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A process for producing physically foamed injection molded articles is provided. The process involves feeding a propellant-free thermoplastic melt into a cavity followed by delivering a physical propellant directly into the cavity or directly into the melt flowing into the cavity. The pressure exert

A process for producing physically foamed injection molded articles is provided. The process involves feeding a propellant-free thermoplastic melt into a cavity followed by delivering a physical propellant directly into the cavity or directly into the melt flowing into the cavity. The pressure exerted on the propellant during the injection stage is greater than that exerted on the propellant during the holding phase.

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The invention claimed is: 1. A process for the production of physically foamed injection molded articles, wherein in a first stage a propellant-free first melt portion is fed into a cavity (initial filling), in a second stage adding a quantity of a physical propellant at elevated pressure to a seco

The invention claimed is: 1. A process for the production of physically foamed injection molded articles, wherein in a first stage a propellant-free first melt portion is fed into a cavity (initial filling), in a second stage adding a quantity of a physical propellant at elevated pressure to a second melt portion (propellant injection phase) and injecting the second melt portion containing the quantity of propellant into the cavity and optionally in a third stage a propellant-free third melt portion is charged into the cavity, the production of the injection molded articles occurring in the cavity; wherein metering of the quantity of the physical propellant in the second stage occurs in a pressure regulated manner, wherein the pressure which is exerted on the propellant during the propellant injection phase is greater than the pressure which is exerted on the propellant in the phases between or before or after metered addition, and the expansion of the quantity of the propellant added to the melt occurs in the cavity including maintaining the propellant under pressure an intermediate cycle time before and after the propellant injection phase; maintaining the propellant at a pressure of at least p (crit) at a given temperature during the intermediate cycle time. 2. A process for the production of physically foamed injection molded articles, wherein in a first stage a propellant-free first melt portion is fed into a cavity (initial filling), in a second stage adding a quantity of a physical propellant at elevated pressure to a second melt portion (propellant injection phase) and injecting the second melt portion containing the quantity of propellant into the cavity and optionally in a third stage a propellant-free third melt portion is charged into the cavity, the production of the injection molded articles occurring in the cavity; wherein metering of the quantity of the physical propellant in the second stage occurs in a pressure regulated manner, wherein the pressure which is exerted on the propellant during the propellant injection phase is greater than the pressure which is exerted on the propellant in the phases between or before or after metered addition, and the expansion of the quantity of the propellant added to the melt occurs in the cavity of using a gas or gas mixture as the propellant; wherein the gas or gas mixture is held in an intermediate cycle time at a pressure of at least 60 bar. 3. A process for the production of physically foamed injection molded articles, wherein in a first stage a propellant-free first melt portion is fed into a cavity (initial filling), in a second stage adding a quantity of a physical propellant at elevated pressure to a second melt portion (propellant injection phase) and injecting the second melt portion containing the quantity of propellant into the cavity and optionally in a third stage a propellant-free third melt portion is charged into the cavity, the production of the injection molded articles occurring in the cavity; wherein metering of the quantity of the physical propellant in the second stage occurs in a pressure regulated manner, wherein the pressure which is exerted on the propellant during the propellant injection phase is greater than the pressure which is exerted on the propellant in the phases between or before or after metered addition, and the expansion of the quantity of the propellant added to the melt occurs in the cavity further comprising the step of elevating the pressure of the propellant during the propellant injection phase to a pressure of over 60 bar using a pressure control valve. 4. A process for the production of physically foamed, injection molded articles in a mold cavity, comprising the steps of: in a first stage is an initial filling step, feeding a propellant-free first melt portion into the mold cavity; in a second stage, in a propellant injection phase, concurrently injecting into the mold cavity a physical propellant maintained at an elevated pressure and a second melt portion; metering the physical propellant in the second stage in a pressure regulated manner; wherein the pressure which is directly exerted on the propellant alone during the propellant injection phase is greater than the pressure exerted on the propellant in the phases before and after said metering. 5. The process of claim 4, further comprising the step of controlling the pressure exerted on the propellant via a pressure control valve. 6. The process of claim 5, wherein the pressure control valve is a multi-way valve. 7. The process of claim 6, wherein the multi-way valve is a 3/3-way proportional valve or a 2/3-way proportional valve. 8. The process of claim 4 further comprising the step of controlling the pressure of a critical propellant via at least one pressure relief valve connected downstream of a pressure control valve. 9. The process of claim 8, wherein at least one of the pressure relief valves has a holding pressure equal to or higher than the pressure at which a critical propellant is held in an intermediate cycle time. 10. The process of claim 4, wherein the propellant is a compressible fluid. 11. The process of claim 4 further comprising the step of maintaining the propellant under pressure in an intermediate cycle time before and after the propellant injection phase. 12. The process of claim 4 further comprising the step of using water as the propellant. 13. The process of claim 4 further comprising the step of using a gas or gas mixture as the propellant. 14. The process of claim 13, further comprising the step of using carbon dioxide as the propellant. 15. The process of claim 4 further comprising the step of generating a counterpressure in the cavity. 16. The process of claim 4, wherein the physically foamed injection molded article is selected from the group consisting of a handle, a knob, a gearshift knob, a steering wheel casing, a ball, a sphere, a fender, a float and a closing means for bottle-like containers. 17. The process of claim 4, wherein the step of concurrently injecting includes injecting at an injection point. 18. The process of claim 17, wherein said injection point is upstream of said mold cavity. 19. The process of claim 17, wherein said injection point is at said mold cavity. 20. The process of claim 17, including providing a controlled closure mechanism at the injection point, the controlled closure mechanism opening upon an increase in pressure exerted on the propellant upstream of the controlled closure mechanism above its holding pressure. 21. The process of claim 17, wherein the injection point is configured as a throttle means. 22. The process of claim 21, wherein the injection point is in the form of a defined gap in an injector or of an injector with a sinter metal. 23. The process of claim 21, wherein the injection point is configured as a controlled closure mechanism. 24. The process of claim 4 further comprising the step of elevating the pressure of the propellant during the propellant injection phase to a pressure of over 60 bar using an upstream pressure control valve. 25. The process of claim 4 further including in a third stage, a propellant free third melt portion charged into the cavity. 26. A device for the discontinuous metered addition of physical propellants to a foamable melt, comprising: a storage means, in which the propellant is stored under pressure, a pressure control valve for regulating the propellant pressure, and an injection point, which is configured as a throttle means, at which the propellant under pressure is fed to the melt, wherein a controlled closure mechanism is provided at the injection point, and the controlled closure mechanism opens upon an increase in pressure exerted on the propellant upstream of the controlled closure mechanism above its holding pressure wherein the injection point for the propellant is upstream to the spray point x within the mold and the part of the feeder pipe between the injection point and the spray point x is designed such that premature expansion in volume of the propellant under pressure is avoided. 27. The device of claim 26, further comprising at least one pressure relief valve. 28. A device for the discontinuous of physical propellants to a foamable melt, comprising: a storage means, in which the propellant is stored under pressure, a pressure control valve for regulating the propellant pressure, and an injection point, which is configured as a throttle means, at which the propellant under pressure is fed to the melt, wherein at least one pressure relief valve is provided before the injection point, and the pressure relief valve opens upon a pressure increase exerted on the propellant upstream of the pressure relief valve above its holding pressure wherein the injection point for the propellant is upstream to the spray point x within the mold and the part of the feeder pipe between the injection point and the spray point x is designed such that premature expansion in volume of the propellant under pressure is avoided.