JP2019183858A - Rotary joint and fluid feeding mechanism - Google Patents

Abstract

To provide a rotary joint and a fluid feeding mechanism capable of easily and objectively detecting change of a sliding state caused by accumulation and solidification of foreign matters after intrusion into a sliding clearance between a fixed shaft portion and a fitting hole.SOLUTION: A rotary joint 1 for feeding a fluid supplied from a fluid supply source 20 to a rotary flow channel of equipment 23 comprises a sliding state detection portion 13 used for detecting a sliding state of a fixed shaft portion constituting a fixed flow channel. The sliding state detection portion 13 includes a detection member moving with the fixed shaft portion 8a, and a pressurization space communicating with a detection hole into which the detection member is fitted, and pressurized at a prescribed pneumatic pressure. The pressure in the pressurization space is detected by a flow rate sensor 22, and data on a result of the detection is processed by a data processing portion 24 to determine the sliding state of the fixed shaft portion fitted into the fitting hole.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a rotary joint and a fluid feeding mechanism used for feeding a fluid to a rotating part.

  As a fluid coupling that connects a fixed fluid feed pipe to the flow path of a rotating part in a fluid feeding mechanism that feeds a coolant or other fluid to a rotating part that is rotating during operation, such as a spindle of a machine tool A rotary joint is used. The rotary joint is a seal of a rotary seal mounted on each facing end face, with a rotating shaft coupled to the rotating part and a fixed shaft connected to the fluid supply pipe arranged coaxially and facing each other in the axial direction. It is the structure which prevents the leakage of a fluid by sticking a surface mutually. With this configuration, a fluid having a predetermined pressure and a predetermined flow rate is continuously supplied from the fluid supply pipe to the rotating portion in a rotating state via the rotary joint. In such a rotary joint, it is necessary to move the fixed shaft side in the axial direction in order to bring the sealing surface into close contact. For this reason, the fixed shaft is slidably fitted in a fitting hole provided in the casing portion or the like, and a sealing member such as an O-ring interposed between the inner periphery of the fitting hole and the fixed shaft. Thus, fluid leakage from the sliding gap is prevented.

  By the way, the fluid to be supplied by the rotary joint often contains foreign matter such as minute cutting waste such as coolant circulated in the machine tool. For this reason, it is inevitable that these foreign substances enter the sliding gap between the fixed shaft and the fitting hole in the process of continuously supplying the fluid. If these foreign substances repeatedly enter, they will accumulate and adhere in the sliding gap, and the smooth sliding of the fixed shaft will be hindered. As a result, the rotary joint will not operate normally, causing problems such as a large amount of fluid leakage Arise. Therefore, in order to detect such a problem, a rotary joint having a function of detecting leakage from the joint portion has been proposed (see Patent Document 1). In the prior art example shown in Patent Document 1, a flow sensor is provided in a drain pipe for discharging leakage coolant from a rotary joint, and an alarm is output when the coolant flow rate in the drain pipe exceeds a set value.

Japanese Patent Laid-Open No. 11-179631

  However, the above-described prior art has the following drawbacks. In the prior art, only the fact that the coolant flow rate in the drain pipe exceeds the set value by an alarm is issued, and the state of the sliding state of the fixed shaft into the fitting hole is determined. No useful information to guess was provided. That is, the rotary joint has a service life and requires replacement of consumable parts such as a fixed shaft at an appropriate timing. However, the usable life is not constant depending on the situation in which the rotary joint is used, for example, the state of contamination of foreign matters contained in the coolant, and it is not always appropriate to periodically replace it at preset intervals. For this reason, there has been a demand for a method for simply and objectively detecting a change in the sliding state due to the use of the rotary joint.

  The present invention has been made in view of such a problem, and it is simple and objective to observe a change in a sliding state caused by a foreign substance invading into a sliding gap between a fixed shaft portion and a fitting hole to be accumulated and solidified. An object of the present invention is to provide a rotary joint and a fluid feed mechanism that can be detected automatically.

