WO2003015934A1

WO2003015934A1 - Device for applying free-flowing material to a substrate moveable with respect thereto

Info

Publication number: WO2003015934A1
Application number: PCT/EP2002/008728
Authority: WO
Inventors: Thomas Burmester; Kai Luebbecke
Original assignee: Nordson Corp
Current assignee: Nordson Corp
Priority date: 2001-08-03
Filing date: 2002-08-05
Publication date: 2003-02-27
Anticipated expiration: 2004-02-03
Also published as: DE60236872D1; CN1551804A; JP2004538140A; CN1281337C; EP1417037A1; JP4195660B2; US20050034657A1; ES2344054T3; ATE472378T1; EP1417037B1; US7147136B2; DE20112891U1

Abstract

The invention relates to a method and apparatus for a device for applying free-flowing material to a substrate moveable with respect thereto with a base (6) in which a flow channel (19) for the free-flowing material is formed, a valve arrangement (17) with a moveable valve body (14) disposed within the flow channel (19). A drive means (15) co-operates with the valve body (14) to move between the open position and the closed position. A cylinder chamber (52) is provided in the flow channel, and valve body (14) has a moveable piston portion (56) inside the cylinder chamber (52). The piston portion (56) is sealed within the cylinder chamber (52) in such a manner that the free-flowing material is displaced and/or drawn up when the piston portion (56) moves inside the cylinder chamber.

Description

Device for applying free-flowing material to a substrate moveable with respect thereto

The present invention relates to a device for applying free-flowing material to a substrate that is moveable relative to said device, comprising a base in which a flow channel for the free-flowing material is provided, a valve arrangement with a moveable valve body disposed within the flow channel, wherein said valve body is moveable downstream into a position that opens the flow channel in order to release the flow of material in the flow channel, and moveable upstream into a position that closes the flow channel in order to interrupt the flow of material flow in the flow channel, and a drive means that co-operates with the valve body to permit the valve body to move between the open position and the closed position.

In industry, devices of this kind, which are often referred to as application heads, are used, for example, to coat the surfaces of film-type substrates with liquid adhesive, such as hot-melt glue. The free-flowing material flows from a source of material into the flow channel of the device, usually from a container, passes the valve body and flows on to a nozzle arrangement with an outlet opening, from which the material is dispensed and applied to a substrate. More frequently, so-called intermittent application is performed, i.e., intervals in which from which the material is dispensed and applied to a substrate. More frequently, so-called intermittent application is performed, i.e., 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, thus interrupting the application of material. When application is intermittent, very short intervals are often used in order to obtain application zones that are spaced closely together.

The common requirement with regard to the pattern of application on the substrate is that a zone where material is applied must have sharply defined boundaries. In the case of application to a surface using a known slit nozzle arrangement, it is particularly desirable that not only the lateral edges - in the direction of substrate movement relative to the application device - but also the leading and trailing edges of a zone where material is applied be sharply delimited. The prerequisite for such sharp delimitation of the leading and trailing edges is that the valve body of the valve arrangement be moved quickly into its closed position, so that the flow of material out of the outlet opening is interrupted equally quickly. In order to achieve a sharply defined line at the leading edge of an application zone, it is necessary, when the valve arrangement is opened, that this be done quickly and that the application of material begin without delay.

In the prior art, a so-called needle valve is used for this purpose; the valve body comprises a needle with a needle tip that can be brought into contact with a valve seat matching the shape of the needle tip. To close the valve, the needle is moved by electro-pneumatic means in the direction of the valve seat, with which it comes into contact in such a way that the flow cross-section of the flow channel is closed and the flow of material is interrupted. During the closing movement of the needle tip, a little adhesive is forced downstream by the needle in the direction of the outlet openings. This results in the application of material to the substrate not being interrupted as abruptly as would be necessary to produce a sharp boundary line at the end portion of an application zone. "Afterdripping" from the outlet opening on closing the valve cannot be prevented. Reducing such afterdripping of material from the outlet opening is achieved by the application head known from the published EP-A-0 850697, in which an extended valve body as opposed to a valve shaft is moved upstream to close the valve, i.e. against the flow direction of the material in the open position toward the outlet opening of a nozzle arrangement, thus leading, during the upstream closing movement ofthe valve body upstream, to a slight reverse flow of material due to material adhering to the extended valve body and due to additional material being earned along, with the result that there is relatively abrupt interruption of the flow of material from the outlet opening and to afterdripping being largely preventable. In the latter device, the valve body is positioned inside a chamber provided in the flow channel, said chamber being much larger than the valve body.

