Abstract: This application provides techniques comprising S1: establishing a queue for accommodating m file descriptors for creating n1 first access request data packets; S2: creating an ith file descriptor in the queue, sending an ith first access request data packet by using the ith file descriptor, and monitoring a source port recorded by the ith file descriptor; S3: at every first preset time interval t1, enabling i to automatically increase by 1, continuing to perform operation S2, and setting preset monitoring time T for each source port, where T=t1*m; and S4: ending monitoring of an (i?m)th source port and destroying a corresponding file descriptor while creating an ith file descriptor in the queue when m*j<i?m*(j+1), and stopping monitoring of other source ports in response to detecting that a first port receives a response data packet, where the first port is any source port in a monitored state.

Abstract: This application provides techniques comprising creating a main thread and at least two task threads; determining, by the main thread, a target task thread based on a data packet corresponding to a data transmission task in response to detecting the data transmission task associated with a client device, and sending the data packet to the target task thread, where the target task thread is any one of the at least two task threads; and receiving, by the target task thread, the data packet sent by the main thread, determining, based on the data packet, a first file descriptor corresponding to the client device, and communicating with the client device by using the first file descriptor to perform data transmission.

Abstract: The present disclosure provides a heat treatment method for realizing grain boundary serration in a nickel-based superalloy forging, including introducing a serrated grain boundary into a microstructure of a nickel-based superalloy forging by using a heat treatment method for controlling a cooling rate; the heat treatment method for controlling cooling speed includes the following steps: step S1: holding the nickel-based superalloy forging for 0.5-4 h at 1,050-1,200° C.; step S2: cooling the nickel-based superalloy forging to 650-800° C. at a preset cooling rate, and holding for 1-8 h, where the preset cooling rate is 1-20° C./min; and step S3, taking out and cooling the nickel-based superalloy forging to room temperature with water. The heat treatment method for realizing grain boundary serration in a nickel-based superalloy forging provided by the present disclosure can realize the grain boundary serration in the nickel-based superalloy forging.

Abstract: The present disclosure provides a heat treatment method for realizing grain boundary serration in a nickel-based superalloy forging, including introducing a serrated grain boundary into a microstructure of a nickel-based superalloy forging by using a heat treatment method for controlling a cooling rate; the heat treatment method for controlling cooling speed includes the following steps: step S1: holding the nickel-based superalloy forging for 0.5-4 h at 1,050-1,200° C.; step S2: cooling the nickel-based superalloy forging to 650-800° C. at a preset cooling rate, and holding for 1-8 h, where the preset cooling rate is 1-20° C/min; and step S3, taking out and cooling the nickel-based superalloy forging to room temperature with water. The heat treatment method for realizing grain boundary serration in a nickel-based superalloy forging provided by the present disclosure can realize the grain boundary serration in the nickel-based superalloy forging.