or otherwise affect the operation and performance of the automatic aerosol dispenser.

4. The present invention is low in production cost and can be easily fitted into aerosol containers during filling operations.

The foregoing detailed description is made up of components or integers having known equivalents, and includes those equivalents presented separately.

Although the present invention has been described in an illustrative manner with reference to specific embodiments, it is to be understood that modifications and / or improvements may be made without departing from the scope or spirit of the invention.

Claims (14)

A discharge head 1 comprising an implementation mechanism 8 and a docking mechanism 9; And
A container 2 comprising an implementation projection 3 and a docking projection 10;
Including,
The docking mechanism 9 is releasably engaged with the docking projection 10 for attaching the discharge head 1 to the container 2 so that the implementation projection 3 operates the aerosol dispenser. An aerosol dispenser associated with the actuation mechanism 8 for positioning in a state. The method of claim 1,
The actuation mechanism 8 comprises a cam 5, a switch 11 and a control circuit 12 which are deflected downwards, the cam 5 having the discharge head 1 attached to the container 2. An aerosol dispenser which is displaced downward to engage the switch 11 when engaged. The method of claim 2,
An upward displacement of the cam (5) is laterally associated with the switch (11) to position the aerosol dispenser in the operating state. The method of claim 2,
An upward displacement of the cam (5) is normally associated with the switch (11) to position the aerosol dispenser in the operating state. The method according to any one of claims 1 to 4,
The docking projection (10) comprises a valve (4). The method of claim 5, wherein
The discharge head (1) further comprises a solenoid valve (14) adapted to fluidly connect with the valve (4) when the discharge head (1) is attached to the container (2). The method according to claim 6,
The discharge head (1) further comprises a manual switch (13) for supplying power to the solenoid valve (14). The method according to any one of claims 1 to 7,
The implementation projection (3) comprises a cap (16) attached to the container (2). The method according to any one of claims 1 to 8,
The docking projection (10) is at least partially enclosed by the implementation projection (3) and comprises a screw component for attachment corresponding to the screw component of the docking mechanism (9). An ejection head (1) comprising an actuation mechanism (8) and a docking mechanism (9), said actuation mechanism (8) comprising a cam (5), a switch (11) and a control circuit (12) biased downward;
Including,
The docking mechanism 9 is adapted to be releasably engaged with the docking projection 10 of the container 2 to attach the discharge head 1 to the container 2 to implement the container 2. An aerosol dispenser in which projection (3) displaces the cam (5) upwards. The method of claim 10,
An upward displacement of the cam (5) is associated with the switch (11) to position the aerosol dispenser in an operational state. The cam (5) is adapted to be disengaged from the switch (11) to position the aerosol dispenser in an inoperative state when the container (2) is removed. The method according to any one of claims 10 to 12,
An aerosol dispenser further comprising the container (2). The method of claim 13,
The docking projection (10) comprises a valve (4) and is at least partly surrounded by the implementation projection (3).

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