The present invention relates to a device for pressing a substance out of a deformable tube. The tube can consist of plastics material or metal, for example. The substance to be pressed out can be in particular an adhesive.
Devices of this kind for pressing a substance out of a deformable tube are intended to make it easier to handle the tube and to press out and apply the substance to a surface. In particular the dosing of the substance is intended to be made easier.
A device for pressing a substance out of a deformable tube is known from EP 24 90 956 B1, which device comprises a housing and a squeezer that can be inserted into the housing, the squeezer comprising a support element and two jaws positioned opposite one another for gripping and squeezing a substance out of the tube. Lever elements are attached to the jaws for manual operation of the squeezer.
It is an object of the present invention to disclose an improved device for pressing a substance out of a deformable tube. In particular, the handling of the device is to be improved to the effect that the substance can be precisely dosed and the tube emptied, even with a relatively low force exertion.
This object is achieved by the subject matter of the independent claim. Further embodiments are the subject matter of the dependent claims.
According to one embodiment of the invention, a device for pressing a substance out of a deformable tube is disclosed, which device comprises a housing having a base end, an upper portion opposite the base end and lateral wall portions between the base ends and the upper portion. The device further comprises a squeezer that can be inserted into the housing, the squeezer comprising a support element and two jaws positioned opposite one another for gripping and squeezing a substance out of the tube.
The housing further comprises an opening in the upper portion, through which a dispensing outlet of the tube can be guided, and openings in opposite sides of the lateral wall portions, by means of which the jaws can be operated, the jaws being secured at one end to the support element and the squeezer furthermore comprising a manual lever element on at least one jaw.
The lever element is connected to the jaw in a connection region in an arrangement in which pressure applied manually to the lever element produces a force on one jaw towards the other jaw. The lever element comprises a body that has reinforcing ribs, the reinforcing ribs being surrounded, at least in part, by a closed outer shell, one region of the outer shell forming a grip region.
According to this embodiment, a device is provided by means of which a user can squeeze a substance out of the deformable tube by exerting pressure, in the grip regions, on the manual lever elements. This pressure is transferred from the lever element to the jaws and from the jaws to the deformable tube.
The device is advantageous in that the lever element is particularly suitable for transferring a relatively low force to the deformable tube in a particularly effective manner. For this purpose, the lever element is not completely solid and therefore not completely stiff, but rather has a degree of flexibility on account of the reinforcing ribs, without losing load-bearing capacity. The reinforcing ribs are in this case not exposed in the grip region but are covered by a closed outer shell. This substantially improves the handling of the device, since rib-like structures exposed in the grip region can push into the fingers of the user when the device is being handled. This is at least uncomfortable but can even be painful, which negatively affects the handling of the device.
According to one embodiment of the invention, the lever element has a concave portion on the at least one jaw at the same height as the connection region. This has the object of further improving the handling of the device. Said portion creates a secure hold for the fingers of a user and prevents the fingers from slipping off in the event of pressure being exerted. Furthermore, the concave portion visually emphasizes the grip region.
Moreover, the lever element can be convex, for example.
According to one embodiment of the invention, the radius of curvature r of the outer shell of the lever element in the concave portion is 5 mm≤r≤50 mm, in particular 16 mm≤r≤35 mm. It has been demonstrated that a portion curved in such a way offers a particularly secure hold in the grip region.
According to one embodiment of the invention, grip ribs are arranged in the grip region on the outer shell of the lever element. The grip ribs can be formed for example as relatively small elevations of at most 1 mm on the outer shell and can be arranged in particular so as to be transverse to the longitudinal direction of the lever element. The object of the grip ribs is to prevent the fingers of a user from slipping off and thereby further improve the handling.
The grip ribs can be formed for example from the material of the outer shell and be integral therewith.
According to one embodiment of the invention, the connection region between the lever element and the jaw has a length L, L being less than 25% of the length of the jaw. Length measurement in this case is assumed to be in the longitudinal direction of the lever element or the jaw.
For example, L is 2 mm≤L≤20 mm, in particular 3 mm≤L≤12 mm.
It has been demonstrated that the connection between the lever element and the jaw, in the case of said dimensions, is robust and stable enough to reliably transfer a force exerted by the user on the lever element to the jaws. However, the connection is relatively flexible and therefore makes it easier to handle the device.
It is furthermore advantageous for the connection region between the lever element and the jaw to have a maximum width v, which is at most half of the width b of the jaw in said region. For example, v can be at most 7 mm.