The object of the present invention is to provide a device of the kind described at the outset, with which the flow of material in the flow channel of the device and hence from an outlet opening of a nozzle arrangement can be interrupted even better, that is to say more abruptly, and, in particular, with which afterdripping can be prevented more effectively, so that, for example, very sharply defined zones or patterns of application can be produced.

The invention achieves said object with a device (application head) of the kind initially specified by having a cylinder chamber in the flow channel, by the valve body having a moveable piston portion inside the cylinder chamber, and by the piston portion being sealed inside the cylinder portion in such a way that the free-flowing material is displaced and/or drawn up when the piston portion moves inside the cylinder portion.

The invention essentially achieves the benefits that, by providing the valve body with a moveable and essentially sealed piston portion inside a cylinder chamber, the material is positively displaced in a defined manner within the flow channel when the piston portion moves. By upstream movement of the piston portion of the valve body into the closed position, that is to say against the direction of material flow when the valve arrangement is open, the material is drawn up and made to flow upstream. In that portion of the flow channel located downstream from the valve body, in particular, the material is drawn up and flows upstream, and may even flow back at the outlet opening of a nozzle arrangement in such a way that the flow of material from the outlet opening is interrupted very abruptly and any afterdripping is with certainty prevented. This enables very sharply defined zones or patterns of material application on the substrate to be achieved. With the help of a slit nozzle arrangement, in particular, it is also possible to produce sharply delimited trailing edges on the application pattern when adhesive is applied to the surface of films, packaging and the like. This is achieved by disposing the piston portion inside the cylinder portion such that it is essentially sealed. A preferable way to achieve the seal is by having a narrow (O-shaped) gap between the outer circumferential surface of the piston portion and the inside surface of the cylinder portion, in that the cooperating components (cylinder portion and cylinder chamber) are sized accordingly and have appropriate tolerances; in such a case, it is possible to dispense with additional sealing means, such as sealing rings, piston rings, or the like. According to the invention, however, such additional sealing means may also be provided to improve a seal between the piston portion and the cylinder portion.

In a preferred embodiment of the invention, the piston portion is positioned downstream from the cylinder chamber when in the open position and is moved upstream into the cylinder chamber such that material is transported upstream within the cylinder chamber by movement of the piston portion. From its open position, in which the downstream flow of material occurs, the piston portion is moved into the cylinder chamber, and, as soon as a certain sealing effect is produced between the piston portion and the cylinder chamber, material is displaced upstream from the piston portion, material is drawn upstream from the piston portion in a defined manner, and the flow of material is interrupted.

In another preferred embodiment of the invention, it is proposed that the valve arrangement has a valve seat (25) associated with the flow channel, and that, upstream from the piston portion, the valve body has a ring-shaped surface that comes into contact with the valve seat when in the closed position. In addition to this seal between the piston portion and the cylinder chamber, a valve seat also achieves a defined and total blockage of the flow channel.

Yet another preferred embodiment of the invention is characterised in that the valve body has a guide portion at a distance from the piston portion for laterally guiding the valve body, wherein said guide portion is in contact with opposite guide surfaces of the flow channel that demarcate said flow channel. In this way, the valve body is guided in a defined manner and precisely centred inside the flow channel. The guide portion is designed in such a way that a free flow cross-section for the material is formed between said guide portion and the guide surfaces of the flow channel. Preferably, the guide portion has an essentially triangular cross-section, and the guide surfaces of the flow channel are essentially cylindrical. By virtue of the guide portion having an essentially triangular cross-section, the free flow cross-section of the flow channel can be maximized with little production effort, for example by milling the guide portion. Alternatively, the guide portion is essentially square in cross-section. On the guide portion of the valve body, axial grooves may also be provided to enable the material to flow along the guide portion.

