Electrolyzer system and matrix cell therefor

The invention claimed is: 1. A matrix cell configured for an electrolyzer system for electrolyzing an aqueous electrolyte, wherein the matrix cell comprises: an electrolyte space for accommodating the aqueous electrolyte; a cathode electrode and an anode electrode; a cathodic gas space, disposed adjacent to the electrolyte space and separated therefrom by a gastight first membrane, the cathodic gas space and the cathode electrode being configured such that energizing of the cathode electrode allows a cathodic product gas to be generated at an interface of the cathode electrode with the first membrane such that it is flowable into the cathodic gas space; an anodic gas space, disposed adjacent to the electrolyte space and separated therefrom by a gastight second membrane, the anodic gas space and the anode electrode being configured such that energizing of the anode electrode allows anodic product gas to be generated at an interface of the anode electrode with the second membrane such that it is flowable into the anodic gas space; and a degassing device bound between the electrolyte space and the anode electrode or the cathode electrode, which is configured to allow selective emergence of gas located in the electrolyte space into at least one of the cathodic gas space and the anodic gas space, wherein the degassing device is disposed in a degassing aperture, formed in at least one membrane, in order to provide selective passage for at least one of the cathodic product gas or the anodic product gas from the electrolyte space into at least one of the cathodic gas space and the anodic gas space. 2. The matrix cell as claimed in claim 1 , wherein the degassing device is disposed in a degassing aperture, formed in the first membrane, in order to provide passage for the cathodic product gas from the electrolyte space into the cathodic gas space. 3. The matrix cell as claimed in claim 1 , wherein the degassing device has a degassing membrane which is configured selectively to let through predominantly the cathodic product gas or the anodic product gas. 4. The matrix cell as claimed in claim 1 , wherein the degassing device comprises at least one degassing membrane layer structure which has a hydrophilic or hydrophobic degassing membrane. 5. The matrix cell as claimed in claim 1 , wherein the degassing device comprises a degassing membrane layer structure which comprises a hydrophobic degassing membrane and a hydrophilic degassing membrane, the hydrophobic degassing membrane being disposed between the hydrophilic degassing membrane and the electrolyte space such that the hydrophobic degassing membrane in an operating state comes into contact with the electrolyte. 6. The matrix cell as claimed in claim 1 , wherein the degassing device is configured to be brought into a state in which gas bubbles can be generated in a hydrophilic degassing membrane. 7. The matrix cell as claimed in claim 1 , wherein the degassing device comprises at least one degassing membrane, wherein at least one of: at least one degassing membrane is a porous membrane which is configured to transport product gas by means of pores, at least one degassing membrane is a solution-diffusion membrane which is configured to transport product gas dissolved in the membrane by means of diffusion, or at least one degassing membrane is a functional membrane which has a poreless configuration and is at least one of water- or ion-conducting. 8. The matrix cell as claimed in claim 1 , wherein at least one of: the electrolyte contains a devolatilizing additive which is configured to promote a coalescence of small gas bubbles into a larger gas bubble; the electrolyte contains a viscosity-modifying additive which is configured to change a viscosity of the electrolyte in comparison to the viscosity of the electrolyte without such additive; the electrolyte contains a defoaming additive which is configured to reduce a probability of the development of liquid interfaces, in order to facilitate gas transport; the electrolyte contains a magnetorheological additive which is configured to heighten an interaction between the electrolyte and a magnetic field; or the electrolyte contains an electrorheological additive which is configured to heighten the interaction between the electrolyte and an electrical field. 9. The matrix cell as claimed in claim 1 , further comprising a field generation device which is configured to generate at least one of an electrical field or a magnetic field configured such that a flow of the electrolyte in the electrolyte space in a fluid flow direction can be generated. 10. The matrix cell as claimed in claim 1 , wherein the degassing device comprises a degassing membrane layer structure which comprises a hydrophobic degassing membrane, wherein the hydrophobic degassing membrane is a silver membrane. 11. The matrix cell as claimed in claim 1 , wherein the degassing device comprises at least one degassing membrane, wherein the at least one degassing membrane is a functional membrane which has a poreless configuration and is at least one of water- or ion-conducting. 12. The matrix cell as claimed in claim 5 , wherein the hydrophilic degassing membrane is a silver membrane. 13. An electrolyzer system configured for electrolyzing an aqueous electrolyte, wherein the electrolyzer system comprises: an electrolyzer device having at least one matrix cell which has an electrolyte space for accommodating the aqueous electrolyte, the at least one matrix cell further comprising; a cathode electrode and an anode electrode; a cathodic gas space disposed adjacent to the electrolyte space and separated therefrom by a gastight first membrane, the cathodic gas space and the cathode electrode being configured such that energizing of the cathode electrode allows a cathodic product gas to be generated at an interface of the cathode electrode with the first membrane such that it is flowable into the cathodic gas space; an anodic gas space disposed adjacent to the electrolyte space and separated therefrom by a gastight second membrane, the anodic gas space and the anode electrode being configured such that energizing of the anode electrode allows anodic product gas to be generated at an interface of the anode electrode with the second membrane such that it is flowable into the anodic gas space; and a degassing device bound between the electrolyte space and the anode electrode or the cathode electrode, which is configured to allow selective emergence of gas located in the electrolyte space into at least one of the cathodic gas space and the anodic gas space, wherein the degassing device is disposed in a degassing aperture, formed in at least one membrane, in order to provide selective passage for at least one of the cathodic product gas or the anodic product gas from the electrolyte space into at least one of the cathodic gas space and the anodic gas space; wherein the electrolyzer system comprises at least one of the following features: a) at least one separation device which is in fluid communication with the electrolyte space and a product gas exit and is configured to let product gas through from a liquid side to a gas side; or b) at least one pump device which is configured to convey the electrolyte in a circuit extending through the electrolyte space. 14. The electrolyzer system as claimed in claim 13 , further comprising at least one pressure regulation device, which is connected in a fluid flux direction between one of the gas spaces and the separation device, wherein the at least one pressure regulation device is configured to limit a fluid flux from the gas space to the se