The present invention relates to a device for dispensing fluid material onto a substrate that is movable relative to the device. More specifically, the invention relates to dispensing devices used for intermittent application of liquids such as hot melt adhesive.
Dispensing devices such as application heads, are utilized in industry, for example, in order to coat areas of film or foil substrates with liquid adhesive such as hot melt adhesive. The fluid material flows out of a source of material, normally a reservoir, into the flow channel of the device, passes through a valve body, and continues to flow to a nozzle arrangement with an outlet opening. Frequently a so-called intermittent application is performed, meaning that intervals in which the valve body is in the open position and material is applied to the substrate alternate with intervals in which the valve body is in the closed position, so that the application of material is interrupted. Often, very short intervals are used in intermittent applications in order to realize application zones at very small distances from each other.
The application pattern that is produced on the substrate is normally subject to the requirement that a material application zone on the substrate have sharply delimited edges. In the case of a large-area application with the help of a known slit nozzle arrangement, it is especially desired that not only the lateral edges (in the direction of motion of the substrate relative to the application device) but also the front and rear edges of a material application zone be sharply delimited. A prerequisite for such sharp delimitation of the front and rear edges is that the valve body of the valve arrangement is moved quickly into its closed position, so that the flow of material from the outlet opening is interrupted uniformly quickly. When the valve arrangement is opened, in order to attain a sharp boundary line at the front edge of a material application zone it is necessary for the valve arrangement to open quickly and for the application of material to begin without delay.
A needle valve has been used for this purpose, having a needle with a needle tip as a valve body, which may be brought into contact with a valve seat that conforms to the shape of the needle tip. To close the valve arrangement, the needle (under electro-pneumatic actuation) is moved in the direction of the valve seat and comes into contact with the latter, so that the flow cross section of the flow channel is closed and the flow of material is thereby interrupted. During the closing motion of the needle tip, some adhesive is moved downstream by the needle tip in the direction of the outlet opening. As a result, the application of material to the substrate is not interrupted as abruptly as would be necessary to produce a sharp boundary line in the end area of an application zone. An “afterdrip” from the outlet opening during closure of the valve arrangement cannot be prevented.
A reduction of such an afterdrip of material from the outlet opening was achieved by an application head known from the published patent EP-A-0 850 697, in which a valve body that is enlarged compared to a valve shaft is moved upstream to close the valve arrangement, i.e., counter to the direction of flow of the material in the open position in the direction of the outlet opening of a nozzle arrangement. The result of this arrangement is that during the closing motion of the valve body, because of adhesion of the material to the enlarged valve body, and because of material being drawn along, there is a slight backflow of material upstream. A relatively abrupt interruption of the flow of material from the outlet opening results and it is largely possible to prevent afterdripping.
The object of the present invention is to further improve intermittent dispensing devices such that the flow of material out of an outlet opening is interrupted more abruptly, and in particular afterdripping may be prevented even more effectively resulting in very sharply delimited material application zones or application patterns on a substrate.
The present invention provides a device for dispensing fluid material onto a substrate. The device includes a base body including a flow channel for receiving the fluid material and a movable valve body positioned in the flow channel. The valve body is movable in a downstream direction into an open position to release a flow of the fluid material into the flow channel and is movable in an upstream direction into a closed position to interrupt the flow of the fluid material into the flow channel. A drive device moves the valve body between the open position and the closed position. A cylindrical chamber is positioned in the flow channel and the valve body includes a piston movable within the cylindrical chamber. The piston is sealed within the cylindrical chamber in such a way that when the piston moves in a first direction within the cylindrical chamber, the fluid material is displaced from the flow channel and when the piston is moved in a second direction opposite to the first direction, the fluid material is drawn into the flow channel.
In other aspects of the invention, the piston is positioned downstream from the cylindrical chamber in the open position and is positioned in the cylindrical chamber in the closed position. The movement of the piston from the open position to the closed position draws the fluid material into the flow channel. A valve seat engages with a portion of the valve body positioned upstream from the piston when the valve body is in the closed position. The valve body further comprises a guide section spaced from the piston and the flow channel includes guide surfaces. The guide section contacts the guide surfaces for guiding the valve body laterally as the valve body moves between the open and closed positions. The guide section further comprises a triangular cross section, and the guide surfaces further comprise portions of a cylinder. A tapered section on the valve body is positioned downstream from the piston. The cylindrical chamber and the guide surfaces are formed in a sleeve. The drive device further comprises a second piston coupled to the valve body and operative to move the valve body between the open and closed positions.
Various additional aspects will become more readily apparent by reviewing the following detailed description of the preferred embodiments.
The present invention will be described below on the basis of a number of exemplary embodiments of the device according to the invention for area application of fluid adhesive to a substrate (application head), with reference to the accompanying drawing.
The device 2 depicted in
Control part 4 is connected by means of two pressurized air lines 10, 11 to a pressurized air source, not shown, which supplies a pressure of about 6 bar. With the help of an electrically actuatable solenoid valve 12, pressurized air can be applied to control part 4. In the upper area of control part 4 are two bores 21, 23, which may optionally be connected with a pressurized air line by appropriate switching of solenoid valve 12. Control part 4 includes a drive device 15, described in greater detail below, for moving a valve body 14 of a valve arrangement 17 in order to optionally interrupt or release the flow of the fluid material in a flow channel 19 which is formed in base body 6.
The valve arrangement 17, shown enlarged in
As
Above piston 18 is a chamber 26 that may be filled with gas. It is chargeable with pressurized gas through bore 21. This makes it possible to apply a force to piston 18. Below piston 18 is another chamber 28 in bore 20 that may be filled with gas. It is chargeable with pressurized gas through line 10, bore 23 and channel 30. Piston 18 may be pressed downward in
To open valve arrangement 17 and thus release the flow of adhesive, solenoid valve 12 is actuated. This causes a pressure that corresponds approximately to the pressurized air source to be produced in chamber 26 and to operate on piston 18. To close valve arrangement 17 and thus interrupt the flow of adhesive, solenoid valve 12 is switched so that the pressure in chamber 26 is reduced. To this end, pressurized air is discharged from solenoid valve 12 into the environment. Through this reduction in pressure in chamber 26 piston 18 is pressed “upward,” and valve body 14 is moved into the closed position. The spring force of spring 32 operates supportively.
Feeding adhesive to nozzle arrangement 8, from which the adhesive is dispensed and applied to substrate 1, is the function of adhesive flow channel 19 formed in base body 6. Flow channel 19 can be supplied with adhesive from a source of adhesive via a cylindrical bore 48 in base body 6. Bore 48 communicates with a tube 50.
As illustrated in
As
In the closed position of valve body 14 shown in
As illustrated in
As
Number | Date | Country | Kind |
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201 12 891 U | Aug 2001 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP02/08728 | 8/5/2002 | WO | 00 | 8/30/2004 |
Publishing Document | Publishing Date | Country | Kind |
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WO03/015934 | 2/27/2003 | WO | A |
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1147820 | Oct 2001 | EP |
Number | Date | Country | |
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20050034657 A1 | Feb 2005 | US |