The present disclosure relates to a continuous fermentation device that can ferment objects continuously fed thereinto while conveying the objects. The present disclosure provides a continuous fermentation device comprising a plurality of fermentation modules, each including: a conveyor belt, which transports objects that are continuously fed thereinto to be fermented from one side to the opposite side thereof; agitators, which is located on the conveyor belt; and an air diffuser, which is located on one side of the conveyor belt, in which the continuously fed objects to be fermented are fermented while being passed through the fermentation modules. According to the present disclosure, feeding of raw materials to be fermented, fermenting the raw materials, and discharging of the fermented materials are continuously performed so that it is possible to significantly reduce the processing time, thereby reducing the operation time of the production process. Accordingly, it is possible to achieve an increase in competitiveness, such as improved productivity, reduction of investment cost, etc., in the development of a method of mass production through solid-state fermentation, thereby innovatively reducing the production cost of the product.

The present disclosure relates to a continuous fermentation device that can ferment objects continuously fed thereinto while conveying the objects. The present disclosure provides a continuous fermentation device comprising a plurality of fermentation modules, each including: a conveyor belt, which transports objects that are continuously fed thereinto to be fermented from one side to the opposite side thereof; agitators, which is located on the conveyor belt; and an air diffuser, which is located on one side of the conveyor belt, in which the continuously fed objects to be fermented are fermented while being passed through the fermentation modules. According to the present disclosure, feeding of raw materials to be fermented, fermenting the raw materials, and discharging of the fermented materials are continuously performed so that it is possible to significantly reduce the processing time, thereby reducing the operation time of the production process. Accordingly, it is possible to achieve an increase in competitiveness, such as improved productivity, reduction of investment cost, etc., in the development of a method of mass production through solid-state fermentation, thereby innovatively reducing the production cost of the product.

Work-saving improvements for food-process lines include (1) mounting alternate machines of a food process line on pivot hardware to speed up washing and maintenance operations, (2) mounting the machines on rolling riding gear in order to speed up the activities of building and re-building food process lines of a different series of machines, or (3) isolate the food process line in its own tunnel and hence its own climate-controlled atmosphere to reduce conflicts with running two food process lines side by side where one food process line is a source of air borne allergens.

Work-saving improvements for food-process lines include (1) mounting alternate machines of a food process line on pivot hardware to speed up washing and maintenance operations, (2) mounting the machines on rolling riding gear in order to speed up the activities of building and re-building food process lines of a different series of machines, or (3) isolate the food process line in its own tunnel and hence its own climate-controlled atmosphere to reduce conflicts with running two food process lines side by side where one food process line is a source of air borne allergens.

A transfer conveyor for food process lines is equipped with hardware to enable pivoting in place and other hardware to enable and reversible expansion and contraction of the transfer conveyor, or at least the upper, food-product carrying run of the endless conveyor belt therefor.

An order picking system (1) for transporting and providing general cargo (S, S) and associated method includes a feeding device (2) with a suspension conveyor (21) for feeding the general cargo (S, S), and a delivery station (22) for delivering the general cargo (S, S) from the suspension conveyor (2.1) to a transfer device (3) for grouping the conveyed general cargo (S, S), which transfer device (3) includes a horizontally movable transfer element (31) by which the general cargo (S, S) can be grouped gravity-driven onto a grouping space (P).

An order picking system (1) for transporting and providing general cargo (S, S) and associated method includes a feeding device (2) with a suspension conveyor (21) for feeding the general cargo (S, S), and a delivery station (22) for delivering the general cargo (S, S) from the suspension conveyor (2.1) to a transfer device (3) for grouping the conveyed general cargo (S, S), which transfer device (3) includes a horizontally movable transfer element (31) by which the general cargo (S, S) can be grouped gravity-driven onto a grouping space (P).

A high-speed and high-precision Radio Frequency Identification (RFID) detection tunnel machine includes: an RFID reader-writer and an RFID antenna; a first conveying line, which conveys a carrier, and the carrier includes at least one RFID tag; a tunnel machine body, which is configured for the first conveying line to pass through, and covers the reading range; and a second conveying line, which conveys the carrier and ensures that the first conveying line only has one carrier. In the application, the second conveying line is disposed, and its relevant parameters may be adjusted according to parameters of the first conveying line and position of the carrier on the first conveying line, so as to realize continuous operation of the tunnel machine and ensure timely supplement of the carrier on the first conveying line.

A high-speed and high-precision Radio Frequency Identification (RFID) detection tunnel machine includes: an RFID reader-writer and an RFID antenna; a first conveying line, which conveys a carrier, and the carrier includes at least one RFID tag; a tunnel machine body, which is configured for the first conveying line to pass through, and covers the reading range; and a second conveying line, which conveys the carrier and ensures that the first conveying line only has one carrier. In the application, the second conveying line is disposed, and its relevant parameters may be adjusted according to parameters of the first conveying line and position of the carrier on the first conveying line, so as to realize continuous operation of the tunnel machine and ensure timely supplement of the carrier on the first conveying line.

An assembly line system comprising including a programable controller, a priority component, a first section upstream of the priority component that includes upstream backup detecting sensors, and a second section downstream of the priority component that includes downstream backup detecting sensors. In operation, the programable controller identifies whether there is a backup in the first and/or second section from a current status of each of the upstream and downstream backup detecting sensors and alters an operating speed of the priority component responsive thereto so as to avoid micro stops of the priority component.