A system for treating pharmaceutical waste at a location at which the pharmaceutical waste is disposed includes a waste conduit having an inlet that is configured to receive the pharmaceutical waste, a diluent conduit fluidly coupled to the waste conduit and configured to discharge water into the waste conduit, a first reagent conduit fluidly coupled to the waste conduit and configured to dispense a first reagent into the waste conduit, and a second reagent conduit fluidly coupled to the waste conduit and configured to discharge a second reagent into the waste conduit. In some embodiments, the waste conduit further comprises an outlet disposed downstream from the second reagent conduit. The waste conduit may be free of waste-receiving vessels between the inlet and the outlet.

A method of maintaining a backpressure of a fluidic product is provided. The method includes pressurizing a first reservoir to a first predetermined pressure level using compressed air, delivering the fluidic product to the pressurized first reservoir until a current level of the fluidic product in the first reservoir reaches a first predetermined level, pressurizing a second reservoir to a second predetermined pressure level using the compressed air, delivering the fluidic product to the pressurized second reservoir until a current level of the fluidic product in the second reservoir reaches a second predetermined level, and controlling the backpressure of the fluidic product using the first reservoir and the second reservoir such that a discharge flow of the fluidic product is continuous.

Methods are provided for accurately blending biodiesel into distillate streams to achieve a pre-determined percentage of biodiesel in the distillate, applicable to wild-type distillate streams as well as distillate streams that already contain some percentage of biodiesel.

Systems and methods are described for dissolving ammonia gas in deionized water. The system includes a deionized water source and a gas mixing device including a first inlet for receiving ammonia gas, a second inlet for receiving a transfer gas, and a mixed gas outlet for outputting a gas mixture comprising the ammonia gas and the transfer gas. The system includes a contactor that receives the deionized water and the gas mixture and generates deionized water having ammonia gas dissolved therein. The system includes a sensor in fluid communication with at least one inlet of the contactor for measuring a flow rate of the deionized water, and a controller in communication with the sensor. The controller sets a flow rate of the ammonia gas based on the flow rate of the deionized water measured by the sensor, and a predetermined conductivity set point.

The present disclosure provides a system and method for odorizing natural gas flowing through a distribution pipeline. The system includes a bypass line adjacent to a distribution pipeline, wherein bypass gas flows through the bypass line and an odorant tank connected to the bypass line, and into the distribution pipeline; a high-flow control valve and a low-flow control valve in the bypass line, wherein bypass gas flows through the odorant tank into the distribution pipeline when the high-flow control valve or the low-flow control valve is open; and a programmable logic controller connected to the high-flow and low flow control valve; wherein the programmable logic controller opens the high-flow or low-flow control valve for a predetermined dwell time proportional to an amount of bypass gas needed to odorize gas in the distribution pipeline each time that a preselected quantity of gas flows through the distribution pipeline.

A fuel dispensing system includes that receives fuel from a fuel storage tank, and a blending system in fluid communication with the fuel dispensing unit. The blending system including a fuel conveyance device that receives the fuel from the fuel dispensing unit, and an additive conveyance device that pumps a fuel additive to be blended with the fuel based on a volumetric flow rate of the fuel, whereby the blending system provides a product mixture having a known fuel-to-fuel additive ratio. A hose and a nozzle are fluid communication with the blending system to dispense the product mixture.

A gas control system of a non-road gas engine and a gas control method thereof are disclosed by the present disclosure. The gas control system includes a mixer, the mixer is provided with an air inlet, a gas inlet and a mixed gas outlet respectively, the air inlet is provided with a first pressure sensor, the gas inlet is provided with a second pressure sensor and a pressure regulating valve that are spaced apart, and the mixed gas outlet is provided with a third pressure sensor; the first pressure sensor, the second pressure sensor, the pressure regulating valve and the third pressure sensor are respectively electrically connected to a controller, and the controller controls an opening degree of the pressure regulating valve according to pressure information fed back by the first pressure sensor, the second pressure sensor and the third pressure sensor so as to adjust an air-gas ratio of the mixed gas. The system has a simple structure. By disposing a pressure regulating valve at the gas inlet, the pressure of the gas entering the mixer is controlled, and the air-gas ratios required under various working conditions are controlled, which realizes a closed-loop control so that a control range of the air-gas ratio is smaller, the accuracy is higher, and a transient response speed of the engine is improved.

Systems and methods are described for dissolving ammonia gas in deionized water. The system includes a deionized water source and a gas mixing device including a first inlet for receiving ammonia gas, a second inlet for receiving a transfer gas, and a mixed gas outlet for outputting a gas mixture comprising the ammonia gas and the transfer gas. The system includes a contactor that receives the deionized water and the gas mixture and generates deionized water having ammonia gas dissolved therein. The system includes a sensor in fluid communication with at least one inlet of the contactor for measuring a flow rate of the deionized water, and a controller in communication with the sensor. The controller sets a flow rate of the ammonia gas based on the flow rate of the deionized water measured by the sensor, and a predetermined conductivity set point.

An automated nutrient injection system is provided. The automated nutrient injection system comprises a nutrient mixing and delivery system coupled to a controller. The nutrient mixing and delivery system is configured to mix a predefined formula comprised of at least one nutrient and water. The controller is configured to receive, store, and execute user-defined settings of the nutrient mixing and delivery system. The controller comprises a remote display, wherein the remote display is viewable on a device physically remote from the nutrient mixing and delivery system.

An additive management system is disclosed. The system includes an additive selection system, which selects an additive for dispensing into a working fluid. The system also includes an additive dispensing system having a fluid sensing chamber with sensors. The system also includes an additive delivery system, which delivers the selected additive to the additive dispensing system, and a processor which causes the fluid sensing chamber to receive a sample of the working fluid, receives measurement signals from the one or more fluid parameter sensors corresponding with the values of fluid parameters of the working fluid, and determines values for fluid parameters of the working fluid based on the measurement signals. The processor also causes the additive delivery system to deliver the selected additive to the additive dispensing system and causes the additive dispensing system to dispense the selected additive into the working fluid through the fluid sensing chamber.