KR101424318B1 - Ink cartridges having heat-staked vent sealing members - Google Patents

Abstract

In one embodiment, the ink cartridge includes: a main body configured to receive ink; an air vent portion provided on the main body, the air vent portion being configured to allow the inflow of air into the main body and the outflow of air out of the main body; And the sealing member is thermally fused to the body.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to ink cartridges,

The present invention relates to an ink cartridge having heat-staked vent sealing members and a method of manufacturing the ink cartridge.

The ink cartridge used in an ink jet printer typically includes a vent portion that allows air to enter the cartridge when the ink is ejected from the cartridge. This air passage into the cartridge prevents the creation of a vacuum in the cartridge, thereby facilitating the ejection of ink from the cartridge.

The vent portion of the ink cartridge is normally sealed prior to use to prevent evaporation of the ink contained in the cartridge and leakage from the vent portion due to pressure changes during transportation. In some cases, the vent portion is covered by the sealing member and removes the sealing member before the end user mounts the cartridge in the printer. Often, such a sealing member is held in place by a pressure sensitive adhesive. Unfortunately, such adhesives exhibit high failure rates, especially when the adhesives are exposed to high temperatures and / or high altitudes (low pressures). If the adhesive force is lost, air may enter the cartridge and dry the ink contained in the cartridge.

As described above, the ink cartridge vent portion can be sealed using the sealing member attached to the cartridge by the pressure-sensitive adhesive. Unfortunately, by using a pressure-sensitive adhesive, the failure rate can be increased particularly when the adhesive is exposed to high temperatures and / or high altitudes.

Therefore, the present invention aims to solve such a problem.

However, as described later, a low failure rate can be achieved when the sealing member is heat staked to the cartridge. The thermal fusion process can raise the temperature of the air contained in the cartridge and thereby expand the air, so that the thermal fusion can be performed in a multi-step process in which the vent portion is not completely sealed until the final stage of the thermal fusion. In this case, air can be discharged from the cartridge during the heat-sealing process. In some embodiments, the thermal welding element used in the thermal welding process maintains an air gap between the sealing member and the cartridge to provide a passage through which air can be discharged.

The ink cartridge described can be better understood with reference to the following drawings. The components in the drawings are not necessarily drawn to scale.

1 is a front perspective view showing an embodiment of an ink cartridge including a heat-sealable vent seal member,
Fig. 2 is a rear perspective view of the ink cartridge of Fig. 1,
FIG. 3 is a partial rear perspective view of the ink cartridge of FIGS. 1 and 2, showing one embodiment of the air vent portion of the cartridge before it is covered by the sealing member;
Fig. 4 is another partial rear perspective view of the ink cartridge of Fig. 3, showing the cartridge after the air vent has been covered by the sealing member, Fig.
5A to 5C are partial plan views of the ink cartridge of FIG. 3, showing multiple steps of a thermal fusion process in which a sealing member is thermally fused to a cartridge,
FIG. 6 is a partial side view of the ink cartridge of FIG. 3, showing a heat seal element bonded to a sealing member,
Fig. 7 is another partial side view of the ink cartridge of Fig. 3, showing the cartridge after the second step of the thermal fusion bonding shown in Fig.
FIG. 8 is another partial rear perspective view of the ink cartridge of FIG. 3, showing the exposure of the air after the cut-away portion of the sealing member is removed; FIG.

1 and 2 show an embodiment of an ink cartridge 10 configured to receive ink and supply it to a printing apparatus such as a printer. As shown in the figure, the ink cartridge 10 includes a polymer body 12 formed, for example, by injection molding. The body 12 includes a front face 14, a rear face 16, an upper face 18, a lower face 20 and opposite opposite faces 22. A finger tab 26 extends upwardly from the lower end of the front face 14 and can be used for insertion of the cartridge 10 into the printing apparatus and / or removal of the cartridge from the printing apparatus. have. An ink outlet 28, which is capable of ejecting ink from the cartridge 10, extends downwardly from the lower surface 20.

