EP0245319A1 - Device for dispensing viscous materials, such as liquids, creams, pastes or similar from a storage vessel. - Google Patents

Abstract

Device for dispensing viscous materials contained in a storage container by means of a piston pump which is attached to the outlet of the storage container, the cylinder (2) of the pump which is smaller in diameter than the device being held inside of it. The connecting rod (9) is guided with limited displacement longitudinally inside a bore of the device and against the force of a return spring (17). A ventilation channel is provided which leads to the storage container and the bore of the device designed to guide the connecting rod extends into a pipe (8) arranged coaxially and oriented towards the suction pipe (5) of the piston pump . The connecting rod passes through the aforementioned bore as well as the tubing leaving a vacuum (10), and has a ventilation opening (32) in the pump cylinder between the cover of the device and the connecting rod when it is in its extreme position superior.

Description

 Device for conveying viscous materials, such as liquids, cream, pastes or the like, from a storage container

The invention relates to a device according to the preamble of claim 1.

Devices of this type are sufficiently known, the piston for conveying the viscous substance having to be pressed into the pump cylinder against the force of a return spring.

In this case, a bore is provided in the screw cap for ventilation of the storage container and is sealed in the upper dead position of the piston. But there is the disadvantage that pressure in the storage container, which can be caused, for example, by temperature changes, the sealing effect can be partially or completely canceled.

The object of the invention is to improve a device of the type specified in the preamble of claim 1 in such a way that a higher degree of security when sealing the ventilation duct is achieved with simple means.

The solution to this problem is characterized by the features identified in the characterizing part of claim 1.

Through these measures, on the one hand, when the piston rod is pressed into the cylinder against the force of the return spring, atmospheric air can pass through the air gap between the piston rod and its guide bore together with the connecting piece and the ventilation opening arranged in the upper end part of the cylinder unhindered and thus ensure the function of the piston pump.

On the other hand, when the piston is in the upper end position, which is inevitably reached by the force of the return spring after the piston rod is released, the air gap

5 inevitably closed between the piston rod and the connecting piece, an internal overpressure of the container contributing to an increase in the sealing effect, since the sealing sleeve is even more firmly attached to the part forming the sealing seat

10 is pressed.

Further configurations which favor the function and / or the manufacture of the device are described in the subclaims. To improve the sealing of the ventilation

15 line in both dead positions of the pump piston, that is to say when the piston is fully retracted or extended, the feature formation according to claim 3 is proposed.

To further avoid liquid or

20 Paste emerges from the container provided with the device when the pump piston is in one of the two extreme positions and the container is e.g. is turned upside down during transport, the training according to claim

25 4 to 7 proposed. The embodiment according to claim 4 has the advantage that the outlet of the piston pump is only open when substances are conveyed by means of the piston pump, but otherwise the aforementioned outlet is blocked by means of the ring seal tightly fitting against the piston, so that when not in use the device no medium can pass the outlet line.

5, the suction line is additionally blocked when the piston rod is pressed into the cylinder. By these measures according to claim 7, the piston rod can be locked in its end positions only by turning the piston rod about its longitudinal axis, so that an unintentional actuation of the piston pump is prevented. At the same time, the end position of the piston rod can also be positively fixed, in which the suction line is also blocked.

This is particularly advantageous for transport purposes, since the space requirement of the container provided with the device is smaller when the piston rod is fully inserted and in this position both locking and sealing is desired, even when the piston rod is fully extended a locking mechanism for protection against unintentional operation while maintaining the seal has been achieved.

Embodiments of the invention are in the

Drawings shown and described in more detail below.

It shows:

Figure 1 shows a device for conveying viscous substances from a storage container in the starting position, in the front view, partially in longitudinal section.

2 likewise in a middle position,

3 to 5 a variant in three different functional positions, partly in longitudinal section; 6 shows a detail in principle;

Fig. 7 shows another embodiment, partially in longitudinal section.

This device according to FIGS. 1 and 2 essentially comprises a piston pump, which is held on a screw cap 1, by means of which the piston pump can be attached to the mouth of a storage container (not shown) in such a manner that the suction pipe 5 of the piston pump extends into the storage container . The piston pump consists of a cylinder 2, a piston rod 9, a piston 16, a return spring 17 and two valves 6 and 29, each closing against the direction of delivery by gravity.

