DE1500597B2 - Dip tube atomizer - Google Patents

Description

The invention relates to a dip tube atomizer. especially for cosmetic and pharmaceutical Liquids, which can be attached to a liquid container with a connecting sleeve and with a inner and an outer closure member is provided, which is slidable and resilient in each other Closed position are loaded, in which both locking elements to interrupt the connection

jo lie against one another between the immersion tube and the atomizing nozzle and the outer closure member for breaking the connection between the container and the atmosphere on the connecting sleeve, and which by actuating a spring-loaded lever in the opening

J5 position, with the trigger compressing air and pushing it through the atomizing nozzle.

The invention is based on the object of no longer predominantly atomizing by mechanical means and to be conveyed by pressure to the atomizing nozzle, as can be seen from French patent specification No. 13 63 410 is, but to suck up the liquid like a jet pump from that container which the atomizer is attached, if air flows through the nozzle when the trigger is depressed is blown. Because of this difference, the known proposal takes the one below Marking does not anticipate the outlined invention nor does it suggest it.

This object is achieved according to the invention in that the atomizing nozzle is designed in the manner of a venturi tube and is provided with a liquid suction channel opening into the constriction, as is known per se that furthermore the pusher, which is resiliently loaded away from the housing, from a cylinder housing with the nozzle and from the existing atomizer head relative to the connection sleeve is resiliently movable, and that the spring between The pusher and the housing are stronger than the spring or springs between the housing and the connecting sleeve inner closure member is attached to the housing.

The immersion tube atomizer according to the invention is characterized in that it is divided into a die Valve body for the connecting channels carrying cap and the pump piston and the Atomizing nozzle receiving atomizer body, which is arranged displaceably on this and for Actuation of the valve body is used.

A preferred embodiment of the dip tube atomizer according to the invention is characterized

net that the inner closure member is designed as a rod with a widened head at the free end which rod the sleeve-shaped outer locking member is slidably mounted, as is known per se.

In a further embodiment of the invention, the sleeve-shaped outer closure member can move radially have outwardly directed annular flange for tight contact with the connecting sleeve and the sleeve on the Contact side facing away from the annular flange radially inwardly protruding projections for holding the have outer closure member in the open position.

An embodiment of the invention is shown in the drawing and will be described in more detail below described. It shows 1>

1 shows a view of a longitudinal section through the atomizer in the rest position;

FIG. 2 is a view of a cross section along the line H-II in FIG. 1;

3 shows a view of a longitudinal section through a _> o Part of the nebulizer in the operating position.

According to FIGS. 1 and 3, a closure cap for the container containing the liquid to be atomized is formed on a cap-shaped part I and a sleeve 3 with an internal thread pressed into it. 2> Opposite the closure cap, an atomizer body 38 is slidably guided, which is pushed over the closure cap with a cylindrical edge. The guidance is ensured by pins 39 which are provided on the closure cap and which engage in bores 40 m of a cylindrical component 41 which is fastened in the atomizer body 38. Springs 42, which are housed in other bores 40 and are supported on the closure cap, endeavor to push the atomizer body upwards. The sleeve r> 3 is provided with a central bore in which a cylindrical sleeve 43 slides with play, the sleeve 43 having an outer flange 43 on its upper edge; which lies in the lower position of the sleeve against inner projections 3a of the sleeve, whereby the sleeve 43 is prevented from falling out. The cap-shaped part I of the closure cap is also provided with a central bore on its upper end face, the diameter of which, however, is smaller than the diameter of the sleeve 43, so that it cannot leave the sleeve upwards. A sliding of the sleeve 43 in the sleeve 3 is therefore only possible within these limits. A piston valve 50 is guided with play inside the sleeve 3, the piston rod 48 of which slides sealingly in the sleeve and is firmly connected to the atomizer body 38, being screwed into the component 41. The piston rod has an axial bore 47, from which a radial bore 49 extends, which is provided above the piston 50. The axial bore 47 is connected via a connecting channel 46 and 45 τ> with an atomizing nozzle 44, which is designed as a Venturi nozzle. The connecting channel 45 opens into the neck 44 of the nozzle 44. At its lower end, the sleeve 43 carries a dip tube 5 which extends down into the liquid to be atomized. In the upper part of the atomizer body 38, a piston 52 designed as a pusher is slidably arranged, the sealing being effected by a seal 53 which is fixed to the piston. The piston is pressed into its upper position by a compression spring 54, 6 ^r > the hardness of which is greater than that of all springs 42 put together, which are provided between the closure cap and the atomizer body. The pump chamber 55 formed between the piston 52 and the cylindrical component 41 is connected to the nozzle 44 via connecting channels 56 and 57. The connecting channel 57 is closed during the suction stroke of the piston 52 by a check valve 58, 59, which consists of a ball 58 which is pressed onto its seat by a spring 59. A bore 60 is provided within the piston 52, which represents a connection between the pump chamber 55 and the ambient air. A valve body 61 formed on the seal 53 is resiliently pressed against the inner edge of this opening and although it allows air to enter the pump chamber 55 during the suction stroke of the piston, it prevents the trapped air from escaping during the downward pressure stroke of the piston 52.

