Line and method for the continuous cycle production of plastic objects

1 . A line for the continuous cycle production of plastic objects, comprising: an extruder configured to receive solid plastic material in raw form and to feed out a flow of plastic fluid; a compression moulding machine including a rotating moulding carousel and a plurality of moulds to form an ordered succession of objects from corresponding doses; a transfer apparatus configured to obtain an ordered succession of doses from the flow of plastic fluid and to feed the doses individually to the compression moulding machine; a conveyor configured to receive the objects individually and to transport them in the same ordered succession; a first sensor configured to detect a first diagnostic signal and located at a first predetermined position in the line; and a control unit configured to generate a synchronization signal representing an operating configuration of the line in real time and programmed to capture the first diagnostic signal synchronously relative to the synchronization signal. 2 . The line according to claim 1 , wherein the synchronization signal represents the speed at which the doses and objects move along the line, and wherein the first predetermined position is a stationary position relative to the movement of the ordered succession of doses and objects along the line. 3 . The line according to claim 2 , wherein the synchronization signal is correlated with an angular position of the moulding carousel. 4 . The line according to claim 3 , wherein the control unit is responsible for receiving an analogue signal representing a time trend of the first diagnostic signal, is configured to generate a digital representation of the analogue signal and is programmed to process the digital signal as a function of the synchronization signal. 5 . The line according to claim 2 , wherein the control unit is programmed to capture the first diagnostic signal in a first succession of time instants, to derive a corresponding first ordered succession of values of the first diagnostic signal, wherein the first succession of time instants is a function of the synchronization signal and of the first predetermined position. 6 . The line according to claim 5 , comprising a second sensor configured to detect a second diagnostic signal and disposed at a second predetermined position in the line different from the first position, wherein the control unit is programmed to capture the second diagnostic signal in a second succession of time instants, to derive a corresponding second ordered succession of values of the second diagnostic signal, wherein the second succession of time instants is a function of the synchronization signal and of the second predetermined position, and wherein the control unit is programmed to correlate the first and second ordered successions of captured values, so that each value of the first ordered succession is correlated with a respective value of the second succession. 7 . The line according to claim 6 , wherein at each time instant of the first succession of time instants, the first sensor operatively interacts with a respective member of the ordered succession of doses or objects, and wherein at any time instant of the second succession of time instants, the second sensor operatively interacts with the same member of the ordered succession of doses or objects. 8 . The line according to claim 1 , wherein the first sensor is selected from the following list: a) a temperature sensor configured to detect the temperature of the objects moulded by the compression moulding machine; b) a pressure or flow sensor operatively connected in a pneumatic circuit responsible for driving pushers of the transfer apparatus, the pushers acting on respective doses of the ordered succession of doses; c) a detection camera directed at the rotating moulding carousel of the compression moulding machine to view each of the doses in a respective mould individually and in succession; d) an inspection camera positioned along a path of movement of the objects moulded by the compression moulding machine to capture images of the individual objects; e) a flow pressure meter operatively mounted in a duct responsible for supplying compressed air to a pneumatic system configured to extract from the respective moulds the moulded objects formed in the compression moulding machine; f) a pressure transducer operatively connected in a hydraulic circuit responsible for the relative movement of the mould parts which, for each of the moulds of the compression moulding machine, act in conjunction to produce compression; g) an accelerometer coupled to a pump responsible for the relative movement of the mould parts which, for each of the moulds of the compression moulding machine, act in conjunction to produce compression; h) an optical sensor coupled to the extruder for detecting a plasticization parameter, which indicates a physical state of the plastic material processed by the extruder; i) a speed sensor configured to measure the angular speed of a screw of the extruder, acting in conjunction with a plastic fluid pressure sensor located at an outfeed end of the extruder to measure the pressure of the plastic fluid flow; l) a current or electrical power sensor configured to measure the electrical power absorbed by the line or part of the line. 9 . The line according to claim 8 comprising two or more sensors selected from corresponding items of the list of claim 8 . 10 . A method for the continuous cycle production of plastic objects, comprising the following steps: extruding a solid plastic material and generating a flow of plastic fluid; forming an ordered succession of doses from that flow of plastic fluid; inserting the doses in corresponding moulds integral with a rotating moulding carousel; compression moulding an ordered succession of objects by compressing the doses in the moulds; transporting the objects away from the moulding carousel one by one while keeping them in the same ordered succession; detecting a first diagnostic signal through a first sensor located at a first predetermined position in the line; generating a synchronization signal representing an operating configuration of the line in real time; and capturing the first diagnostic signal synchronously relative to the synchronization signal. 11 . The method according to claim 10 , wherein the synchronization signal represents the speed at which the doses and objects move along the line, and wherein the first predetermined position is a stationary position relative to the movement of the ordered succession of doses and objects along the line. 12 . The method according to claim 11 , wherein the synchronization signal is correlated with an angular position of the rotating carousel. 13 . The method according to claim 12 , comprising a step of digitizing an analogue signal representing a time trend of the first diagnostic signal, the method further comprising a step of processing the digital signal as a function of the synchronization signal. 14 . The method according to claim 11 , wherein the first diagnostic signal is captured in a first succession of time instants, so as to derive a corresponding first ordered succession of values of the first diagnostic signal, wherein the first succession of time instants is generated as a function of the synchronization signal and of the first predetermined position. 15 . The method according to claim 10 , wherein the first sensor is selected from the following list: a) a temperature sensor which detects the temperature of the objects moulded by the compression moulding machine; b) a pressure or flow s