EP0365770A1 - Spray can - Google Patents

Abstract

The invention relates to a spray can with a spray mechanism for the fine atomisation of liquids by means of a pump. The spray can (1) consists in this connection of a housing (2) for receiving the spray mechanism (3) and of a receiving container (4) for the spray liquid (5), which is removably connected to the housing (2). …<??>An electromotor-driven gear pump (12) or alternatively a reciprocating pump (48) is used as a spray mechanism (3). …<IMAGE>…

Description

The invention relates to a spray can with a spray mechanism for the fine atomization of liquids by means of a hydraulically acting pump. Spray cans and spray bottles of the aforementioned type are generally known in the trade. Mechanically actuated pumps spray a finely atomized liquid from a nozzle arranged on the housing. According to an earlier German patent application P 38 29 674.8, the hydraulically acting pump is driven electromechanically by a geared motor, whereby the harmful propellant gases are avoided. In addition to the environmental impact, another disadvantage of the previously known spray cans and spray bottles is that after the spray liquid has been removed, the entire spray can, including the pump mechanism, the line system and the outlet nozzle, is thrown away, which also destroys reusable and functional components.

It is therefore an object of the invention to improve a spray can of the type mentioned in such a way that the destruction of reusable components is avoided and the environmental pollution is reduced and, in addition, a spray mechanism is used which ensures that all possible usable spray media function properly even in long-term operation.

According to the invention this object is achieved in that the spray mechanism is inserted in a housing which can be connected to the receiving container for the spray liquid by positive or non-positive connection and the spray mechanism has an electromotive driven gear pump, the suction line through a bottom opening of the housing into the a vent line provided receptacle, wherein the gear pump has a pressure pipe on the output side, which is connected to an outlet nozzle. The gear pump can be firmly mounted on the bottom of the housing.

In an embodiment of the invention, a clutch can be connected between the output shaft of the motor and the drive shaft of the gear pump.

In yet another embodiment of the invention, the vent line of the receptacle can be closed on the outlet side by a ball which is under the action of a spring in such a way that a vacuum created in the receptacle when liquid is removed overcomes the spring force and moves the ball away from the outlet opening.

Furthermore, the gear pump can have two gear wheels of the same size and have an overflow valve in the form of a spring-assisted steel line on the output side.

In an embodiment of the invention, as an alternative to the features of claims 1 to 4, the spray mechanism can have an electric motor-driven piston pump, the suction line of which is led through a bottom opening of the housing into the receiving container, the piston pump having a pressure pipe on the output side which is connected to an outlet nozzle . The bottom opening can in principle be sealed and the pressure pipe can be provided with a helical spiral of at least 180 °.

A special design is also achieved in that the outlet nozzle is inserted into a spray head which is connected outside the housing and separately from it to a pressure pipe which is led out of the housing. This means that a line goes away from the housing, so that the outlet nozzle is only arranged at the end of this line, for example after one meter. This means that even ceilings in living rooms or buildings can be sprayed easily and intensively. The outgoing line can be flexible. In an improved embodiment, the housing or the container can have a handle in which the flexible spray line is at least partially guided and furthermore a switch is installed which is electrically connected to an energy source and the pump. This eliminates the switch on the spray head. A second socket on the container or on the housing can then be used to connect an electrical line to the switch in the handle. The switch in the handle enables the electric pump to be started up easily, and the spray can can also be easily guided by hand. Both the flexible spray line and the electric cable for switching on the electric motor of the pump are located in the handle.

The use of a gear pump has the advantage that different spray liquids with different viscosities and compositions are safely delivered. The gear pump is driven in a simple manner by an electric motor with the interposition of a clutch. In order to prevent the spray liquid from overflowing after the gear pump is switched off, an overflow valve is used on the output side, which also serves as a safety valve on the pressure side. The spring that acts on the steel ball in the valve can be adjustable in a conventional manner. In addition to the embodiment of the gear pump shown in the figures with two gear wheels of the same size and in engagement with one another, other embodiments can also be used, for example wise with an internal toothing and planet gear. Furthermore, it is within the scope of the invention that the gears have any toothing, preferably involute toothing with a more precise flow rate.

The ball valve with an adjustable spring inserted into the vent line on the outlet side has the advantage that air is automatically supplied in accordance with the spray liquid removed from the receptacle. The ball valve is actuated solely by the vacuum created in the receptacle when liquid is removed.