Closing springs can also be assigned to the valves. Furthermore, the piston rod 9 is penetrated by a delivery channel 11 extending in its longitudinal extent. The piston rod 9 is longitudinally adjustable in a bore 32 of the screw cap cover. From the inside of the screw cap 1 strives for a coaxial arrangement with the bore 32, the same width in the clear width

and towards the intake manifold 5, molded, cylindrical connection piece 8 made of dimensionally stable material. Through the latter and the bore 32, the cylindrical piston rod 9 is passed leaving an air gap 10. A ventilation opening 24 is arranged in the cylinder 2 between its upper mouth and the piston 16 standing in the upper end position (FIG. 1). At the upper end of the cylinder 2, a circumferential shoulder 30 is formed, which is blown into an undercut of a cover part connected to the screw cap 1.

In this area there is a longitudinal slot which forms the ventilation opening 24.

The piston 16 is fastened to the piston rod 9 and has a molded-on, relatively soft, cuff-like ring seal 19, which rests tightly against the inside of the cylinder 2 under elastic prestressing and which is formed by the

Pressure of the conveyed material is applied even more firmly to the inside of the cylinder. From the face of the valve 29 facing the

Piston 16 still strives for a relatively soft seal 21 which is smaller in diameter than the diameter of cylinder 2 and is designed as a sleeve and which, in the upper end position of piston 16 (FIG. 1), tightly closes socket 8 and thus the air gap 10 closes.

If the piston rod 9 of the piston pump connected to a storage container is manually pushed into the cylinder 2 for the first time against the force of the return spring 17, the air in the cylinder 31 of the cylinder 2 is pressed outwards with a temporary opening of the valve 29 ( Fig. 2), wherein valve 6 is closed.

If the piston rod 9 is released, 6 conveyed material is sucked into the displacement 31 while the valve is temporarily opened, valve 29 being closed. When the piston rod 9 is repeatedly depressed, the material to be conveyed located in the displacement 31 is pressed outward through the conveying channel 11 while the valve 29 is temporarily opened. In all this, the air gap 10 is in the upper end position Piston 16 closed, so that in this position no material can escape through the air gap 10 to the outside. If, on the other hand, the piston rod 9 is pressed down, the air gap 10 is automatically released and atmospheric air can flow into the storage container through the air gap 10 and the ventilation opening 24 for pressure compensation.

When a container equipped in this way is stored, the piston 16 is in the upper end position, the excess pressure building up inside the container not leading to an overflow from the ventilation opening, but rather the seal 21 is pressed increasingly against the corresponding sealing surface.

The screw cap 1 is preferably assembled from two individually prefabricated parts which are connected to one another by means of a corner connection secured by catches.

All parts with the exception of the return spring 17 in the form of a helical compression spring and the valve body 6, 29 according to FIGS In the device according to FIGS. 3 to 5, a piston pump is held on a screw cap 1 for detachable and tight connection of a storage container, not shown, flowable medium, for example perfume or cream, whose cylinder 2 is smaller in diameter than that clear width of the screw cap 1 is. The piston pump is also arranged coaxially with the screw cap 1. The cylinder 2, which is open at the top, is closed by means of an end wall 3 which is connected to the screw cap 1 by means of a plug-in connection secured by detents.

At the lower end part of the cylinder 2, a connecting piece 4 is formed, in which a suction line 5 engages tightly. Above the suction line 5, a valve body 6, which automatically closes by gravity against the conveying direction of the medium, is arranged, which cooperates with a valve seat 7 arranged in the connecting piece 4.

On the end wall 3, a guide bushing 8 is formed which is directed into the cylinder's displacement,

through which the piston rod 9 of the piston pump passes through a longitudinal air gap 10.

The piston rod 9 is penetrated by a channel 11 forming the outlet line of the piston pump. In the lower mouth of the channel 11, a pin 12 is frictionally inserted. On the end part of the pin 12 protruding from the piston rod 9 there is a laterally over the piston

10 rod 9 protruding, relatively soft ring seal 13 formed.

