A fastener sealing tool that utilizes curable material to seal the area around a fastener connected to a surface. In one embodiment of the invention the fastener sealing tool is a manually operated tool, hand operated by a user who visually identifies the fastener to be sealed and then operates the fastener sealing tool to seal the desired fastener. In a second embodiment of the invention the fastener sealing tool is an end of arm tool for a robot that automatically identifies or is programmed to move to the location of the fastener, and then seal the fastener using the fastener sealing tool. The fastener sealing tool utilizes a load cell to control the flow of material and to detect certain unwanted conditions.

An injection molding machine includes a cylinder; an injection member housed within the cylinder; and a molten resin supply device connected to the cylinder and configured to pump a molten resin from a position closer to a proximal end of the injection member than to a distal end of the injection member. In the cylinder, a pumping force applied to the molten resin by the molten resin supply device is used to move the molten resin in front of the injection member, and the molten resin is accumulated on a front side of an internal space of the cylinder. The molten resin is injected from the distal end of the cylinder by moving the injection member forward.

A feeder according to an embodiment includes: a weight-type feeder including a hopper to which a raw material is supplied, and a discharging port from which the raw material is discharged; and a volume-type feeder including a hopper to which the raw material discharged from the discharging port is supplied, and a discharging port from which the raw material is discharged. The volume-type feeder repeats the discharging of the raw material from the discharging port and the stopping of the discharging, and the weight-type feeder continuously discharges the raw material from the discharging port to the hopper during which the discharging of the raw material from the discharging port and the stopping of the discharging are performed.

A production plant includes an injection unit suitable for forming processes, and the injection unit includes a barrel and an injection actuator, a hydraulic system for moving the injection actuator, an safety device configured to output an access signal when access detecting a person accessing the production plant and/or a possibility of a person accessing the production plant, and an electronic control unit to operate the hydraulic system in a production mode and in a safety mode. The control unit is configured to switch from the production mode to the safety mode when the access safety device outputs the access signal, and is configured to operate the hydraulic system in the safety mode such that the hydraulic system at least partially, preferably completely, counteracts an axial movement of the injection actuator caused directly or indirectly by an action of a molding compound present in the barrel on the injection actuator.

A production plant includes an injection unit suitable for forming processes, and the injection unit includes a barrel and an injection actuator, a hydraulic system for moving the injection actuator, an safety device configured to output an access signal when access detecting a person accessing the production plant and/or a possibility of a person accessing the production plant, and an electronic control unit to operate the hydraulic system in a production mode and in a safety mode. The control unit is configured to switch from the production mode to the safety mode when the access safety device outputs the access signal, and is configured to operate the hydraulic system in the safety mode such that the hydraulic system at least partially, preferably completely, counteracts an axial movement of the injection actuator caused directly or indirectly by an action of a molding compound present in the barrel on the injection actuator.

A plasticizing device includes a plasticizing mechanism including a feeding port for receiving a material and configured to plasticize the material to generate a melted material and a material feeding mechanism configured to feed the material to the plasticizing mechanism. The material feeding mechanism includes a housing including a depositing port communicating with the feeding port, the housing storing the material, and a rotating member housed in the housing and capable of rotating along an inner edge of the housing. A plurality of through-holes are provided in the rotating member at intervals along an outer circumference of the rotating member. When the rotating member rotates and any one of the plurality of through-holes and the depositing port communicate, the material stored in the housing is fed from the feeding port to the plasticizing mechanism through the depositing port.

The resin molding device comprises: a lower mold on which a substrate is placed; an upper mold in which a cavity is formed by a side block and a cavity block provided so as to be capable of rising and descending vertically with respect to the side block; a clamp mechanism for clamping the lower mold and the upper mold; a transfer mechanism that supplies a resin material to the cavity by means of a plunger; and a controller that uses the relationship between the position of the plunger and a resin filling rate for the cavity calculated on the basis of the volume of a chip arranged on the substrate and the volume of the resin material when performing filling rate correspondence control for controlling operation relating to resin molding triggered as a result of the plunger arriving at a position corresponding to a predetermined resin filling rate.

An injection molding apparatus (10) comprising: one or more valves each comprised of a valve pin (1040, 1041, 1042) adapted to be driven upstream and downstream through a downstream channel (1006) that has a downstream channel portion (1006ds) that has a control surface (1008), the control surface (1008) forming a channel or restriction gap (CG, 1006rg), the valve pin (1041) being controllably drivable upstream and downstream through the channel or restriction gap (CG, 1006rg) at a single selected rate of upstream acceleration up to a selected reduced upstream velocity that is less than a maximum velocity at which the valve pin (1041) is drivable, the size or configuration of the channel or restriction gap (CG, 1006rg) and the single selected rate of upstream acceleration being selected in combination with each other to control flow of injection fluid (18) through the channel gap (CG, 1006rg).

The invention relates to a method for process monitoring during production of a finished part (112) in a primary shaping process. The method comprises the following steps: a) providing at least one mould (114) designed for the primary shaping process, wherein the mould (114) has at least one cavity (116) for receiving at least one starting material for the hot-crosslinking material, and wherein an apparatus for determining a mould internal pressure is also integrated into the mould (114); b) heating the mould (114); c) introducing the at least one starting material for the hot-crosslinking material into the cavity (116) under pressure such that the finished part (112) is produced; d) detecting a progression of the mould internal pressure occurring in step c); e) differentiating, at least once or at least twice, the progression of the mould internal pressure in order to determine at least one derivative selected from the group consisting of: the first-order derivative and the second-order derivative; and f) characterising a progression of a chemical crosslinking reaction by means of at least one derivative selected from the group consisting of: the first-order derivative and the second-order derivative.