A particular advantage of the invention is also the combination of the upper housing with the entire spray mechanism and the screw-on receptacle for the spray liquid, for example. When coupled, both housings form one unit. After removing the spray liquid from the receptacle, the housing is removed with the spray mechanism and simply connected to a new receptacle with a receptacle liquid. The entire upper part remains together with the spray mechanism and is reusable.

• Figur 1 eine Spraydose mit Spraymechanismus in schema­tischer Darstellung im Schnitt;
• Figur 2 die Spraydose nach Figur 1 mit im Schnitt dar­gestellter Zahnradpumpe;
• Figur 3 einen Schnitt durch die Zahnradpumpe nach Figur 2 gemäß der Linie III-III;
• Figur 4 eine Spraydose mit einer eingebauten Kolben­pumpe, schematisch im Schnitt;
• Figur 5 einen Spraykopf mit außerhalb liegender Aus­trittsdüse im Schnitt;
• Figur 6 eine Spraydose mit entfernt liegender Austritts­düse und Schalter im Bediengriff;
• Figur 7 ein Verschlußventil des Aufnahmebehälters;
• Figur 8 eine Ventilanordnung bei einer Spraydose mit Druckgaseinsatz, vereinfacht im Schnitt.

Examples of the invention are shown in the drawing. Show it:

• Figure 1 shows a spray can with spray mechanism in a schematic representation in section;
• Figure 2 shows the spray can of Figure 1 with the gear pump shown in section;
• 3 shows a section through the gear pump of Figure 2 along the line III-III;
• Figure 4 shows a spray can with a built-in piston pump, schematically in section;
• Figure 5 shows a spray head with an external outlet nozzle in section;
• Figure 6 shows a spray can with the outlet nozzle and switch in the control handle;
• Figure 7 shows a closure valve of the receptacle;
• Figure 8 shows a valve arrangement in a spray can with compressed gas insert, simplified in section.

The spray can 1 essentially consists of a housing 2 for accommodating the spray mechanism 3 and a receptacle 4 for the spray liquid 5 which is detachably connected to the housing 2.

The housing 2 for the spray mechanism is cylindrical and has a head part 6. The spray mechanism 3 consists of a battery 7 to which an electric motor 8 is electrically connected. The electric motor 8 is connected with its output shaft 9 to a clutch 10, in which a drive shaft 11 of a gear pump 12 engages. A suction line 13 emerges below the gear pump 12, while in the upper part of the gear pump the pressure pipe 14 is connected, which opens into the outlet nozzle 15 in the head part 6 of the spray can. An overflow valve 16 with a ball 17 and an adjustable coil spring 18 is inserted in the pressure pipe 14 on the outlet side of the gear pump 12.

As can be seen from Figures 2 and 3, the gear pump 12 consists of two equally large gears 19 and 20 which are in engagement with each other. When the two gear wheels rotate in the direction of the arrow 21, spray liquid is drawn in from the suction line 13 and conveyed through the free tooth gaps to the pressure pipe 14 in the direction of the arrow 22.

The gears 19 and 20 can be designed with an involute toothing for a precise flow. To För Eliminating fluctuations can also be compensated for by multi-wheel pumps, in which a medium gear with an odd number of teeth is used. Gear pumps with internal toothing and planet gear can also be used.

The gear pump 12 is enclosed by a housing 23 which can be mounted on the bottom 24 of the housing 2 by screws 25.

The receptacle 4 for the spray liquid 5 screwed onto the housing 2 by the central thread 31 has a vent line 26 which is equipped with a valve 27 on the outlet side of the housing 2. This valve consists of a ball 28 which is pressed by a spring 29 against the outlet opening 30. The spring 29 is designed so that when there is a vacuum in the receptacle when liquid is removed, it loses so much spring force that the ball 28 withdraws from the outlet opening 30 and allows air to flow into the receptacle 4.

The housing 2 is connected to the receptacle 4 for the spray liquid 5 at the bottom 24 of the housing 2, where a collar 32 is provided which has an internal thread 31. The receptacle 4 is also formed on the head side with a collar 33 and has an external thread 34 which is firmly and sealingly engaged with the internal thread 31.