A suitable feature is to provide the valve body with a tapering portion opposite and downstream from the piston portion. Such a tapering portion serves as a contact surface for the valve body.

Another benefit with regard to production of the device is achieved when the cylinder chamber is formed by a sleeve that is mounted in the base, and that the guide surfaces of the flow channel are formed by said sleeve. Since the cylinder portions and the guide surfaces are exposed to friction and hence to wear and tear, it is then easy to replace such sleeves.

A preferred embodiment is characterised in that the drive means has a piston to which compressed air can be applied, said piston being connected via a valve shaft to the valve body so that the valve body can be moved by applying compressed air to the piston. With the help of such a piston, which can be connected to a source of compressed air, the valve arrangement can achieve high switching frequencies, i.e., a very rapid movement of the valve body from the open to the closed position, and vice versa, as is necessary for intermittent application at a relatively high frequency.

Other advantageous embodiments of the invention are described in the subclaims.

The invention will now be described on the basis of several embodiments of the device for planar application of a fluid adhesive to a substrate (application head), with reference to the accompanying drawings. The drawings show:

Figure 1 a device in accordance with the invention, for applying liquid adhesive to a substrate using an application head, in a partial cutaway view

Figure 2 a lower section of the device shown in Fig. 1 , in a cutaway view

Figure 3 a partial cutaway view of a valve body with piston portion in accordance with the invention

Figure 4 a cross-sectional view of section A-A in Fig. 3

Figure 5 a cross-sectional view of a sleeve containing the cylinder portion

Figure 6 a section of the device according to the invention, with the valve body in the open position

Figure 7 a section of the device according to the invention, during the upstream movement of the valve body

Figure θ a section of the device according to the invention, with the valve body in the fully closed position

The device 2 shown in Fig. 1, also referred to as an application head 2, is used to apply liquid adhesive or other free-flowing material onto a substrate 1 that is moveable, relative to device 2^* in the direction shown by arrow 3. Said application head 2 comprises an electrc-pneumatically operated control unit 4 and a base 6 or basic body connected thereto, The base 6 has a bored hole 7 into which a lower portion of the control unit 4 is inserted. A nozzle arrangement detachably screw-mounted on one side of the base 6. The base 6 and hence the application head 2 is mounted by means of a rod 9 to a stationary support 13 and can be longitudinally displaced and affixed in different positions along rod 9.

The control unit 4 is connected by means of two compressed air lines 10, 11 to a source of compressed air, not shown, which provides a pressure of about 6 bar. With the help of a electrically activated solenoid valve 12, compressed air can be supplied to the control unit 4. In the upper portion of control unit 4, there are two bores 21, 23, which can be sefectably connected to a compressed air line by operating solenoid valve 12 accordingly. Control unit 4 comprises a drive means 15, described in further detail below, for moving a valve body 14, a valve arrangement 17 for selectably interrupting or releasing the flow of the free- flowing material in a flow channel 19, which is provided in base 6.

The valve arrangement 17 shown in enlarged form in Fig. 2 comprises the moveable valve body 14 positioned inside flow channel 19, a rod-shaped, axially moveable valve shaft 16 that is screw-connected to said valve body, and a valve seat 25 associated with flow channel 19. The moveable valve body 14 co-operates with valve seat 25 in such a way that the flow of material is stopped entirely by the valve body 14 moving upstream into a closed position, and released again by downstream movement of the valve body into an open position.

A Fig. 1 shows, the drive means 15 for moving the valve shaft 16 and the valve body 14 has a piston 18 operated by compressed air, the top end of which is attached to the moveable valve shaft 16. Piston 18 is positioned inside a bored hole 20 within control unit 4 and is axially slidable. Piston 18 is provided with a centrally bored hole 27 in which an end portion of valve shaft 16 is disposed. A screw 24 which fastens piston 18 to valve shaft 16 is screwed into an internal thread bored into the end of valve shaft 16.

