A dispenser actuator assembly (100) for actuating a dispenser (10) is disclosed. The dispenser (10) is in the form of a glass ampoule assembly (10) having a rupturable glass ampoule (12) containing a flowable material (M). The glass ampoule (12) is contained within an outer container (14) wherein the outer container (14) has a distal end segment defining a first open end (22) and a second closed end (24). The dispenser actuator assembly (100) has a base member (102) having an opening (110) configured to mount to the outer container (14). The base member (102) has an outlet aperture (280) configured to be in fluid communication with the outer container (14). The base member (102) has an applicator (250) integrally formed thereon and extending from the base member (102). The applicator is in fluid communication with the outlet aperture (280). The dispenser actuator assembly (100) also has an actuator assembly (104) operably connected to the base member (102) wherein the actuator assembly (104) has a first actuator arm (132a) and a second actuator arm (132b) each pivotally connected to the base member (102). The first actuator arm (132a) and the second actuator arm (132b) extend from the base member (102) in generally opposed relation defining a first position, or neutral position. The first actuator arm (132a) has a first protrusion (150a) depending therefrom and the second actuator arm (132b) has a second protrusion (150b) depending therefrom. The first actuator arm (132a) and the second actuator arm (132b) are pivotable from the first position towards one another to a second position, or actuating position, that is configured such that the first protrusion (150a) engages the outer container (14) and the second protrusion (150b) engages the outer container (14) to crush the glass ampoule (12) wherein the flowable material (M) is configured to be dispensed from the glass ampoule assembly (10) and through the applicator.

A dispenser (10) for dispensing a flowable material M has a container (12) having an outer wall (20) and membrane (14) collectively defining a first chamber (22) configured to contain the flowable material M. The membrane (14) has a thickness and a weld seam (40) wherein the weld seam (40) has a thickness less than the thickness of the membrane (14). A fracturing mechanism (16) is operably connected to the container (12). The fracturing mechanism (16) has an extending member (64) projecting from the outer wall (20) of the container (12). The extending member (64) has a projection (66) positioned proximate the membrane (14), wherein in response to deflection of the extending member (64), the projection (66) deflects the outer wall (20) proximate the membrane (14) wherein the weld seam (40) fractures creating an opening (41) through the membrane (14) configured to allow the flowable material M to pass therethrough and from the dispenser (10).

A dispenser (10) for dispensing a flowable material M has a container (12) having an outer wall (20) and membrane (14) collectively defining a first chamber (22) configured to contain the flowable material M. The membrane (14) has a thickness and a weld seam (40) wherein the weld seam (40) has a thickness less than the thickness of the membrane (14). A fracturing mechanism (16) is operably connected to the container (12). The fracturing mechanism (16) has a first extending member (64a) and a second extending member (64b). The first extending member (64a) and the second extending member (64b) are positioned on the container (12) in spaced relation, wherein the first extending member (64a) and the second extending member (64b) extend above the longitudinal axis. In response to deflection of the extending members (64a,64b) towards one another, the outer wall (20) deflects proximate the membrane (14) wherein the weld seam fractures creating an opening (41) through the membrane (14) configured to allow the flowable material M to pass therethrough and from the dispenser (10).

A dispenser (10) for dispensing a flowable material M has a container (12) having an outer wall (20) and membrane (14) collectively defining a first chamber (22) configured to contain the flowable material M. The membrane (14) has a thickness and a weld seam (40) wherein the weld seam (40) has a thickness less than the thickness of the membrane (14). A fracturing mechanism (16) is operably connected to the container (12). The fracturing mechanism (16) has an extending member (64) projecting from the outer wall (20) of the container (12). The extending member (64) has a projection (66) positioned proximate the membrane (14), wherein in response to deflection of the extending member (64), the projection (66) deflects the outer wall (20) proximate the membrane (14) wherein the weld seam (40) fractures creating an opening (41) through the membrane (14) configured to allow the flowable material M to pass therethrough and from the dispenser (10).