FIG. 4 again shows a spray can 1, which essentially corresponds to the spray can according to FIGS. 1 and 2 and has a housing 2 for receiving the spray mechanism 3 and a further container 4 for the spray liquid 5. The base piece 35 of the housing 2 has a central collar 36 drawn inwards with an internal thread 31. The collar 35 closes at the top with a base plate 37, which is attached in one piece or separately can be and shows a central opening 38 for the passage of the suction pipe 13. The opening 38 receives an annular seal housing 39 with an inserted sealing tape or sealing ring 40. Furthermore, a decentralized opening 41 of relatively small cross-section is provided in the base plate 37, through which the air pipe 26 projects as a ventilation line. A special seal between the ventilation line 26 and the opening 41 in the base plate is not required here.

The container 4 for the spray liquid 5 has a central ring web 42 with an external thread 34 on the head side. In the example of FIG. 4, the upper opening 43 is closed with a thin film 44. Instead of the film 44, a removable cover made of solid material or a solution according to FIG. 7 can also be provided.

The connection of the housing 2 to the container 4 takes place in that the housing 2 is placed together with the spray mechanism 3 on the container 4 and screwed to the latter via the threads 31 and 34. The upper film 44 of the opening 43 is pierced by the suction pipe 13 and the air pipe 26 when the housing 2 is put on.

Of course, the connection types of housing 2 and container 4 of Figures 1, 2 and 4 can be exchanged and combined.

The spray mechanism 3 according to FIG. 4 consists of a battery 7 to which an electric motor 8 is electrically connected. The electric motor 8 drives an eccentric 46 via a reduction gear 45, which is operatively connected to the piston pump 48 via a slide 47. A suction pipe 13 emerges below the piston pump 48, while in the upper part of the piston pump 48 the helically coiled pressure pipe 14 is connected, which leads into an outlet nozzle 15 opens out. The electric motor 8 is switched by an electrical switch 49 with electrical switch contacts 50. An air tube 26 is also connected to the electrical switch 49 and has an only very small passage cross section of approximately two to five millimeters. Below the electric switch 49, the air tube 26 can be closed by a spring-assisted valve 52 against the escape of liquid.

A battery 7 is inserted or exchanged through the opening 54 in the cylinder wall of the housing 2, which can be closed with a cover 53. 55 denotes the helix of the pressure tube 14 or the flexible pressure line.

In the state of the spray can 1 shown in FIGS. 1, 2 and 4, a spray liquid 5 can be sprayed from the nozzle 15 in the head part 6 of the housing 2 at the push of a button. After the spray liquid has been completely removed and, if necessary, also in each intermediate stage, the receptacle 4 can be removed from the housing 2. The receptacle 4 can then either be reused by refilling with a spray liquid 5 or be sent to a landfill. Of course, it is possible to separate the receptacle 4 if the operator wants to use the same spray mechanism to remove another spray liquid from another receptacle. In this case, it makes sense that the upper opening 44 of the receptacle 4 has a sealable lid.

As an alternative to the screw connection shown, the connection between the housing 2 and the receptacle 4 can also be made by a conventional type of bayonet, plug-in or clamp lock.

When the electric switch 49 is actuated, a plunger 51 opens the spring-assisted air valve 52, causing an inflow of air into the receptacle to compensate for the liquid withdrawn.

FIG. 5 shows the possibility of laying the outlet nozzle 15 outside the head part 6 of the housing 2 of the spray can 1. For this purpose, an extension tube 56 is inserted in the head part 6, into which the pressure line 14 opens. At the end of the extension tube 56, the outlet nozzle 15 is attached.

According to FIG. 6, the extension tube 56 can also be a relatively long flexible or rigid line 57, for example one meter in length. The purpose of this is that ceilings or removed parts in living rooms, halls or similar rooms can be sprayed easily and specifically. In this case, the switching of the electric motor 8 for the function of the pump 12 or 48 is not carried out via the spray head 6 or the upper switch 49, but by a separate switch 58 in an additional operating or working handle 59 of the housing 2. From a socket 60 in the housing or on the housing 2, an electrical line 61 is guided in a very simplified drawing to the switch 58 in the control handle 59. Furthermore, the electric motor 8 is connected to the switch 58 in such a way by the electric lines 62 that when the switch 58 is depressed, an electrical connection is established between the socket 60 and the electric motor 8. When the socket 60 is connected to an energy source (plug, mains), a current flows to the electric motor 8, which starts the electric motor 8 and at the same time the connected pump 12 (48).