1 and 2, it is shown that a sealing member 30 is attached to the surface of the top surface 18 and a portion of the rear surface 16, (Not shown in Figs. 1 and 2) provided on the top surface of the cartridge so that the cartridge can be sucked into and ejected from the cartridge. In some embodiments, various indicia are printed on the sealing member 30, so that the sealing member also serves as a label. Examples of indications that can be printed on the sealing member 30 include an indication of the manufacturer of the cartridge, the model number of the cartridge, the date of manufacture of the cartridge, and the like. As an example, the sealing member 30 comprises a thin strip of polymeric material.

As will be described later, the sealing member 30 is thermally fused to the cartridge 10. More specifically, the sealing member 30 is thermally fused to the surface of the upper surface 18 in a discrete position. Further, the sealing member 30 is bonded to the cartridge 10 by an adhesive. In some embodiments, a thermal adhesive is provided along the entire length of the sealing member 30 and a pressure-sensitive adhesive is provided in a discrete position that is inconsistent with the air vent portion described below. 1 and 2, the sealing member 30 is provided with a cutout slit (not shown) that facilitates intentional cutting of the sealing member at a predetermined point along the length of the sealing member to expose the vented portion to ambient air tear slit 34). The portion of the sealing member extending from the distal end 36 of the sealing member to the cutout slit 34 includes the cutout portion 38 of the sealing member that can be removed by the user prior to use of the cartridge 10. [ As an example, the cut-away portion 38 is cut away using the end portion 32 of the sealing member 30 that does not adhere to the cartridge 10 and serves as a pull tab.

Figure 3 shows an exemplary embodiment of an air vent portion 50 provided on the top surface 18 of the cartridge 10. 3, the vent portion 50 includes a labyrinth vent (not shown) including a vent opening 52 provided in a circular recess 54 in fluid communication with an elongated vent channel 56 And a labyrinth vent. The channel 56 includes a serpentine channel section 58 extending from the recess 54 to the linear channel section 60. The channel 56 is terminated at the T-shaped end 62 exposed when the cut-out portion 38 of the sealing member 30 is removed by the end user, as described below.

3, a plurality of thermal welding elements 64 are provided on the surface 66 forming the upper edges of the circular recesses 54 and the vent channels 56. As shown in FIG. In the illustrated embodiment, the heat seal element 64 includes a small cylindrical element that is formed integrally with the top surface 18 of the cartridge 10. Although cylindrical elements have been shown and described, it will be appreciated that the heat seal element 64 may include other shapes, including conical, round dome, ribbed, and the like. In some embodiments, the heat-seal element 64 has a height of about 30 [mu] m to 500 [mu] m. As an example, the heat seal element 64 has a height of about 200 mu m.

The exemplary cartridge 10 shown in Figure 3 includes a first pair of elements located on opposite sides of the circular recess 54, a second pair of elements located on opposite sides of the linear channel section 60, Includes one element located within the last curved portion of the meandering channel section 58 prior to the section and seven thermally welded elements 64 including a pair of elements 68 located on opposite sides of the middle portion of the meandering channel section do. Depending on the requirements in a particular cartridge application, more or less thermal welding elements 64 may be used, or may be located at different locations. As will be described below, the thermal welding element 68 may be the final element to be bonded to the sealing member 30, in which case the thermal welding element 68 is moved outwardly from the cartridge 10 during the previous stage of the thermal welding process Allow air to escape.

