CONNECTOR FOR HYDRODYNAMIC APPLICATIONS EQUIPPED WITH AT LEAST ONE DETECTION SENSOR

Abstract

A connector, e.g. a quick connector, for hydraulic applications, in particular for hydraulic circuits and the like, the connector including a female coupling and a male coupling suited to be alternatively connected and disconnected from each other, wherein the mutual connection of the female and male coupling translates into the possible flow of a fluid between the female and male couplings, wherein at least either the male or female coupling comprises a first detection sensor configured so as to detect working and/or operating parameters and/or values of the connector.

Claims

1. A connector for hydraulic applications, in particular for hydraulic circuits and the like, said connector comprising a female coupling and a male coupling suited to be alternatively connected to and disconnected from each other, wherein the mutual connection of said female and male coupling translates into the possible flow of a fluid between said female and male couplings, wherein at least either said male or female coupling comprises a first detection sensor configured so as to detect working and/or operating parameters and/or values of said connector.

2. The connector according to claim 1, wherein said female coupling comprises an outer hollow main assembly, and wherein said first detection sensor is housed in said outer hollow main assembly.

3. The connector according to claim 1, wherein said first sensor is configured to detect whether said male and female couplings are connected correctly.

4. The connector according to claim 2, wherein said first sensor is configured to detect whether said male and female couplings are connected correctly.

5. The connector according to claim 1, wherein said first sensor is configured to detect at least one of the following parameters: absence or presence of fluid flow between said male and female couplings, pressure value of said fluid inside said connector, temperature value of said fluid inside said connector, total time of presence of fluid between said male and female couplings.

6. The connector according to claim 4, wherein said first sensor is configured to detect at least one of the following parameters: absence or presence of fluid flow between said male and female couplings, pressure value of said fluid inside said connector, temperature value of said fluid inside said connector, total time of presence of fluid between said male and female couplings.

7. The connector according to claim 1, wherein the second of said male and female couplings also comprises a second detection sensor configured so as to detect working and/or operating parameters and/or values of said connector.

8. The connector according to claim 6, wherein the second of said male and female couplings also comprises a second detection sensor configured so as to detect working and/or operating parameters and/or values of said connector.

9. The connector according to claim 1, wherein either one of said first and second sensors is configured to detect the pressure of said fluid inside said male coupling and in the absence of connection between said male and female couplings.

10. The connector according to claim 8, wherein either one of said first and second sensors is configured to detect the pressure of said fluid inside said male coupling and in the absence of connection between said male and female couplings.

11. An integrated system comprising at least one female or respectively male coupling of a connector according to claim 1, wherein it also comprises a communication unit, wherein said communication unit and said first sensor are configured to communicate with each other in such a way so as to allow at least the transmission of said parameters and/or values from said first sensor to said communication unit.

12. The integrated system according to claim 11, wherein said communication unit and said first sensor are configured to communicate with each other in BLUETOOTH mode or also possibly via WI-FI or even simply in wireless mode.

13. The integrated system according to claim 12, wherein said communication unit is configured so as to allow the comparison between the parameters and/or values detected by said first and/or second sensors and corresponding predetermined parameters and/or values and to generate a warning and/or alarm signal if the differences between detected parameters and/or values and the predetermined parameters and/or values are higher than default tolerances.

14. The integrated system comprising at least one female or respectively male coupling of a connector according to claim 8, wherein it also comprises a communication unit, wherein said communication unit and said first and/or second sensor are configured to communicate with each other in such a way so as to allow at least the transmission of said parameters and/or values from said first and/or second sensor to said communication unit.

15. An operating machine comprising a hydraulic circuit, said machine being equipped with at least one female or respectively male coupling of a connector according to claim 1, and wherein said female or respectively male coupling comprises said first sensor.

16. An operating machine comprising a hydraulic circuit, said machine being equipped with at least one female and male coupling of a connector according to claim 8, and wherein each of said female and male couplings comprises a sensor.

17. An operating machine comprising a hydraulic circuit, said machine being equipped with at least one female or respectively male coupling of a connector comprising a female coupling and a male coupling suited to be alternatively connected to and disconnected from each other, wherein the mutual connection of said female and male coupling translates into the possible flow of a fluid between said female and male couplings, wherein at least either said male or female coupling comprises a first detection sensor configured so as to detect working and/or operating parameters and/or values of said connector, and wherein said female or respectively male coupling comprises said first sensor, said machine being equipped with a system according to claim 13.

18. The operating machine according to claim 17, further comprising a control unit with an operator interface, wherein said control unit and said communication unit are configured to communicate with each other.