The flexible or rigid pressure line 57, like the electrical lines 61, 62, is also laid in the control handle 59 up to the pump 12 (48). The pressure line 57 can be inserted and pulled out into the housing 2 and the operating handle 59.

In order not to allow the receiving container 4 for the spray liquid 5 to be refilled by unauthorized persons, so that dangers and the refilling with harmful liquids or agents are generally avoided, a special locking security is provided in FIG the suction pipe 13 is connected. This valve 63 is inserted into the cover of the receptacle 4 and consists of the actual valve body 64, the valve spring 65 of the spring socket 66 inserted inside, the spring plate 67 and the outer seals 68, 69 and the inner seal 70. When the receptacle 4 is screwed into the housing 1, 2 and 4, the valve 63 is pressed down against the force of the valve spring 65 and the valve is thereby opened. The spray liquid 5 can then emerge from the receptacle.

As has been shown in tests, the spray jet 71 can be improved when it emerges from the spray can 1 in that the spray liquid 5 is placed under a slight pressure of about 0.5 to 0.8 bar. For this purpose, a compressed gas, for example nitrogen, is introduced into the receptacle 4 in addition to the spray liquid. This compressed gas also at least reduces the necessary suction power of the gear pump 12 or the piston pump 48, since the spray liquid 5 rises with the aid of pressure.

If a pressurized gas is introduced into the receptacle 4, it must be prevented that the spray jet or the spray liquid 5 does not accidentally emerge from the outlet nozzle 15. This is prevented by installing a valve 72 in the head part 6 of the housing 2, as shown in FIG.

The valve housing 75 is in the housing 2 of the spray can 1 a sealing ring 89 to the lower spray mechanism 3 with the pump 12 (48). In the valve housing 75 there is the inlet opening 76 for the pressure line 14. From the inlet opening 76 there is an annular channel 77 around the valve body 72 to the upper valve disk 73, which, like the valve body 72, interacts with the nozzle receptacle 79. The valve body 72 is under the action of a valve spring 74. The nozzle receptacle 79 is acted upon by a pressure piece 83, which is operatively connected to the head part 6 of the spray can 1, and has an upper stop 80 and a lower stop 81 lying axially one above the other. Between the lower stop 81 and the valve disc 73 are installed disk springs 82.

The pressure piece 83 acts decentrally on a switching pin 84 under the action of a spring 85 which is axially spaced from a pressure pin 86. This in turn can be moved to a limit switch 87 which is fastened in the valve housing 75 by a screw 88.

If its spray jet 71 is to be generated, the head part 6 is usually depressed as a switch. Finally, valve body 72 is pressed against spring pressure via nozzle receptacle 79. The spray liquid 5 in the ring channel 77 of the valve 72 can escape into the upper pressure line 90 via the slot 78. In order for the pump 12 (48) to be in operation for a fraction of a second before the outlet nozzle 15 is opened or the valve 72 is opened, so that the spray liquid does not emerge from the nozzle 15 under the gas pressure, the limit switch 87 are operated, which requires a smaller stroke of its switching plunger 91 than the valve disk 73 to open the slot 78. In addition, the stroke of the switching plunger 91 with respect to the switching point has a relatively large tolerance of approximately ± 0.3 mm. The limit switch 87 must therefore already switch before the valve 72 opens. This is now through the Spring 85 reached, which actuates the switch 87 via the switching pin 84 when depressing the pressure piece 83. In addition, it is achieved that, after the maximum switching stroke has been covered by the pressure pin 86, the spring 85 is compressed even further, but the pressure pin 86 comes into contact with the bearing surface 92 of the valve housing 75. The pressure pin 86 can therefore not be moved axially, although the spring 85 is still compressed to allow the entire necessary stroke of the valve 72.