A dispenser (10) for dispensing flowable materials has a container (12) having an outer wall (20), a dividing wall (21) and a membrane (14) operably connected to define a first chamber (22), a second chamber (24) and a third chamber (16). The dividing wall (21) is connected to the membrane (14) at an interface (30). The first chamber (22) defines a first volume and is configured to contain a first flowable material (M1), and the second chamber (24) defines a second volume and is configured to contain a second flowable material (M2). The membrane (14) has a first section (34) having a first rupturable member (40) and a second section (36) having a second rupturable member (40). The first section (34) is separated from the second section (36) by the interface (30). The third chamber (16) is positioned adjacent the membrane (14) generally opposite the first chamber (22) and the second chamber (24), wherein the third chamber (16) defines a third volume and is configured to receive the first flowable material (M1) and the second flowable material (M2) upon rupture of the first rupturable member (40) and the second rupturable member (40) wherein a mixture (MX) is formed. The first volume and the second volume are collectively approximately equal to the third volume.

A dispenser (10) for dispensing flowable materials has a container (12) having an outer wall (20), a dividing wall (21) and a membrane (14) operably connected to define a first chamber (22), a second chamber (24) and a third chamber (16). The dividing wall (21) is connected to the membrane (14) at an interface (30). The first chamber (22) defines a first volume and is configured to contain a first flowable material (M1), and the second chamber (24) defines a second volume and is configured to contain a second flowable material (M2). The membrane (14) has a first section (34) having a first rupturable member (40) and a second section (36) having a second rupturable member (40). The first section (34) is separated from the second section (36) by the interface (30). The third chamber (16) is positioned adjacent the membrane (14) generally opposite the first chamber (22) and the second chamber (24), wherein the third chamber (16) defines a third volume and is configured to receive the first flowable material (M1) and the second flowable material (M2) upon rupture of the first rupturable member (40) and the second rupturable member (40) wherein a mixture (MX) is formed. The first volume and the second volume are collectively approximately equal to the third volume.

A dispenser (10) for dispensing a flowable material M has a container (12) having an outer wall (20) and membrane (14) collectively defining a first chamber (22) configured to contain the flowable material M. The membrane (14) has a thickness and a weld seam (40) wherein the weld seam (40) has a thickness less than the thickness of the membrane (14). A fracturing mechanism (16) is operably connected to the container (12). The fracturing mechanism (16) has an extending member (64) projecting from the outer wall (20) of the container (12). The extending member (64) has a projection (66) positioned proximate the membrane (14), wherein in response to deflection of the extending member (64), the projection (66) deflects the outer wall (20) proximate the membrane (14) wherein the weld seam (40) fractures creating an opening (41) through the membrane (14) configured to allow the flowable material M to pass therethrough and from the dispenser (10).

A permeation system for permeating a wetting agent into fabric includes a fabric supply part; a permeation part provided with a permeation device and a height adjustment device; a drying part; and a collecting part for winding the fabric, which has passed through the drying part, around a collecting roll, thereby obtaining functional fabric of uniform quality and increasing productivity of the fabric into which the wetting agent is permeated. A method for manufacturing fabric includes adjusting the height of the permeation paddle contacting the fabric; supplying the fabric; supplying a wetting agent to be permeated into the fabric; rotating the permeation roller and the permeation paddle to permeate the wetting agent into the fabric; drying the fabric into which the wetting agent is permeated; and collecting the fabric.

A permeation system for permeating a wetting agent into fabric includes a fabric supply part; a permeation part provided with a permeation device and a height adjustment device; a drying part; and a collecting part for winding the fabric, which has passed through the drying part, around a collecting roll, thereby obtaining functional fabric of uniform quality and increasing productivity of the fabric into which the wetting agent is permeated. A method for manufacturing fabric includes adjusting the height of the permeation paddle contacting the fabric; supplying the fabric; supplying a wetting agent to be permeated into the fabric; rotating the permeation roller and the permeation paddle to permeate the wetting agent into the fabric; drying the fabric into which the wetting agent is permeated; and collecting the fabric.

The present invention is directed to construction tools. The present invention includes tools used for applying mastic or mud to a work surface, for example, a flat box mastic applicator tool, blade assembly, and/or blade adjustment system, that have many improvements too numerous to mention all in the Abstract. The flat box mastic applicator may include unique walls. The blade assembly may have a non-uniform cross section, e.g., a blade holder with thinner areas and/or material removed at various locations along its lateral length. The blade holder may have a larger size outer end(s) to withstand bending or braking. The blade holder may have and arched shape, ribs or bumps for holding a blade more firmly, and a ridge or bump at its outer edge to act as a dam. The blade adjustment system may include symmetrical pins or posts and a tapered leaf spring. See further improvements herein.