  The rotary joint of the present invention is formed by coaxially arranging a rotating portion provided with an axial rotation flow path and mounted on the rotation shaft and a fixed portion provided with an axial fixed flow path, and is supplied from a fluid supply source. A rotary joint that feeds the fluid to be rotated to the rotation flow path of the rotation unit that rotates about the axis through the fixed flow path, and is provided in the rotation unit, and the rotation flow path is open at a side end surface. The rotation seal portion having one sealing surface and the axial movement of the fixed flow path are allowed while maintaining a predetermined sliding clearance in a fitting hole formed in the holding member and penetrating in the axial direction. And a fixed seal portion having a second seal surface with the fixed flow path opened on one side end surface thereof, and the fitting hole from the fluid supply source. The fluid is supplied to the inside and the fixed shaft portion is lowered by the fluid force. The first sealing surface and the second sealing surface are brought into close contact with each other to form a surface sealing portion, and a detection hole into which a detection member that moves together with the fixed sealing portion is fitted; The sliding state of the fixed shaft portion fitted in the fitting hole is measured by measuring the flow rate of the air flowing out through the detection hole from the pressurized space to which a predetermined air pressure is applied. A sliding state detection unit used for detection, and the detection member includes an inner hole which is longitudinally opened in the longitudinal direction and is open to the outside, and an outer peripheral surface provided on the upstream side of the inner hole and the inner hole. And the pressurizing space includes a first enlarged diameter portion provided on the upstream side of the detection hole and a piping portion for applying air pressure to the first enlarged diameter portion. In the state where the detection member is located on the upstream side, the inner hole is The communicating state is communicated with the first diameter-expanded portion through the communication port, the detection member moves to the downstream side along with the movement of the fixed seal portion, and the communication port is located inside the detection hole. In the state, the communication port is in a cut-off state in which communication with the first enlarged-diameter portion is interrupted, and in the communication state and the cut-off state, the detected value of the flow rate is an upper value and a lower value, respectively, and the sliding state detection The part detects the sliding state when the fixed shaft part is pressed downstream.

  The rotary joint of the present invention is formed by coaxially arranging a rotating portion provided with an axial rotation flow path and mounted on the rotation shaft and a fixed portion provided with an axial fixed flow path, and is supplied from a fluid supply source. A rotary joint that feeds the fluid to be rotated to the rotation flow path of the rotation unit that rotates about the axis through the fixed flow path, and is provided in the rotation unit, and the rotation flow path is open at a side end surface. The rotation seal portion having one sealing surface and the axial movement of the fixed flow path are allowed while maintaining a predetermined sliding clearance in a fitting hole formed in the holding member and penetrating in the axial direction. And a fixed seal portion having a second seal surface with the fixed flow path opened on one side end surface thereof, and the fitting hole from the fluid supply source. The fluid is supplied to the inside and the fixed shaft portion is lowered by the fluid force. The first sealing surface and the second sealing surface are brought into close contact with each other to form a surface sealing portion, and a detection hole into which a detection member that moves together with the fixed sealing portion is fitted; The sliding state of the fixed shaft portion fitted in the fitting hole is measured by measuring the flow rate of the air flowing out through the detection hole from the pressurized space to which a predetermined air pressure is applied. A sliding state detection unit used for detection, and the detection member includes an inner hole which is longitudinally opened in the longitudinal direction and is open to the outside, and an outer peripheral surface provided on the upstream side of the inner hole and the inner hole. And a pipe part that constitutes the pressurized space is connected to the upstream side, and a second enlarged diameter part is formed on the downstream side, and the detection hole A member is positioned on the upstream side, and the communication port is positioned inside the detection hole. In this state, the communication port is in a cut-off state in which communication with the second enlarged diameter portion is interrupted, and the inner hole is in a state in which the detection member moves downstream as the fixed seal portion moves. Is in a communication state communicating with the second enlarged diameter portion via the communication port, and in the blocking state and the communication state, the detected values of the flow rate are lower values and upper values, respectively, and the sliding state detection unit is The sliding state when the fixed shaft portion is pressed downstream is detected.

  A fluid feeding mechanism according to the present invention is a fluid feeding mechanism that feeds a fluid supplied from a fluid supply source to a rotating flow path that rotates about an axis by the rotary joint according to claim 3. An air pressure supply source for applying an air pressure of the predetermined pressure to the pressurizing space; a flow rate sensor for measuring a flow rate of air flowing out from the pressurizing space through the detection hole; and Based on the flow rate pattern data detected in a time series, a data processing unit that performs a process of determining the sliding state of the fixed shaft portion, and a notification unit that notifies the determination result of the data processing unit.

  According to the present invention, it is possible to easily and objectively detect a change in a sliding state caused by a foreign substance entering a sliding gap between the fixed shaft portion and the fitting hole and accumulating and solidifying.

Sectional drawing of the rotary joint in one embodiment of this invention Operational explanatory diagram of a rotary joint in an embodiment of the present invention Structure explanatory drawing of the 1st Example of the sliding state detection part with which the rotary joint in one embodiment of this invention was equipped The block diagram which shows the structure of the fluid feed mechanism using the rotary joint in one embodiment of this invention Operation | movement explanatory drawing of the sliding state detection part of 1st Example with which the rotary joint in one embodiment of this invention was equipped The graph which shows the flow volume pattern data acquired by the sliding state detection part of 1st Example in one embodiment of this invention. Structure explanatory drawing of 2nd Example of the sliding state detection part with which the rotary joint in one embodiment of this invention was equipped Operation | movement explanatory drawing of the sliding state detection part of 2nd Example with which the rotary joint in one embodiment of this invention was equipped The graph which shows the flow volume pattern data acquired by the sliding state detection part of 2nd Example in one embodiment of this invention.