Claims (18)

1. spray can with a spray mechanism for fine atomization of liquids by means of a hydraulic pump,
characterized,
that the spray mechanism (3) is inserted into a housing (2), which can be connected to a receptacle (4) for the spray liquid (5) by positive or / and non-positive connection, and the spray mechanism (3) is an electromotive gear pump (12 ), whose suction line (13) is guided through a bottom opening of the housing (2) into the receptacle (4) provided with a ventilation line (26), the gear pump (12) having a pressure pipe (14) on the output side, which is provided with a Outlet nozzle (15) is connected. 2. Spray can according to claim 1,
characterized,
that the gear pump (12) on the bottom (24) of the housing (2) is fixedly mounted. 3. spray can according to claim 1,
characterized,
that a clutch (10) is connected between the output shaft (9) of the motor (8) and the drive shaft (11) of the gear pump (12). 4. spray can according to claims 1 to 3,
characterized,
that the gear pump (12) has two gear wheels (19, 20) and on the output side has an overflow valve (16) in the form of a spring-supported steel ball (17). 5. spray can with a spray mechanism for fine atomization of liquids by means of a hydraulic pump,
characterized,
that the spray mechanism (3) is inserted into a housing (2) which can be connected to a receiving container (4) for the spray liquid (5) by positive and / or non-positive connection, and that the spray mechanism (3) is an electromotive driven piston pump ( 48), the suction line (13) of which is guided through a bottom opening (43) of the housing (2) into the receptacle (4), the piston pump (48) having a pressure pipe (14) on the output side, which is connected to an outlet nozzle (15 ) connected is. 6. spray can according to claims 1 and 5,
characterized,
that the bottom opening (43) of the housing (2) is sealed. 7. spray can according to claims 1 and 5,
characterized,
that the pressure pipe (14) is provided with a helical spiral (55) of at least 180 °. 8. spray can according to claims 1 and 5,
characterized,
that the outlet nozzle (15) outside the container (2) is connected to a pressure pipe (14, 57) led out of the container (2). 9. spray can according to claim 8,
characterized,
that at least the outside of the container (2) Part of the pressure pipe (57) is a flexible line. 10. spray can according to one or more of the preceding claims,
characterized,
that the container (2) has an operating handle (59) in which the flexible line (57) is at least partially guided and a switch (58) is used which is electrically connected to an energy source (60) and the electric motor (8) for the gear pump (12) or the piston pump (48) is connected. 11. Spray can according to claim 1,
characterized,
that the vent line (26) is closed on the outlet side by a ball (28) which is so under the action of a spring (29) that a vacuum created in the receptacle (4) during liquid removal overcomes the spring force and the ball (28) from the Exit opening (30) moved away. 12. spray can according to claims 1 and 5,
characterized,
that in the bottom piece (24) of the housing (2) there is a thread (31) which can be connected to a thread (34) in the head part of the receptacle (4). 13. spray can according to claims 1 and 5,
characterized,
that the bottom piece (24) of the housing (2) can be connected to the head part of the receptacle (4) by a bayonet or stretch or clamp lock. 14. Spray can according to claims 1, 5, 12 and 13,
characterized,
that one connected to the pump (12, 48) in the housing (2) Suction pipe (13) is guided through a bottom opening in the housing (2), which has a housing seal (40) which surrounds the suction pipe (13) in a ring. 15. spray can according to claims 1, 5 and 12 to 14,
characterized,
that the receptacle (4) is provided on the head side with a removable cover (44) which consists of a deformable material which can be pushed open or torn open under the action of force. 16. Spray can according to claims 1, 5 and 12 to 14,
characterized,
that a second opening (41) is provided in the base piece (24) for the passage of an air pipe (26) which is operatively connected to the motor switch (49) of the spray mechanism (3), the opening optionally having a small cross section of approximately two to five millimeters. 17. spray can according to the preceding claims,
characterized,
that the housing (2) for the spray mechanism (3) and the receptacle (4) for the spray liquid (5) are optionally made of plastic, metal or glass. 18. Spray can according to one or more of the preceding claims,
characterized,
that in the receptacle (4) for the spray liquid (5) a compressed gas is entered and in the upper part of the housing (2) with the axial movement of the head part (6) coupled for switching purposes passage valve (72) for the passage of the spray liquid (5) under pressure from the receptacle (4) is provided, which in combination with a switching mechanism (84, 85, 86) of a limit switch (87, 91) for starting the electrical system motors (8) of the pump (12, 48) acts in such a way that the limit switch (87, 91) is actuated briefly before the valve (72) opens and the switching mechanism (84, 85, 86) controls the entire opening stroke of the valve (72 ) controlled by spring force and metered to the limit switch (87, 91).

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