In the rest position, the springs 42 endeavor to remove the atomizer body 38 from the intermediate cap 1, 3 to push away. However, this upward movement is limited by the fact that with a Seal-provided valve piston 50, which via its piston rod 48 with the component 41 of the atomizer body 38 is connected, lies against its seat in the sleeve 43 and this against the bottom of the cap 1 presses. This is the connection between the dip tube 5 and the atomizing nozzle 44 and the Connection of the interior of the container to the ambient air, which between the bottom of the cap 1 and the upper edge of the sleeve 43 is provided, interrupted. When the piston designed as a pusher is actuated 52 the springs 42 are first compressed due to the greater hardness of the spring 54, wherein the Piston 50 and sleeve 43 are moved downwards. I lierbei moves the sleeve 43 down until their outer flange 43 <-i on the inner projections 3, j sits, while the piston 50 can be moved further down within the sleeve 43. In the the lower layer of the sleeve 43, the connection between the interior of the container and the ambient air is restored, by the outside air between the bottom of the cap 1 and the upper edge of the sleeve 43 in the can flow inside the container. The displacement of the piston 50 within the sleeve 43 causes the Radial bore 49 emerges from the guide for the piston rod 48, whereby the connection between Dip tube 5 and the nozzle 44 via the connecting channels 49, 47, 46 and 45 is made. The downward Directed movement is ended when the component 41 rests on the closure cap 1. Then begins the downward movement of the piston 52, which compresses the air trapped in the pump chamber 55, which reaches the nozzle 44 via the bores 56 and 57. In the throat 44 <? the venturi makes the air so strong accelerates the fact that it sucks liquid out of the channel 45 which is in communication with the dip tube and this atomized. At the same moment, an amount of liquid corresponding to the amount of liquid that has been withdrawn flows Amount of air between the atomizer body 38 and the cap 1 through and passes through the Gap created by the lowering of the sleeve 43 between the upper edge and the bottom of the Closure cap 1 arises into the container, so that there is no negative pressure as a result of the withdrawal of liquid can arise. The path of the air flowing into the container is indicated by an arrow 62 in FIG. 3 shown. If the piston 52 is now released, the atomizer body 38 and the piston move back up. By lifting the atomizer

5 6

The body of the cap is over which the upward movement of the piston 52 is over the

Piston rod 48 of piston 50 pulled upwards, opening 60 for as long as air into pump chamber 55

whereby a termination of both the connection between sucked and the suction effect by the piston stops,

Immersion tube and atomizing nozzle as well as between the check valve 61 from its seat

Inside the container and the ambient air. At 5 it will be picked up.

For this purpose 2 sheets of drawings

Claims (10)

Patent claims: I. Immersion tube atomizer, especially for cosmetic and pharmaceutical liquids, which attachable with a connecting sleeve to a liquid container and with an inner as well an outer closure member is provided which is displaceable and resilient on one another in the closed position are loaded, in which both locking members to interrupt the connection between Immersion tube and atomizing nozzle rest against one another and the outer closure member for interruption the connection between the container and the atmosphere is applied to the connecting sleeve, and which through Actuation of a spring-loaded lever in the open position are movable, the lever Air is compressed and forced through the atomizing nozzle, characterized in that the Atomizing nozzle (44) is designed like a venturi tube and has a nozzle opening into the constriction (44.-j_) Liquid suction channel (45,46) is provided, as is known per se, that also consists of a cylinder housing (38,41) with the nozzle (44) and out of the pusher (52), which is resiliently loaded away from the housing (38, 41) existing atomizer head with respect to the connecting sleeve (1,3) is resiliently movable, and that the The spring (54) between the pusher (52) and the housing (38, 41) is stronger than the spring or springs (42) between Housing (38,41) and connecting sleeve (1,3), the inner closure member (48, 50) on the housing (38, 41) is attached. 2. Immersion tube atomizer according to claim 1, characterized in that the inner closure member as Rod (48) is formed with a widened head (50) at the free end, on which rod (48) the sleeve-shaped outer closure member (43) is slidably mounted, as is known per se. 3. Immersion tube atomizer according to claim 1 or 2, characterized in that the sleeve-shaped outer closure member (43) has a radially outwardly directed annular flange (43. · ^ for tight contact with the connecting sleeve (1,3), and that the sleeve (1 , 3) on the side of the annular flange (43a,) facing away from the contact side has radially inwardly projecting projections (3a) for holding the outer closure member (43) in the open position. 4. Immersion tube atomizer according to claim 1, 2 or 3, characterized in that the immersion tube (5) is attached to the sleeve-shaped outer closure member (43) is. 5. immersion tube atomizer according to one of claims 1 to 4, characterized in that the Connection sleeve consisting of an outer cap (1) and an internally threaded screw sleeve (3) exists, as is known per se. 6. immersion tube atomizer according to claim 3, 4 and 5, characterized in that the annular flange (43a,) of the outer closure member (43) rests in the closed position of the same on the cap (1), and that the radially inwardly projecting projections (3a) of the Connection sleeve on the screw sleeve (3) are provided. 7. Immersion tube atomizer according to one of the preceding claims, characterized by axial Pin (39) on the connecting sleeve (1, 3), which in corresponding axial bores (40) of the cylinder housing (38,41) intervene to guide it. 8. Immersion tube atomizer according to one of the preceding claims, characterized in that between the atomizing nozzle (44) and the air pumping chamber (55) of the atomizing head (38, 41, 44, 52) a check valve (58, 59) opening towards the nozzle (44) is provided, as is known per se. 9. Immersion tube according to claim 8, characterized in that between the air pumping chamber (55) and the atmosphere is provided with a check valve (61) which opens towards the chamber (55), such as known per se. 10. Immersion tube according to claim 9, characterized in that that the check valve is provided in the handle (52) and has a closure member (61), which is formed in one piece with the pusher seal (53) and resiliently against a valve bore (60) is pressed in the pusher (52).