Abstract: The present invention relates to the field of garbage landfill. The present invention discloses a classified landfill device and method for garbage landfills, and the problem solved by the present invention is that the device proposed in the above background absorbs metals in the garbage using a magnet, but when the surface of the magnet has absorbed a large amount of metal, the device needs to be closed to treat the metal adsorbed on the surface of the magnet. The present invention comprises a screening mechanism, crushing mechanism and discharge mechanism. According to the classified landfill device and method for garbage landfill, the second crushing knife is set at an angle to divert the falling garbage to the front and rear sides, so that the two first crushing knives and the second crushing knife cooperate to crush the garbage respectively to avoid excessive accumulation of garbage.

Abstract: Embodiments of the present disclosure disclose a semiconductor device and a method for manufacturing the same. The semiconductor device includes an active region and a passive region, the semiconductor device further includes a source, a gate and a drain located on one side of a substrate, the gate being located between the source and the drain, the gate includes a first end portion and an intermediate portion, the intermediate portion, the source and the drain all being located in the active region, and the first end portion being located in the passive region, the first end portion includes a first sub end portion and a second sub end portion. In a first direction, an extension width of the first sub end portion is greater than that of the intermediate portion, and an extension width of the second sub end portion is greater than that of the first sub end portion.

Abstract: Devices and systems are disclosed that utilize single-eye virtual reality adapters. The single-eye virtual reality adapter may include a body and a VR lens. The body may be configured to be disposed around a display screen. The body may have an inner surface and an outer surface, separated by a first sidewall and a second sidewall. The body may define a lens opening extending from the outer surface to the inner surface. The body may define a display opening extending from the first sidewall to the second sidewall (e.g., to slidably receive a display screen through the display opening). The VR lens may be removably coupled to the body. The VR lens may be disposed within the lens opening. The VR lens configured to prevent the lens from contacting the display screen; for example, the VR lens may be positioned at a distance d1>0 in front of the display screen.

Abstract: A pyrido[1,2-a]pyrimidinone compound or a pharmaceutical composition thereof for treating peripheral T cell lymphoma, and a method for or use of a pyrido[1,2-a]pyrimidinone compound for treating peripheral T cell lymphoma.

Abstract: The present application belongs to the field of medicinal chemistry, and relates to a use of a pyrido[1,2-a]pyrimidinone compound in treating lymphoma. Specifically, the present application relates to a pyrido[1,2-a]pyrimidinone compound or a pharmaceutical composition thereof for treating lymphoma, and a method or use of pyrido[1,2-a]pyrimidinone compound in treating lymphoma.

Abstract: The present disclosure provides compounds represented by Formula I: wherein R2a, R2b, R2c, R2d, R3, R13, and Z are as defined in the specification, and the salts and solvates thereof. Compounds of Formula I are cereblon (CRBN) ubiquitination inhibitors or monofunctional synthetic intermediates that can be used to prepare PROTAC molecules. CRBN ubiquitination inhibitors and PROTAC molecules are useful for the treatment of cancer and other diseases.

Abstract: The present invention provides a quinoline derivative for the treatment of nasopharyngeal carcinoma and use thereof in preparation of a pharmaceutical composition for tumor treatment.

Abstract: A flow battery system has an electrolyte storage tank, a flow battery, and a box-type flow battery system. A circular pipe I and a circular pipe II are provided in the electrolyte storage tank; the circular pipe II is communicated with an electrolyte return opening; the circular pipe I is communicated with an electrolyte delivery outlet; the annular perimeter of the circular pipe I is not equal to the annular perimeter of the circular pipe II. The multi-layer circular pipe structure in the storage tank reduces the flowing dead zone of electrolyte in the storage tank. Moreover, The reduction in the longitudinal distance between the electrolyte delivery outlet and the electrolyte return opening also reduced the problem of SOC lag so that the SOC monitoring accuracy of the flow battery is improved.

Abstract: The present invention provides a quinoline derivative for the treatment of nasopharyngeal carcinoma and use thereof in preparation of a pharmaceutical composition for tumor treatment.

Abstract: One witness node may provide quorum witness functionality for multiple quorums concurrently (e.g., while multiple quorums are executing independently and simultaneously). An aggregated heartbeat message from a first quorum actor of the first quorum may include a first quorum heartbeat message that has a unique identifier for the first quorum. This identifier may allow update for the quorum data store with respect to the first quorum. The aggregated heartbeat message may also include information representing a second quorum heartbeat message from a second quorum actor of a second quorum. The second quorum heartbeat message may include a second unique identifier for the second quorum. The second identifier may allow an update for the quorum data store independently of the first update. More than two quorums may be supported by a single witness node by extracting individualized information from an aggregated heartbeat message.