Fig. 4 shows the sealing member 30 disposed in place on the air vent portion 50 before thermal fusing. At this point the sealing member 30 is adhered to the top surface 18 and rear surface 16 of the cartridge 10 such that the vent channel 60 including the T-shaped distal end 62 and the circular recesses 54 ). In particular, the sealing member 30 is not bonded to the cartridge along its entire length. Instead, at least in some embodiments, the portion of the sealing member 30 that rests on the air vent portion 50 does not adhere to the cartridge 10 because it only contains a non-heated thermal adhesive. However, it will be appreciated that a portion of the cut-away portion 38 and the portion of the sealing member 30 that includes the remaining portion of the sealing member lying on the top surface 18 (i.e., between the air vent portion 50 and the front surface 14) And the other portion is adhered to the cartridge 10 by the pressure-sensitive adhesive provided on the lower side of the sealing member. Thus, the pressure-sensitive adhesive maintains the sealing member 30 in place until the heat fusion is performed.

After the sealing member 30 is attached to the cartridge 10, it can be further fixed to the cartridge using a heat fusion process. Figs. 5A to 5C show various steps of a multi-step thermal fusing process in which a plurality of thermal fusing dies bring the sealing member 30 into contact with the cartridge 10. Fig. More specifically, Figs. 5A-5C show contours of the footprints of three different die to match the heat-seal element 64 on which the die operates. Referring first to Figure 5a, the first die 70 applies heat to the three heat sealing elements 64 closest to the T-shaped distal end 62 and the two heat sealing elements close to the circular recess 54 Is used. In particular, the first die 70 does not overlap with the heat-sealing element 68, and therefore heat is not applied to these heat-sealing elements 68. When heat is applied to the heat seal element 64, the thermal adhesive is activated and the seal member 30 is bonded to the top surface 18 of the cartridge 10. Further, the heat-welding element 64 is melted and bonded to the sealing member 30. [ More specifically, the heat sealing element 64 is bonded to the substrate of the sealing element 30. [ This bonding is shown in Figure 6 where the thermal welding element 64 extends through the thermal adhesive layer 80 and the peeling layer 82 of the sealing member 30 to the base material 84 of the sealing member .

Next, referring to FIG. 5B, the second die 72 is used to apply heat to the same heat seal element 64 as that heated in the step shown in FIG. 5A. In addition, the second die 72 does not overlap with the thermal welding element 68, so that heat is not applied to these thermal welding elements 68. 5A and 5B, heat is not applied to the heat-sealing element 68, so that these heat-sealing elements 68 are not bonded to the sealing member 30, Is not activated. These thermal fusing elements 68 support the sealing member 30 above the surface 66 since the thermal fusing elements 68 extend up from the surface 66 of the top surface 18, Forming air gaps through which air in the expanding cartridge 10 can escape during the first two steps. This state is shown in Fig. As shown in FIG. 7, the heat seal element 64 forms a void 86 through which air can escape, as indicated by the arrow 88.

Next, referring to FIG. 5C, a heat-resistant wear third die 74, which overlaps with the three heat-seal elements 64 closest to the T-shaped distal end 62, as well as the heat seal element 68, . After the final stage of the thermal fusion, the sealing member 30 is hermetically sealed to the cartridge 10, thereby allowing air to flow into the cartridge through the vent portion 50 or outflow of air out of the cartridge .

At this point, the manufacture of the cartridge 10 is complete, and such a cartridge can be provided to the end user for the printing apparatus. To use such a cartridge, the user will first remove the cut-out portion 38 of the sealing member 30 shown in Fig. In particular, the user pulls the end portion (pull tab) 32 of the sealing member 30 to pull the back surface 16 and the upper surface 18 of the cartridge 10 against the adhesive force of the pressure- The sealing member is peeled off from a part of the sealing member. When the portion of the sealing member 30 removed from the cartridge 10 extends to the cut-out slit 18, the additional cut off separates the cut-out portion 38 from the rest of the sealing member, The T-shaped distal end 62 of the vent channel 56 is exposed. By this exposure, air can flow through the channel 56 into the vent opening 54.