Furthermore, a longitudinal groove 14 is arranged in the pin 12, which opens on the one hand into the channel 11 at the top, and on the other hand into a lateral one

15 breakthrough 15 of the piston rod 9 passes. On the piston rod 9, the piston 16 of the piston pump is mounted such that it can be adjusted axially to a limited extent, which is in tight contact with the ring seal 13 in one end position and in the

20 other end position releases the opening 15. The piston rod 9 is assigned a return spring 17 which is arranged with a prestress and is located on the one hand on the pin 12 and on the other hand

is supported on a shoulder 18 of the cylinder 2. The piston 16 has an integrally formed, collar-like ring seal 19 which interacts with the cylinder 2 and strives from the piston end face facing the suction line 5. On the other side of the piston, a connecting piece 20 encompassing the piston rod is formed. A cuff-like ring seal 21 is formed on the piston coaxially with this, which comprises the guide bushing 8. Two annular, raised sealing seats 22 and 23, which are arranged one behind the other at an axial distance, are formed on the outside of the latter.

In both end positions of the piston 16 (FIGS. 1 and 3), the ring seal 21 lies tightly against one of the sealing seats 22 and 23, while in the intermediate positions (FIG. 2) the ring seal 21 is arranged with play relative to the guide bushing 8.

In addition, a ventilation opening 24 is provided in cylinder 2, above piston 16. A cam 25 strives from the inside of the guide bushing 8 and engages in an adjustable manner in a longitudinal groove 26 of the piston rod 9. The groove 26 has at both end parts a groove extension 27 running in the circumferential direction, the lengths of which correspond at least to the width of the cam 25.

If this device is tightly connected to a storage container in such a way that the suction line 5 extends into the medium to be conveyed, and if the piston rod 9 has been manually depressed for the first time, the medium is sucked into the displacement of the piston pump after the piston rod 9 has been released Valve body 6 temporarily lifts off from its valve seat 7 and furthermore the piston 16 bears tightly on the ring seal 13.

When the piston rod 9 is repeatedly depressed, the piston 16 is inevitably lifted by the ring seal 13, influenced by the medium in the displacement, and thus releases the opening 15, after which the medium through the opening 15, the groove 14 and the piston rod channel 11

can flow out.

When the upper end position of the piston is reached, the ring seal 13, influenced by the return spring 17, is again placed tightly on the piston 16, so that no medium can pass through the channel 11 in the upper end position described above.

However, the channel 11 is also blocked in the lower piston end position because the ring seal 13 plunges tightly into a sealing seat 28 formed in the cylinder 2. In both end positions of the piston rod, the latter can optionally be fixed relative to the cylinder 2, for which purpose only the piston rod 9 has to be rotated about its longitudinal axis until the cam 25 engages in one of the groove extensions 27 extending in the circumferential direction.

In both end positions of the piston rod, however, the ventilation line leading into the reservoir is blocked, while between the aforementioned end positions of the piston rod atmospheric air through the air gap 10, which is located between the sealing seats 22 and 23

Travel and can flow through the ventilation opening 24 into the reservoir.

In the end positions of the piston rod, any excess pressure which may arise in the container provided with the device produces an improved seal with respect to the ventilation line, since the seal 21 is pressed against the sealing seat 22 or 23 corresponding to the position.

FIG. 6 shows a view of the latching connection of piston rod 9 and guide bush 8. The piston rod 9 can be axially displaced in accordance with the longitudinal groove 26 via the cam 25 striving from the guide bush 8, while in the lower and upper end position there is a rotation in the radial direction through the groove extensions 27 for the purpose of locking under spring tension can. All parts of the device, with the exception of the return spring 17, are preferably made of plastic and are produced by archiving. If, according to FIG. 7, material to be conveyed has been sucked into the displacement 31 and the piston rod 9 is pressed down against the force of the spring element 17, the piston 16, which is axially limitedly adjustable on the piston rod 9, is axially supported on a shoulder 33 of the piston rod 9 and becomes taken away from the latter. When the valve 6 is closed, the lip seal 13 has been lifted off the piston 16 as a result of the hydraulic pressure building up in the displacement 31, so that the annular gap formed between the piston 16 and the lip seal 13 causes the material to be conveyed through the lateral opening. the groove 14 flows into the channel 11.

