Abstract: The invention is an improved tool for pulling a valve seat from a valve in a fluid end. The invention replaces the standard threaded nut and stem commonly used in such tools with a split nut comprising a plurality of removeably engageable split nut segments placed within a base and a stem configured to be used with the plurality of removeably engageable split nut segments. In the preferred embodiment, each split nut segment possesses a center-facing surface relative to the longitudinal axis of the invention comprising a set of horizontal v-grooves suitable to be disposed against complementary v-grooves of the stem. The base permits the plurality of split nut segments to be placed in an engaged position permitting the v-grooves of the split nut segments to removeably engage the v-grooves of the stem securely or to be placed in a disengaged position.

Abstract: The invention is an improved tool for pulling a valve seat from a valve in a fluid end. The invention replaces the standard threaded nut and stem commonly used in such tools with a split nut comprising a plurality of removeably engageable split nut segments placed within a base and a stem configured to be used with the plurality of removeably engageable split nut segments. In the preferred embodiment, each split nut segment possesses a center-facing surface relative to the longitudinal axis of the invention comprising a set of horizontal v-grooves suitable to be disposed against complementary v-grooves of the stem. The base permits the plurality of split nut segments to be placed in an engaged position permitting the v-grooves of the split nut segments to removeably engage the v-grooves of the stem securely or to be placed in a disengaged position.

Abstract: An ion focusing and conveying device 10 comprises a plurality of electrodes 12 in series. Means is provided to apply a first alternating voltage waveform to each electrode 12, the phase of the alternating voltage in the first waveform is applied to each electrode 12 in the series being ahead of the phase of the first alternating voltage waveform applied to the preceding electrode 12 in the series by less than 180°, preferably by 90° or less, such that ions are focused onto an axis of travel and impelled along the series of electrodes 12.

Abstract: A viscoelastic liquid flow splitter includes a flow splitter body having a first bore including a first bore outlet and a first bore inlet, and a second bore including a second bore outlet and a second bore inlet The bore inlets are substantially parallel to each other and the bore outlets diverge from each other at an angle. The flow splitter also includes a compression fitting having a first and a second tubular portion fluidically coupled to the first and second bore inlets where the tubular portions are configured to fluidically couple to a double barreled viscoelastic liquid dispensing syringe.

Abstract: Mass spectrometry apparatus 105 comprises a serial arrangement of an ion source 110, first time of flight means, a field free region 120, means to fragment the molecules, a second time of flight means and a large area detector 160. The second time of flight means includes an ion mirror 150, the ion mirror 150 being arranged to produce a reflecting substantially quadratic field. The first time of flight means is arranged to provide spatial focusing concomitant with time focusing of ions at or near the entrance to the ion mirror 150. The means provided to fragment the ions front the first time of flight means can be a collision cell 140 or in the field free region 220 or in the first time of flight means. The means to fragment the molecules has a potential which is different from the potential at the entrance to the ion mirror 150, and the detecting surface of the detector 160 is mounted in the time focal surface of the ion mirror 150.

Abstract: A replaceable auger assembly includes a body having at least one material inlet defined therein and an auger disposed within the body. The auger includes a helical portion disposed about a shaft portion and a positive shutoff mechanism. The positive shutoff mechanism is configured to selectively close the material inlet.

Abstract: The present invention provides a transpiration cooled rocket motor which operates at low combustion pressures, inherently provides stabilized combustion, and operates over a desired range of L-star. In a preferred embodiment the inventive transpiration cooled rocket motor includes: a housing; a porous injector sleeve; a propellant injector; and a nozzle. Preferably the injector sleeve lines the inside walls of the housing such that the inside volume of the sleeve forms the chamber for the motor. Liquid fuel passes inwardly through the pores of the injector sleeve and is injected from the sleeve into the chamber, thus cooling the walls of the rocket motor.

