The invention relates to a material collection container of a suction excavator, having a suction connection at its rear end-face wall and a suction flow duct that leads from the suction connection through a collection chamber and a filter unit. The suction connection is positioned at the rear end-face wall in such a way that its cross section is intersected by the plane of symmetry of the material collection container. After passing through the collection chamber, the suction flow is divided into at least two subflows that are conducted in air ducts situated on both sides of the plane of symmetry.

The invention further relates to a suction excavator having this type of material collection container.

A floor mat arranged in a working machine includes a floor portion, a wall portion arranged on a circumferential portion of the floor portion, and an opening portion arranged on a part of a connecting portion of the wall portion, the connecting portion connecting to the floor portion. The floor mat includes a mat main body arranged on the floor portion, a covering portion configured to cover the opening portion, and an connecting portion configured to connect the covering portion flexibly to a circumferential portion of the mat main body.

A working machine includes a travel device, a motive power transmission device configured to transmit a motive power to the travel device, a transmission case configured to house the motive power transmission device, and a hydraulic operation fluid tank disposed on an upper surface of the transmission case.

A hydraulic module is provided for a materials-handling vehicle. The hydraulic module can include a mounting frame configured to mechanically connect to a frame of the vehicle but isolate the vehicle frame from vibrations occurring in the power pack. The mounting frame supports the primary components of a hydraulic energy recovery system, including, for instance, a hydraulic tank, a hydraulic pump, and an electric motor. The hydraulic energy recovery system components can be secured to the mounting frame before the mounting frame is connected to the vehicle frame. Standardized integration components such as cables, tubes, and wiring can be used to connect the module to the electrical and hydraulic systems of the vehicle. A fluid level sensor and indicator can be provided to indicate the fluid level of the hydraulic tank. Check valves can be mounted to adapter blocks to ensure low delta pressure during operation.

A hydraulic excavator as an electric work machine includes: an electric motor; a battery unit that stores electric power for driving the electric motor; a hydraulic oil tank that contains hydraulic oil, and a hydraulic pump that is driven by the electric motor and connected to the hydraulic oil tank. The electric motor, the hydraulic pump, and the hydraulic oil tank are arranged below the battery unit on a machine body frame, and are arranged side by side in a lateral direction of the machine body frame.

A revolving frame revolves around a center of revolution. A battery is supported by the revolving frame. An electric motor is supported by the revolving frame and supplied with electric power from the battery. A hydraulic pump is supported by the revolving frame, driven by the electric motor, and arranged closer to the center of revolution than the electric motor in a plan view.

An excavation work machine includes a hydraulic oil tank provided in a tank chamber and storing hydraulic oil that actuates a plurality of hydraulic actuators, a control valve controlling a flow of pressure oil supplied from the hydraulic oil tank to each of the hydraulic actuators, a plurality of hydraulic hoses extending from the control valve and communicatively connected to each of the hydraulic actuators, and a fuel tank that is provided in a front portion in the tank chamber covered with a hood provided to be openable and closable and stores fuel to be supplied to an engine. The plurality of hydraulic hoses are arranged along a rear surface portion of the hydraulic oil tank, and a fuel supply pump is provided in a space portion formed above a step portion in a front portion of the tank chamber.

A fuel tank (16) for storing fuels is located between a right side frame (8) and a center frame (6) of a revolving frame (5) and is disposed on the center frame (6) side. Also, a hydraulic oil tank (19) for storing hydraulic oil is disposed adjacent to the fuel tank (16) in the right-and-left direction on the side of the right side frame (8) closer to an outer side in the right-and-left direction than the fuel tank (16). In addition, a top surface portion (19E) of the hydraulic oil tank (19) is disposed at a position higher than that of a top surface portion (16E) of the fuel tank (16).

A ground processing machine includes a rear carriage with an internal combustion engine, respectively at least one drive wheel to both sides of the internal combustion engine, a driver cabin arranged offset relative to the internal combustion engine in the longitudinal direction of the machine, a fuel tank for fuel to be supplied to the internal combustion engine, an additive substance tank, and a hydraulic fluid tank. The additive substance tank is arranged following a drive wheel in the longitudinal machine direction, and next to the drive wheel in a transversal machine direction.

A shovel is provided that includes a lower running body, an upper turning body pivotally mounted on the lower running body, an engine mounted on the upper turning body, a motor generator driven by the engine, a power storage device for storing electric power generated by the motor generator, an electric motor for supplying regenerative electric power to the power storage device, a selective reduction catalyst system for purifying exhaust gas by injecting a reducing agent stored in a reducing agent storage tank into an exhaust pipe of the engine, an abnormality detection unit for detecting an abnormality of the selective reduction catalyst system, and a control device that performs abnormality determination on the selective reduction catalyst system based on a detection result of the abnormality detection unit. The control device continues to control the electric motor before and after the abnormality determination.