When the piston 16 of the piston rod 9 is pressed down, the piston 16 has also been lifted from the frame-fixed connector 8, after which atmospheric air passes through the annular gap between the piston rod 9 and the connector 8 and

Ventilation opening 24 can flow into the container, not shown, connected to the screw cap 1. When the piston rod 9 is released, the force of the spring element 17 first re-applies the lip seal 13 to the piston 16, the piston rod 9 leading over the piston 16, and then adjusting the piston 16 to its above starting position. The supply of atmospheric air through the ventilation opening 24 is maintained until shortly before the latter is reached, so that material to be conveyed is sucked into the displacement 31 again, the valve 6 opening automatically.

Claims

Patent claims

1. Device for conveying viscous

Materials, such as liquids, cream, pastes or the like, from a storage container by means of a piston pump, which is sealed to the mouth of the storage container by means of a device, for example a cap, and optionally detachably fastened, the inside of the pump cylinder having a smaller diameter than the device the device is held, the piston rod is guided in a longitudinally adjustable manner against a force of a return spring in a bore of the device and a ventilation channel leading into the reservoir is provided, the bore of the device intended for guiding the piston rod being arranged in a coaxial arrangement and continues to the suction pipe of the piston pump, the piston rod engages through the aforementioned bore and the nozzle leaving an air gap, further in the pump

cylinder between the ceiling of the device and the pump piston standing in its upper end position has a ventilation opening and a seal is provided on the piston on the front side facing the ceiling of the device which ver in the upper end position of the piston the aforementioned neck ¬ closes, characterized in that the seal (21) cooperating with the connector (8) is designed as an elastic sleeve and in the upper end position of the piston (16), in particular with elastic expansion, the connector (8) tightly encloses sums up.

2. Device according to claim 1, characterized gekenn¬ characterized in that the socket (8) is formed conically tapered on the outside towards its free end.

3. Apparatus according to claim 1 or 2, characterized in that on the guide bush (8) two with an axial distance one behind the other arranged, raised sealing seats (22 + 23) interacting with the sleeve-like ring seal (21) are provided in such a way that the ring seal (21) in both end positions of the piston (16) tightly closes one of the two aforementioned sealing seats (22 and 23), between the piston end positions but with play to the guide bushing (8).

10 4. Device for conveying viscous

Substances, such as cream, pastes or the like, from a storage container by means of a manually operable piston pump, in particular detachably connected to the latter, according to a

15 of claims 1 to 3, characterized in that the piston rod (9) is penetrated by a channel (11) forming the outlet line, on the end part of the piston rod (9) which is immersed in the pump cylinder (2)

20 ring seal (13) is arranged, behind which the piston rod channel (11) opens out laterally in the conveying direction of the medium and that the piston (16) on the piston rod (9) is axially adjustable so limited that the piston (16)

is arranged in its one end position at an axial distance from the ring seal (13) and releases the lateral channel opening, while in the other end position the piston (16) bears tightly against the ring seal (13).

5. The device according to claim 4, characterized gekenn¬ characterized in that the on the piston rod (9) arranged ring seal (13) in an in the conveying direction of the medium in front of the piston (16) an¬ arranged sealing seat (28) of the cylinder (2) is designed to be tightly immersed.

6. The device according to claim 4 or 5, characterized in that the ring seal (13) on a in the piston rod channel (11) inserted and at least frictionally secured ge pin (12) is arranged, the at least one longitudinal groove (14) has on the one hand opens on the end of the pin (12) facing away from the ring seal (13) and on the other hand in one in the piston rod (9) in the flow direction of the

Medium passes directly behind the ring seal (13) arranged opening (15).

Device according to one of claims 1 to 6, characterized in that the piston rod (9) is axially adjustable and rotatably mounted about its longitudinal axis in a guide bush (8) which is fixed to the frame, and further from the guide bush (8)

10 strives internally directed cam (25), which engages in a longitudinal groove (26) of the piston rod (9) adjustable relative to the latter and that the groove (26) in both end positions of the piston rod (9) the cam

15 (25) each has a groove extension (27) extending in the circumferential direction.