19. The operating machine according to claim 18, wherein the communication between said control unit and/or management and/or said communication unit is such as to allow the verification of said parameters and/or values by an operator through said interface.

20. A tool or implement comprising a hydraulic circuit suited to be operatively connected to the hydraulic circuit corresponding to a main operating machine, said tool being equipped with at least one female or respectively male coupling of a connector according to claim 1, wherein said female or respectively male coupling comprises said sensor.

21. An operating machine-tool system or implement, comprising an operating machine having a hydraulic circuit, said machine being equipped with at least one female or respectively male coupling of a connector comprising a female coupling and a male coupling suited to be alternatively connected to and disconnected from each other, wherein the mutual connection of said female and male coupling translates into the possible flow of a fluid between said female and male couplings, wherein at least either said male or female coupling comprises a first detection sensor configured so as to detect working and/or operating parameters and/or values of said connector, and wherein said female or respectively male coupling comprises said first sensor, further comprising a tool or implement according to claim 20.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0029] Hereinafter, the present invention will be explained by means of the following detailed description of the embodiments depicted in the drawings. However, the present invention is not limited to the embodiments described hereinafter and depicted in the drawings; conversely, all the variants of the embodiments described below and depicted in the drawings which will be apparent to a person skilled in the art are comprised within the scope of the present invention.

[0030] In the drawings:

[0031] FIG. 1 shows schematic views of possible applications of the present invention;

[0032] FIG. 2 shows a schematic view of a first embodiment of the invention;

[0033] FIG. 3 shows a schematic view of an embodiment of the present invention;

[0034] FIG. 4 shows schematic views of possible implementations of the present invention; and

[0035] FIG. 5 shows a schematic view of an embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0036] In FIG. 1, reference numerals 100 and 200 identify an agricultural tractor and a tool or implement, respectively, particularly a rototiller adapted to be used by means of the tractor 100, wherein the examples depicted in FIG. 1 are to be considered as non-limiting, being the applications of the present invention (see description below) not limited to the agricultural sector but also comprising operating machines and tools, implements and machinery of other sectors, such as, for example, that of earth-moving, constructions and/or demolition machines, and the like. Similarly, the tractor 100 is depicted as being equipped with front loader 201 (see the box of FIG. 1b). Both the tool (rototiller) 200 and the front loader 201 for performing given operations exploit the hydrodynamic power made available by the tractor 100 and, for this purpose, the hydraulic circuits of the tool (rototiller) 200 and of the front loader 201 are connected to the hydraulic circuit of the tractor 100 by hydraulic pipes (flexible, in the example as depicted) 31 and 32 in the case of tool (rototiller) 200 and from 31 to 34 in the case of front loader 201.

[0037] For the purpose, as depicted in FIG. 2, the tractor 100 is equipped with a terminal assembly 101 (also referred to as valve assembly or hydrodynamic distributor) of the respective hydraulic circuit, the assembly 101 being provided for connecting the hydraulic circuit of the tractor 100 to the hydraulic circuits of tools, implements and/or machinery (such as the tool, in particular the rototiller 200) applied to the rear of the tractor (e.g. by means of the three-point connector, but also towed). Additional terminal assemblies may be provided for tools, implements and/or machinery applied to the tractor at the front and/or laterally, as in the case of front loader 201. The coupling and/or connecting features and/or methods of the rear terminal assembly 101 will be described below, for the sake of brevity as the following description also applies to different terminals, e.g. side and/or front terminals.

[0038] As depicted in FIG. 2, the terminal or valve assembly 101 comprises a plurality of female couplings 11, 12, each of which can be mechanically and hydraulically connected to a corresponding male coupling 21, 22. The methods for mechanically and hydraulically coupling the couplings 11, 12 respectively with the couplings 21 and 22 vary according to the type of coupling; same are also substantially known and therefore a detailed description is not provided for the sake of conciseness. It is solely specified that a hydraulic connection is established between the circuits respectively upstream of the female couplings 11, 12 (in the case shown) and downstream of the male coupling 21, 22 (again in the case shown) by mechanically coupling the female and male couplings and that the valve assembly 101 may comprise either the female and/or male couplings, wherein the tool or apparatus 200, 201 can be correspondingly equipped with male and/or female couplings, respectively.

[0039] The present invention finds also advantageous application in the case of multiple connectors provided with a plurality of couplings which allow the simultaneous connection of said couplings to those of a moveable terminal of a tool and/or apparatus.

[0040] FIG. 3 shows the innovative concept underlying the present invention.