Claims (15)

In the ink cartridge,
A body configured to receive ink;
An air vent portion provided on the main body so as to be capable of inflow of air into the main body and outflow of air to the outside of the main body; And
A removable first portion that covers the air vent portion and that is attached to the body to cover a portion of the air vent portion and a heat staked non-removable first portion that is heat staked to cover the other portion of the air vent portion. And a sealing member having a second portion as far as possible,
Wherein the non-removable second portion of the sealing member is thermally fused to the body by a thermal welding element extending from a surface of the body
Ink cartridges. The method according to claim 1,
The body includes a polymer body,
Wherein the non-removable second portion of the sealing member is thermally fused to the polymer body by the thermal welding element melted into the sealing member
Ink cartridges. The method according to claim 1,
Wherein the air vent portion includes an air opening in the body and a serpentine vent channel extending from the air opening,
Wherein the removable first portion of the sealing member covers a portion of the meandering vent channel away from the air opening,
Wherein the non-removable second portion of the sealing member covers the air opening and a portion of the meandering vent channel adjacent the air opening
Ink cartridges. The method according to claim 1,
Wherein the sealing member is a label of the ink cartridge,
Ink cartridges. The method according to claim 1,
Wherein the sealing member includes a multi-layer sealing member, and the heat-sealing element is melted into at least one layer other than the entire layer of the sealing member
Ink cartridges. The method according to claim 1,
Wherein the heat sealing element forms a gap between the body and the sealing member
Ink cartridges. The method according to claim 1,
The heat sealing element is positioned adjacent to the air vent portion to prevent air from flowing into the ink cartridge through the air vent portion or outflow of air to the outside of the cartridge after heat fusion.
Ink cartridges. The method according to claim 1,
The heat-sealing element is located on both sides of the vent channel of the air vent
Ink cartridges. The method according to claim 1,
Wherein the removable first portion of the sealing member is bonded to the body by at least a pressure-sensitive adhesive
Ink cartridges. The method according to claim 1,
The non-removable second portion of the sealing member is bonded to the body by a thermal adhesive
Ink cartridges. In the ink cartridge,
A polymeric body configured to receive ink and including an upper surface;
A vent opening formed in an upper surface of the main body and configured to allow air to flow into the main body and to allow air to flow out of the main body, a vent opening provided in the recess, and a vent channel extending outwardly from the recess, A labyrinth vent portion comprising; And
And a polymer sealing member covering the labyrinth vent portion,
Wherein the sealing member is thermally fused to the main body by a plurality of thermal welding elements that are bonded to the main body by an adhesive and are positioned adjacent to the labyrinth vent portion, To prevent the inflow of air into the inside or the outflow of air outside the ink cartridge
Ink cartridges. 12. The method of claim 11,
Wherein the sealing member is a label of the ink cartridge,
Ink cartridges. 12. The method of claim 11,
The heat-sealing element is arranged on both sides of the vent channel of the labyrinth vent portion
Ink cartridges. 12. The method of claim 11,
Wherein the sealing member includes a cut-out portion that can be cut out from the ink cartridge by a user to expose the labyrinth vent portion
Ink cartridges. A method of manufacturing an ink cartridge,
Forming a main body of the ink cartridge, the main body including an upper surface, the upper surface including an air vent portion configured to allow air to flow into the main body and to allow air to flow out of the main body, And a heat fusing element extending outwardly from the top surface adjacent the portion;
Attaching a polymer sealing member covering the air vent portion to an upper surface of the body by an adhesive;
Applying heat to a first portion of the sealing member lying on a first group of the thermal welding elements to thermally fuse the sealing member to the upper surface of the first portion and to heat the second member And the second portion of the sealing member is not heated so as not to heat seal the sealing member to the upper surface of the second portion so that air is removed from the body during the thermal fusion of the second group of the heat- Forming an air gap between the upper surface and the sealing member from which they can exit; And
Subsequently, the sealing member is hermetically sealed to the main body by applying heat to the second portion of the sealing member to thermally fuse the sealing member to the upper surface in the second portion
A method of manufacturing an ink cartridge.

Images