Abstract: An ion focussing and conveying device 10 comprises a plurality of electrodes 12 in series. Means is provided to apply a first alternating voltage waveform to each electrode 12, the phase of the alternating voltage in the first waveform is applied to each electrode 12 in the series being ahead of the phase of the first alternating voltage waveform applied to the preceding electrode 12 in the series by less than 180°, preferably by 90° or less, such that ions are focussed onto an axis of travel and impelled along the series of electrodes 12.

Abstract: Mass spectrometry apparatus 105 comprises a serial arrangement of an ion source 110, first time of flight means, a field free region 120, means to fragment the molecules, a second time of flight means and a large area detector 160 The second time of flight means includes an ion mirror 150, the ion mirror 150 being arranged to produce a reflecting substantially quadratic field. The first time of flight means is arranged to provide spatial focusing concomitant with time focusing of ions at or near the entrance to the ion mirror 150. The means provided to fragment the ions from the first time of flight means can be a collision cell 140 or in the field free region 220 or in the first time of flight means. The means to fragment the molecules has a potential which is different from the potential at the entrance to the ion mirror 150, and the detecting surface of the detector 160 is mounted in the time focal surface of the ion mirror 150.

Abstract: An ion focussing and conveying device 10 comprises a plurality of electrodes 12 in series. Means is provided to apply a first alternating voltage waveform to each electrode 12, the phase of the alternating voltage in the first waveform is applied to each electrode 12 in the series being ahead of the phase of the first alternating voltage waveform applied to the preceding electrode 12 in the series by less than 180°, preferably by 90° or less, such that ions are focussed onto an axis of travel and impelled along the series of electrodes 12.

Abstract: Mass spectromctry apparatus 105 comprises a serial arrangement of an ion source 110, first time of flight means, a field frce region 120, means to fragment the molecules, a second time of flight means and a large area detector 160 The second time of flight means includes an ion mirror 150, the ion mirror 150 being arranged to produce a reflecting substantially quadratic field. The first time of flight means is arranged to provide spatial focusing concomitant with time focusing of ions at or near the entrance to the ion mirror 150. The means provided to fragment the ions from the first time of flight means can be a collision cell 140 or in the field free region 220 or in the first time of flight means. The means to fragment the molecules has a potential which is different from the potential at the entrance to the ion mirror 150, and the detecting surface of the detector 160 is mounted in the time focal surface of the ion mirror 150.

Abstract: A method and apparatus for comminuting minerals and similar materials by vacuum comminution includes an arrangement for introducing the material to the low pressure chamber at a high velocity whereby the rate of change of pressure on the particles of material is greatly increased. The degree of comminution is thereby increased and the effectiveness of the system greatly enhanced.

Abstract: A method for separating the isotopes of an element comprises the passing over a mass of highly magnetizable particles of fluid (either a gaseous mixture or a solution) containing an element or its compounds or ions each containing a single atom of the element to be isotopically separated. A strong magnetic field is utilized to magnetize the mass of particles and while the particles are magnetized the isotope having the higher magnetic moment is concentrated within the mass in the high magnetic field gradient zones at the points of contact between the particles. The less magnetic isotope flows through the matrix and the fluid emerging from the mass is collected in a suitable container. The magnetic field is removed intermittently and the fluid then flowing through the demagnetized mass is directed into a different container which thus collects the isotope having the higher magnetic moment and which is free to flow out with the fluid upon demagnetization of the mass.

Abstract: A method for magnetic separation of materials wherein the materials are ground to provide a mixture of fine particles of more- and less-magnetic materials which may include paramagnetic material and diamagnetic material. Discrete bodies of highly magnetizable material are introduced to a magnetic field of high intensity and thereby become a closely consolidated mass of bodies having interstitial pores extended through the mass in all directions. The mixed particles are caused to flow through the pores and the less-magnetic particles are separated from the more-magnetic particles and the mass of bodies in the magnetic field. The more-magnetic particles are separated from the bodies by moving the mass of bodies out of the magnetic field and by demagnetizing them so that they tumble freely and by washing or otherwise removing the particles from the bodies as they tumble after leaving the closely consolidated mass.