Furthermore, it is additionally advantageous for the connection region between the lever element and the jaw to be arranged substantially in the third quarter of the jaw as seen from the support element. Therefore, in one embodiment of the device, the connection region is arranged in an upper half of the jaw, remote from the support element, but not in the region of the uppermost 20% of the jaw.
This arrangement allows an optimal lever action to be achieved. The connection region channels the force exerted by a user and distributes it over the entire length of the jaw. If the connection region is arranged too close to the opening in the housing and therefore too close to an outlet of the tube, problems can arise with respect to handling because the tube is not sufficiently flexible in the immediate vicinity of its outlet. Complete emptying of the tube can also be problematic.
If in turn the connection region is arranged so as to be too far removed from the opening in the housing and therefore from the outlet of the tube, the leverage exerted on the jaw is significantly lower and it is no longer possible to handle the device with low forces.
According to one embodiment, the body of the lever element is integral with the jaws. This is advantageous in that the lever element and the jaws can be particularly flexible and simultaneously stable.
According to one embodiment, the housing is open at the base end thereof and the squeezer can be inserted into the housing through the open end thereof and fixed therein. A secure connection between the housing and the squeezer can be achieved in this way.
Embodiments of the invention are described in more detail below with reference to the drawings, in which:
The housing 1 further comprises one opening 8 in each of the two opposite sides, in the lateral wall portions 4 of said housing. Below the openings 8, the lateral wall portions 4 project outwardly and form shoulders 9, such that the open base end does not have a round cross section but rather likewise comprises projections.
The squeezer 10, which is shown in detail in
In a resting state, the jaws 12 diverge from one another at the upper end 14 thereof. This is shown in
Each jaw 12 comprises a lever element 15 that can be manually operated, i.e. by a user and by hand. Each lever element 15 is connected to the jaw 12 in a connection region 20. Said element can be produced for example as an injection-molded part so as to be integral with the jaw 12. The connection region 20 extends in the longitudinal direction of the jaw 12, or of the lever element 15, and, in the embodiment shown, is arranged substantially in the third quarter of the jaw 12 as seen from the support element 11, that is to say, in the upper half of the jaw 12, remote from the support element 11, but not in the region of the uppermost 20% of the jaw 12. A very effective lever action is achieved as a result, which allows the tube to be squeezed very precisely and with relatively low force exertion, simultaneously allowing residue to be emptied effectively from the tube. The force required to squeeze the tube is typically in the range between 18 and 28 N, in particular between 20 and 25 N.
Furthermore, the connection region 20 merely extends at most over a quarter of the length of the jaws 12, such that the jaws 12 remain flexible. High flexibility of the jaws 12 is also achieved by the connection region 20 having a maximum extent in the transverse direction of half the width of the jaws 12. In the embodiment shown, the connection region 20 is 6.8 mm wide at the widest point thereof.
The lever element 15 comprises a body 16 having reinforcing ribs 17. Said ribs cause the lever element 15 to be sufficiently stable despite its non-solid formation. Solid formation of the lever element 15 would lead to a lack of flexibility and thus to more difficult handling of the device. The reinforcing ribs 17 can be formed transversely to the longitudinal direction of the lever element 15, as shown in
The reinforcing ribs 17 are not exposed at the surface of the lever element 15 at least in a grip region 19 of the lever element 15, but instead are surrounded, or covered, by an outer shell 18. A user of the device therefore does not come into contact with exposed reinforcing ribs 17 when using the device in the intended way. The outer shell 18 can surround the lever element 15 completely or only in specific regions. In the embodiment shown, the reinforcing ribs 17 (as can be seen in
The lever element 15 has a concave portion 21 at the same height as the connection region 20, in which portion the grip region 19 is formed concavely in order to offer a better fingerhold.
The functioning of the squeezer when a tube (not shown in the drawings for sake of clarity) is squeezed is explained with reference to
Number | Date | Country | Kind |
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10 2016 206 084 | Apr 2016 | DE | national |
Number | Name | Date | Kind |
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6315165 | Regan | Nov 2001 | B1 |
8752543 | Davies | Jun 2014 | B2 |
8794858 | Kirk, III | Aug 2014 | B2 |
20070218229 | Nagahama | Sep 2007 | A1 |
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Entry |
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International Search Report for International PCT Patent Application No. PCT/EP2017/058680 dated May 29, 2017. |
Number | Date | Country | |
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20190100356 A1 | Apr 2019 | US |
Number | Date | Country | |
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Parent | PCT/EP2017/058680 | Apr 2017 | US |
Child | 16154099 | US |