The present disclosure is intended to prevent blockage of a path that allows a fluid to flow to a predetermined position where a pressure of the fluid is applied to a cell unit. An electrochemical compressor according to an embodiment includes first and second members, an elastic body, a fluid chamber, and a fluid path. The elastic body exerts an elastic force in a direction in which the first member and the second member are pushed apart from each other, and thereby presses a stack of electrochemical cells. The fluid chamber has the elastic body disposed therein and receives boosted gas flowing thereinto, the fluid chamber allowing the boosted gas to apply a pressure to push the first member and the second member apart from each other. The fluid path connects the fluid chamber to a flow path into which the boosted gas is discharged from the electrochemical cells.

The present disclosure is intended to prevent blockage of a path that allows a fluid to flow to a predetermined position where a pressure of the fluid is applied to a cell unit. An electrochemical compressor according to an embodiment includes first and second members, an elastic body, a fluid chamber, and a fluid path. The elastic body exerts an elastic force in a direction in which the first member and the second member are pushed apart from each other, and thereby presses a stack of electrochemical cells. The fluid chamber has the elastic body disposed therein and receives boosted gas flowing thereinto, the fluid chamber allowing the boosted gas to apply a pressure to push the first member and the second member apart from each other. The fluid path connects the fluid chamber to a flow path into which the boosted gas is discharged from the electrochemical cells.

A membraneless electrolysis cell, which includes a solid body, the solid body having a central cavity, two housings, at least one secondary cavity, at least one duct for providing a material, two ducts for admitting two electrolyte flows, and at least one supply duct. The cell configuration allows a material, in particular a reagent, to be fed selectively to the anode or cathode, separate from the electrolyte flow.

The present disclosure is intended to provide an electrochemical compressor capable of preventing a liquid, such as water, from accumulating inside a piston. An electrochemical compressor according to an embodiment includes a housing chamber and a drain path. The housing chamber houses an elastic body that presses an electrochemical cell with its elastic force, and is configured to receive part of a gas compressed by the electrochemical cell, the part of the gas flowing into the housing chamber. In the electrochemical cell, the gas is supplied to an anode side of a solid polymer electrolyte membrane as a partition wall, and is compressed by being moved by electricity to a cathode side opposite to the anode side. The drain path allows a liquid in the housing chamber to be drained out of the housing chamber.

The present disclosure is intended to provide an electrochemical compressor capable of preventing a liquid, such as water, from accumulating inside a piston. An electrochemical compressor according to an embodiment includes a housing chamber and a drain path. The housing chamber houses an elastic body that presses an electrochemical cell with its elastic force, and is configured to receive part of a gas compressed by the electrochemical cell, the part of the gas flowing into the housing chamber. In the electrochemical cell, the gas is supplied to an anode side of a solid polymer electrolyte membrane as a partition wall, and is compressed by being moved by electricity to a cathode side opposite to the anode side. The drain path allows a liquid in the housing chamber to be drained out of the housing chamber.

An electrolyzer that includes an anode configured for being connected to a first pole of a voltage source; a cathode configured for being connected to a second pole of the voltage source; a fluid inlet configured to allow a flow of fluid to enter the electrolyzer; and a fluid outlet configured to allow the flow to exit the electrolyzer, wherein the electrolyzer is configured to cause the flow to have a flow speed profile along a flow axis with a relatively higher flow speed at the flow axis between the anode and the cathode, wherein the flow speed becomes relatively lower at locations away from the flow axis and more proximate the anode and the cathode, and wherein the electrolyzer has an entrance length that causes the flow speed profile to be at least a partially developed laminar flow when the flow reaches the anode or the cathode.