Above piston 28 there is a chamber 26 which can be filled with gas and to which compressed gas can be supplied via bore 21. By this means, pressure can be applied to piston 8. Below piston 28 there is another chamber 28 inside bore 20 which can be filled with gas and to which compressed air can be supplied via air line 10, bore 23 and connecting channel 30. in Fig. 1, piston 18 can be pushed downward in a downstream direction toward nozzle arrangement 8, such that valve body 14 is moved into its open position. Piston 18 is sealed against base 22 with O-rlngs in a manner which is not described in further detail. Inside chamber 28, a helical spring 32 is disposed concentrically to the essentially cylindrical valve shaft 16 such that its spring force acts on piston 18 and biases it - in an upward direction in Fig, 4 - into the closed position of valve body 14 in valve arrangement 17.

In order to open valve arrangement 17 and thus release the flow of adhesive, solenoid valve 12 is activated. This causes a pressure to be generated in chamber 26 that is approximately equal to that of the compressed air source and which acts on piston 18. In order to close valve 17 and hence interrupt the flow of adhesive, the solenoid valve 12 is controlled in such a way that the pressure in chamber 26 is reduced. This is achieved by releasing compressed air from the solenoid valve 12 to the surroundings. As a result of this reduction of pressure in chamber 26, piston 18 is pressed upward, and valve body 14 is moved into the closed position. This is supported by the force of spring 32,

In order to supply adhesive to the nozzle arrangement 8 from which the adhesive is dispensed and applied to the substrate 1 , there is an adhesive flow channel 19 in the base 6 that is fed with adhesive from an adhesive source via a cylindrical bore 48 within the base 6. Bore 46 communicates with a pipe 50.

As shown in Figures 2 and 3, a cylinder chamber 52 is provided in the lower portion of flow channel 19 that is defined by a cylindrical portion of a sleeve 54 that is detachably affixed into the base 6. Figures 5 - 8 also show cylinder chamber 52. Valve body 14 includes a piston portion 56 that co-operates with cylinder chamber 52, said piston portion having an essentially cylindrical outer surface, as can well be seen from the drawing of the valve body 14 in Fig.3. Piston portion 56 is sized in such a way that it can moved with minimal tolerance into and out of the cylinder chamber 52 of flow channel 19 and is sealed inside cylinder chamber 52 in such a way that, when piston portion 56 is moved, free- flowing material in the flow channel 29 is displaced and/or drawn up into the chamber. Due to the relatively tight fit between the cylindrical circumferential surface of cylinder portion 56 and the inside surface of cylinder chamber 52, which is delimited by a portion 58 of steeve 54 that has a cylindrical inside surface, free-flowing material is positively and precisely displaced or drawn in. This also has the effect of the downstream flow of material in the flow channel 19, i.e. in the direction shown by arrow 57 in Fig. 2, being interrupted as soon as piston portion 56 plunges into cylinder chamber 52.

As shown in Fig. 6, piston portion 56 is positioned downstream (cf. arrow 52) from cylinder chamber 52 when valve arrangement 17 is open, and can be moved upstream into cylinder chamber 52 (in the opposite direction to that shown by arrow 52). Fig. 7 and Figs. 6 - 8 show the upstream - upwards - movement of valve body 14 with piston portion 56, whereupon piston portion 56 plunges into cylinder chamber 52 (Fig.7). When valve body 14 is positioned as shown in Fig.7, the downstream flow of material into flow channel 19 is interrupted. On further upstream - upwards - movement of the valve body and piston portion 56, displacement of the free-flowing material above piston portion 56 occurs due to piston portion 56 being sealed against the inside surface of cylinder chamber 52, with the result that there is upstream flow of the material and simultaneously, in the section downstream from piston portion 56, that free- flowing material in the lower portion of flow channel 19 is drawn up and hence transported upstream, which effectively prevents any afterdripping at the slit- shaped outlet opening 58 of the nozzle arrangement that communicates with flow channel 19.

When valve body 14 is in the closed position as shown in Fig.8, a ring-shaped surface 60 formed at a conical portion adjacent to piston portion 56 (see also Fig.3) is in contact with a valve seat 25 formed at sleeve 58 (see also Fig.5).