Abstract: Provided in the present invention is a quinoline derivative for treating gastric cancer. 1-[[[4-(4-fluoro-2-methyl-1H-indol-5-yl)oxy-6-methoxyquinolin-7-yl]oxy]methyl]cyclopropylamine or a pharmaceutically acceptable salt, a hydrate or a prodrug thereof as provided in the present application can effectively treat gastric cancer, and can stabilize or relieve the state of illness of a gastric cancer patient.

Abstract: An apparatus monitors the state of charge (SOC) of a flow battery system. The monitoring method include determining SOCs of at least two pairs of different monitoring positions. A pair of monitoring position may be located inside of an anode electrolyte storage tank (2) and inside of a cathode electrolyte storage tank (3), or inside of an anode electrolyte outlet pipeline (6) of a stack and inside of a cathode electrolyte outlet pipeline (7) of the stack, or inside of an anode electrolyte inlet pipeline (8) of the stack and inside of a cathode electrolyte inlet pipeline (9) of the stack. The SOCsum of the flow battery system is acquired according to the SOCs corresponding to different pair of monitoring positions, respectively. The method ensures acquiring an SOC monitoring result timely and accurately.

Abstract: One witness node may provide quorum witness functionality for multiple quorums concurrently (e.g., while multiple quorums are executing independently and simultaneously). An aggregated heartbeat message from a first quorum actor of the first quorum may include a first quorum heartbeat message that has a unique identifier for the first quorum. This identifier may allow update for the quorum data store with respect to the first quorum. The aggregated heartbeat message may also include information representing a second quorum heartbeat message from a second quorum actor of a second quorum. The second quorum heartbeat message may include a second unique identifier for the second quorum. The second identifier may allow an update for the quorum data store independently of the first update. More than two quorums may be supported by a single witness node by extracting individualized information from an aggregated heartbeat message.

Abstract: An apparatus monitors the state of charge (SOC) of a flow battery system. The monitoring method include determining SOCs of at least two pairs of different monitoring positions. A pair of monitoring position may be located inside of an anode electrolyte storage tank (2) and inside of a cathode electrolyte storage tank (3), or inside of an anode electrolyte outlet pipeline (6) of a stack and inside of a cathode electrolyte outlet pipeline (7) of the stack, or inside of an anode electrolyte inlet pipeline (8) of the stack and inside of a cathode electrolyte inlet pipeline (9) of the stack. The SOCsum of the flow battery system is acquired according to the SOCs corresponding to different pair of monitoring positions, respectively. The method ensures acquiring an SOC monitoring result timely and accurately.

Abstract: An apparatus monitors the state of charge (SOC) of a flow battery system. The monitoring method include determining SOCs of at least two pairs of different monitoring positions. A pair of monitoring position may be located inside of an anode electrolyte storage tank (2) and inside of a cathode electrolyte storage tank (3), or inside of an anode electrolyte outlet pipeline (6) of a stack and inside of a cathode electrolyte outlet pipeline (7) of the stack, or inside of an anode electrolyte inlet pipeline (8) of the stack and inside of a cathode electrolyte inlet pipeline (9) of the stack. The SOCsum of the flow battery system is acquired according to the SOCs corresponding to different pair of monitoring positions, respectively. The method ensures acquiring an SOC monitoring result timely and accurately.

Abstract: A flow battery system has an electrolyte storage tank, a flow battery, and a box-type flow battery system. A circular pipe I and a circular pipe II are provided in the electrolyte storage tank; the circular pipe II is communicated with an electrolyte return opening; the circular pipe I is communicated with an electrolyte delivery outlet; the annular perimeter of the circular pipe I is not equal to the annular perimeter of the circular pipe II. The multi-layer circular pipe structure in the storage tank reduces the flowing dead zone of electrolyte in the storage tank. Moreover, The reduction in the longitudinal distance between the electrolyte delivery outlet and the electrolyte return opening also reduced the problem of SOC lag so that the SOC monitoring accuracy of the flow battery is improved.

Abstract: Provided in the present invention is a quinoline derivative for treating gastric cancer. 1-[[[4-(4-fluoro-2-methyl-1H-indol-5-yl)oxy-6-methoxyquinolin-7-yl]oxy]methyl]cyclopropylamine or a pharmaceutically acceptable salt, a hydrate or a prodrug thereof as provided in the present application can effectively treat gastric cancer, and can stabilize or relieve the state of illness of a gastric cancer patient.

Abstract: An apparatus monitors the state of charge (SOC) of a flow battery system. The monitoring method include determining SOCs of at least two pairs of different monitoring positions. A pair of monitoring position may be located inside of an anode electrolyte storage tank (2) and inside of a cathode electrolyte storage tank (3), or inside of an anode electrolyte outlet pipeline (6) of a stack and inside of a cathode electrolyte outlet pipeline (7) of the stack, or inside of an anode electrolyte inlet pipeline (8) of the stack and inside of a cathode electrolyte inlet pipeline (9) of the stack. The SOCsum of the flow battery system is acquired according to the SOCs corresponding to different pair of monitoring positions, respectively. The method ensures acquiring an SOC monitoring result timely and accurately.