A dispensing device for a multi-component composition comprises a plurality of collapsible bag compartments (109, 110) located within a housing (101). The compartments extend adjacent each other and have cross-sectional areas that are proportional to an intended volume mixing ratio for the multi-com
A dispensing device for a multi-component composition comprises a plurality of collapsible bag compartments (109, 110) located within a housing (101). The compartments extend adjacent each other and have cross-sectional areas that are proportional to an intended volume mixing ratio for the multi-component composition. Each compartment has an opening (123) that communicates with a device outlet at one end of the housing, and an opposite, sealed end that is exposed to pressure from a compression device (103). The compression device acts to collapse the compartments and dispenses the components through the device outlet. The components have different viscosities. The chamber of a less viscous component has a flow control regulator (111) to compensate for extra pressure exerted on that compartment by an adjacent compartment containing a more viscous component. The flow control regulator restricts the flow of the less viscous component, thereby achieving a volume mixing ratio that is closer to the intended volume mixing ratio.
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1. A dispensing device for an inter-reactive, multi-component composition comprising a plurality of collapsible bag compartments located within a substantially rigid housing, the housing being in the form of an elongate sleeve that acts as a guide tube for a compression device, wherein the compressi
1. A dispensing device for an inter-reactive, multi-component composition comprising a plurality of collapsible bag compartments located within a substantially rigid housing, the housing being in the form of an elongate sleeve that acts as a guide tube for a compression device, wherein the compression device is a piston, and the compartments each housing a component of the multi-component composition, the compartments extending longitudinally, adjacent each other, within the sleeve and having transverse cross-sectional areas that are generally proportional to an intended volume mixing ratio for the multi-component composition, each compartment further having an opening at a dispensing end thereof that is able to communicate with a device outlet at one end of the housing, and an opposite, sealed end which is located within the guide tube and exposed to pressure from the compression device that in use acts to collapse the compartments simultaneously and dispense the components through the device outlet,wherein the dispensing device further comprises a manifold section downstream of the compartments, the manifold section providing a separate chamber for each component to flow through towards the device outlet and each chamber being provided with an aperture that the dispensing end of a compartment protrudes through for dispensing its component into the chamber,wherein the components have different viscosities at an operating pressure of the compression device, andwherein the chamber of a component that is less viscous at the operating pressure has been modified with a flow control regulator to compensate for extra lateral pressure exerted on the compartment of the less viscous component by an adjacent compartment containing a component that is more viscous at that operating pressure, the flow control regulator presenting a dynamic restriction to the flow of the less viscous component that acts to modify the ratio of the components dispensed at the device outlet to achieve a volume mixing ratio that is closer to the intended volume mixing ratio of the multi-component composition,wherein the aperture, through which the dispensing end of the collapsible bag compartment of the less viscous component protrudes, is the dynamic flow control regulator, the aperture being smaller than an opening the size of which is determined by the proportions of the intended volume mixing ratio, so that the aperture acts as a throttle to restrict the flow, thereby compensating the extra lateral forces exerted on its compartment by an adjacent compartment of a more viscous component,wherein the dynamic flow control regulator comprises a variable aperture that increases in size as more pressure is applied by the compression device and reduces in size when the pressure is removed to provide a dynamic restriction, andwherein the rates of flow for the components are substantially balanced so that the compartments are collapsed at equal rates, and dimensional stability of the compartments is maintained during use. 2. A device as claimed in claim 1, wherein the aperture, through which the dispensing end of the collapsible bag compartment of the less viscous component protrudes, is a flow control regulator, the aperture being smaller than an opening size determined by the proportions of the intended volume mixing ratio, so that the aperture acts as a throttle to restrict the flow, thereby compensating for the extra lateral forces exerted on its compartment by an adjacent compartment of a more viscous component. 3. A device as claimed in claim 2, wherein the flow control regulator comprises a variable aperture that increases in size as more pressure is applied by the compression device and reduces in size when the pressure is removed to provide a dynamic restriction. 4. A device as claimed in claim 1, wherein the apertures into the manifold are each in the form of a biased opening. 5. A device as claimed in claim 4, wherein the biased opening is a resilient orifice having an aperture portion comprising a ring of resilient elements and a body portion comprising a ring of material that a base of the resilient elements extend from. 6. A device as claimed in claim 1, wherein the flow control regulator also acts as a valve. 7. A device as claimed in claim 1, wherein the flow control regulator dispensing device comprises a static flow restricting member that has been inserted into the chamber of the less viscous component downstream of the aperture into the manifold section. 8. A device as claimed in claim 7, wherein the static flow restricting member comprises a part ring shaped element. 9. A device as claimed in claim 1, wherein the flow restricting member is sized to provide a restriction that compensates for volumetric differences in the intended volume mixing ratio. 10. A device as claimed in claim 1, wherein the collapsible bag compartments are provided by a plurality of capsules housed within the elongate sleeve, the compartments arranged side by side as separate capsules. 11. A method of assembling a dispensing device as claimed in claim 1, wherein the manifold section is made to a standard design and the flow of a less viscous component through its chamber is adjusted through the addition of a flow control regulator to the manifold section to achieve a better volume mixing ratio at the device outlet. 12. A method as claimed in claim 11, wherein the flow control regulator is selected from the group of an aperture member provided at the entry of the chamber, a flow restricting member provided in the chamber between the aperture and the device outlet, or a plate or cover extending across the chamber that comprises a restrictive opening. 13. A device as claimed in claim 1, wherein the apertures into the manifold are each in the form of a biased opening. 14. A device as claimed in claim 13, wherein the biased opening is a resilient orifice having an aperture portion comprising a ring of resilient elements and a body portion comprising a ring of material that a base of the resilient elements extend from.
Konuma Ritaro (Shiki JPX) Tanaka Yoji (Kawasaki JPX), Container, method of manufacturing the same, and installation jig for cartridge container for discharge gun.
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