As shown by Figures 2, 3 and 4, valve body 14 has a guide portion 62 adjacent to the conical portion for laterally guiding valve body 14. Said guide portion 62 ensures axial guidance and, with three guide surfaces 64 (see Fig. 3), is in contact with an opposite guide surface 66 on sleeve 54 (Fig. 5). Guide surfaces 64 of guide portion 62 are disposed in the outer peripheral areas of guide portion 62 and have a curved, cylindrical shape such that they match the cylindrical guide surface 66. Guide portion 62 is triangular in cross-section. This means that three identical, free cross-sections of flow 66 (Fig.4) are formed, each shaped like the segment of a circle, between guide portion 62 and the inside surface of sleeve 54, in particular at guide surfaces 66. These two flow cross-sections 66 are part of flow channel 19. Alternatively, guide portion 62 could have a square crass-section or have axial grooves.

As shown by Figures 2 and 3, there is first of alt a conically tapering portion 68 downstream - below piston portion 56 -, to which is connected a square portion 70 that tapers away from piston portion 56, whereby the lower ring-shaped surface 72 of he square portion 70 forms a support surface that, when the valve body is in the fully open position (Fig.6), is in contact with an insertion body 74 that is inserted into the base 6 and delimits the bottom end of flow channel 19.

Claims

1. Device for applying free-flowing material to a substrate moveable with respect thereto with a base (6) in which a flow channel (19) for the free-flowing material is formed, a valve arrangement (17) with a moveable valve body (14) disposed within the flow channel (19), wherein said valve body is moveable downstream into a position that opens the flow channel (19) in order to release the flow of material in the flow channel (19), and moveable upstream into a position that blocks the flow channel in order to interrupt the flow of material in the flow channel, a drive means (15) that co-operates with the valve body (14) to permit the valve body (14) to move between the open position and the closed position, characterised in that a cylinder chamber (52) is provided in the flow channel, and the valve body (14) has a moveable piston portion (56) inside the cylinder chamber (52), and that the piston portion (56) is sealed within the cylinder chamber (52) in such a manner that the free-flowing material is displaced and/or drawn up when the piston portion (56) moves inside the cylinder chamber.

2. Device according to claim 1 , characterised in that the piston portion (56) is disposed downstream from the cylinder chamber (52) when in the open position and is moved upstream into the cylinder chamber (52) such that material is transported upstream within the cylinder chamber (52) by movement ofthe piston portion (56).

3. Device according to claim 1 , characterised in that the valve arrangement has a valve seat (25) associated with the flow channel and that, upstream from the piston portion (56), the valve body (14) has a ring-shaped surface (60) that comes into contact with the valve seat (25) in the closed position.

Device according to one of the above claims, characterised in that the valve body (14), at a distance from the piston portion (56), has a guide portion (62) for laterally guiding the valve body (14) and which interacts with opposite guide surfaces (66) of the flow channel that demarcate the flow channel.

5. Device according to claim 4, characterised in that the guide portion (62) has an essentially triangular cross-section and that the guide surfaces (66) of the flow channel are essentially cylindrical.

6. Device according to claim 4, characterised in that the guide portion (62) is essentially square in cross- section.

7. Device according to at least one of the above claims, characterised in that the valve body (14) has a tapering portion (70) opposite the piston portion (56) downstream from the piston portion (56).

8. Device according to one of the above claims, characterised in that the cylinder chamber (52) is formed by a sleeve (54) mounted in the base member (6), and that the guide surfaces (66) of the flow channel are formed by the sleeve (54).

9. Device according to one of the above claims, characterised in that the drive means (15) has a piston (16) to which compressed air can be applied, said piston being connected via a valve shaft (19) to the valve body (14) so that the valve body (14) can be moved by applying compressed air to said piston (18).

10. Device according to one of the above claims, characterised in that a slit nozzle arrangement (8) that is fed through the flow channel (19) with free-flowing material is detachably affixed to the base member.

11. Device according to one of the above claims, characterised in that sealing means for enhancing the seal are provided on the piston portion (56) and/or the cylinder chamber (52).

1 . Device according to claim 11 , characterised in that the sealing means has elastic sealing rings or piston rings essentially consisting of a rigid material.