[0041] As depicted, the female coupling 11 is equipped (according to solutions and/or methods described in detail below) with a detection sensor 111, while the male coupling 21 is equipped with a sensor 121. Obviously, in the case of a multiple terminal, each of the respective couplings, according to the invention, may be equipped with a corresponding sensor, wherein moreover, according to the present invention, even only one of the male and female couplings of a connector can be equipped with a sensor.

[0042] The sensors 111 and 121 (or at least one of the two) are configured to monitor the functionality and/or the actual conditions of use of the connector in particular, according to the invention, the data which can be detected by the sensor 111 and/or the sensor 121 comprise:

[0043] absence or presence of fluid flow between said male 21 and female 11 couplings, pressure value of said fluid inside said connector, temperature value of said fluid inside said connector, total time of presence of fluid between said male 21 and female 11 couplings.

[0044] Either alternatively or additionally, the sensor 111 and/or the sensor 121 may be configured to detect and/or verify the correct or incorrect hydraulic connection between the male 21 and female 11 couplings. Furthermore, the sensor 121 may be configured so as to detect the pressure of said fluid inside said male coupling 21 and in the absence of connection between said male 21 and female 11 couplings.

[0045] Again with reference to FIG. 3, reference numeral 300 identifies a unit or communication control unit specifically configured to at least receive the data detected by the sensors 111 and/or 121 from the sensors themselves and summarized above.

[0046] In particular, according to the present invention, the communication between the control unit 300 and the sensors 111 and/or 121 (one-way at least from the sensors to the control unit, but possibly also two-way from the sensors to the control unit and vice versa) can be wireless, in particular in BLUETOOTH mode, but possibly via WI-FI.

[0047] Moreover, according to the present invention, a communication is provided (wired or wireless, e.g. BLUETOOTH, but possibly via WI-FI), between the control unit 300 and a control unit accessible to an operator, e.g. provided in the cab of the tractor 100 and equipped with an interface for viewing the data collected by the sensors and/or configured to allow the insertion of instructions and/or requests by the operator, e.g. with touch-screen technology.

[0048] Furthermore, the control unit 300 may be provided with a calculation and/or processing unit for processing the data transmitted by the sensors 111 and/or 121, e.g. for extrapolating the data themselves and/or calculating weighted averages, preparing statistics or similar operations.

[0049] Then, according to an embodiment of the present invention, an application which can be downloaded to smartphones and/or tablets is also provided for the remote management of the control unit 300, i.e. for displaying the data processed by the control unit 300 and/or entering instructions as through the control unit provided in the cab.

[0050] FIG. 4 shows two possible solutions for integrating the sensors in the female and/or male couplings.

[0051] In particular, according to the solution in FIG. 4a, the sensor 111 (not shown in the figure) is housed in the inner space defined by a hollow element 110, in turn threaded onto the female coupling 11, the sensor 121 (not shown in the figure) being similarly housed in the inner space defined by a hollow element 210 of the male coupling 21.

[0052] The solution according to FIG. 4b is substantially similar to that of FIG. 4a, wherein FIG. 4b shows a male coupling 21 and a corresponding female coupling 11 of type flat-face, the sensors 111 and 121 being also in this case housed in the inner spaces defined by hollow elements 110 and 210 respectively of the female 11 and male 21 couplings.

[0053] FIG. 5 instead shows a possible solution for applying sensors to couplings which do not have hollow elements which define an inner space suited to accommodate one or more sensors. In this case, as depicted, an additional hollow element 220 which is applied externally to the both female 11 and male 21 coupling is provided, said additional hollow element being shaped so as to define the inner space suited for housing the sensor (not shown in the figure).

[0054] It has thus been demonstrated by means of the above detailed description of the embodiments of the present invention depicted in the drawings that the present invention allows to achieve the predetermined objects by overcoming the drawbacks affecting the prior art.

[0055] In particular, the present invention allows the direct monitoring of at least the main parameters of a hydraulic circuit, in particular at a connector, e.g. a quick connector and/or of the push-pull type.

[0056] Furthermore, the present invention also provides a solution which allows the direct verification of the actual or missing or even incorrect connection of the couplings of a connector, characterized by low costs, and which can be made and installed through simple and quick operations, and the installation of which on couplings of known type does not require modifications, at least not substantial modifications, of the couplings themselves.

[0057] Although it is explained above by means of a detailed description of the embodiments shown in the drawings the present invention is not limited to the embodiments described above and shown in the drawings. Conversely, all the modifications and/or variants of the embodiments described above and shown in the drawings which will appear obvious and immediate to a person skilled in the art are included in the scope of the present invention.

[0058] For example, the number and type of sensors and the data which can be detected by them may vary in the scope of the present invention, according to needs and/or circumstances.

[0059] The scope of the present invention is thus defined by the claims.