  Next, embodiments of the present invention will be described with reference to the drawings. First, the overall configuration of the rotary joint 1 will be described with reference to FIGS. In FIG. 1, a rotary joint 1 is used in a fluid supply mechanism that feeds a cooling fluid to a rotating shaft such as a spindle shaft of a machine tool, and a rotating portion 1a provided with an axial rotating flow path. And the fixing | fixed part 1b provided with the axial fixed flow path is coaxially arranged and comprised.

  The rotating portion 1a is fastened to a flow passage hole 2a of a spindle shaft 2 that is a rotating shaft. The spindle shaft 2 is driven to rotate by a motor built in the spindle and rotates about an axis A, and is also clamped / unfastened. Advancing and retreating in the axial direction is performed by the clamp cylinder. The fixed portion 1b is fixedly mounted in a mounting hole 3a provided in the casing 3 in communication with the flow path hole 3b via a housing member 7 as a holding member, and a frame (not shown) through which the spindle shaft 2 is inserted. ), The fixing portion 1b is arranged coaxially with the rotating portion 1a. A fluid to be supplied such as a liquid coolant and cooling air is supplied to the flow path hole 3b from the fluid supply source 20.

  Next, the detailed structure of each part will be described. The rotating part 1a is mainly composed of a rotor 4 mounted on the spindle shaft 2. The rotor 4 is provided with a flange part 4b having an outer diameter larger than that of the rotating shaft part 4a at one end of the rotating shaft part 4a. It has a shape in which a rotational flow path 4e is provided in the axial direction at the center. A male screw portion 4d is provided on the outer surface of the rotating shaft portion 4a, and a female screw portion 2b is provided on the inner surface of the flow path hole 2a. By screwing the male screw portion 4d into the female screw portion 2b, the rotor 4 is screwed to the spindle shaft 2, and the screw fastening portion is sealed by the O-ring 6. As a result, the rotating flow path 4 e communicates with the flow path hole 2 a of the spindle shaft 2.

  A circular recess 4c is formed on the side end surface of the right side of the rotor 4 (the side facing the fixed portion 1b) so as to surround the opening surface of the rotating flow path 4e. The recess 4c has a first seal. The ring 5 is fixed. The first seal ring 5 is formed by molding a hard material rich in wear resistance such as ceramic into an annular shape having an opening 5a in the center, and the first seal surface 5b finished to be a smooth surface. It fixes to the recessed part 4c in the state made into the outer surface side. In this state, the rotating flow path 4e communicates with the opening 5a and opens to the first seal surface 5b. In the above configuration, the rotor 4 to which the first seal ring 5 is fixed is a rotary seal portion having a first seal surface 5b provided in the rotary portion 1a and having a rotary flow path 4e opened on a side end surface.

  Next, the structure of the fixing portion 1b attached to the casing 3 will be described. The fixed portion 1 b is configured such that the floating sheet 8 is attached to the housing member 7. A mounting hole 3a provided in communication with the flow path hole 3b is opened on the mounting surface 3c of the casing 3, and a cylindrical housing member 7 constituting the main body of the fixed portion 1b is fitted into the mounting hole 3a. To do. The housing member 7 is bolted to a screw hole (not shown) provided in the mounting surface 3 c, and the fitting portion to the mounting hole 3 a is sealed by the O-ring 11.

  The floating sheet 8 is provided with a disk-shaped flange portion 8b on one side (the side facing the rotating portion 1a in the drawing), and a fixed shaft portion formed with a fixed passage 8e penetrating in the axial direction on the other side. The shape has 8a. A second seal ring 9 is fixed in a convex portion 8c provided in a circular bank shape on the left side of the flange portion 8b (an end surface facing the rotating portion 1a). The second seal ring 9 is formed by molding a hard material similar to that of the first seal ring 5 into an annular shape having an opening 9a in the center, and the second seal surface 9b finished to be a smooth surface. It is fixed to the flange portion 8b in the state of being on the outer surface side. In this state, the fixed flow path 8e communicates with the opening 9a and opens to the second seal surface 9b.

  The fixed shaft portion 8a is fitted in a fitting hole 7a provided through the central portion of the housing member 7 in the axial direction in a state where movement in the axial direction is allowed. In other words, depending on the shape / dimension setting of the fitting hole 7a and the fixed shaft portion 8a, a sliding gap (shown in the figure) between the inner peripheral surface 7b of the fitting hole 7a and the outer peripheral surface 8d of the fixed shaft portion 8a. (Omitted) is secured. In the sliding gap, a seal member 12 is mounted on the inner peripheral surface of the fitting hole 7a. The seal member 12 has a function of sealing the fluid flow in the sliding gap while allowing the fixed shaft portion 8a to move in the fitting hole 7a.

  In the fluid feeding operation by the rotary joint 1, the floating sheet 8 advances and retreats in the axial direction toward the rotating portion 1a. The flange portion 8b is provided with a guide mechanism for guiding the forward / backward movement of the floating seat 8. That is, the flange portion 8b is provided with a bolt 16 and a cylindrical collar 17 that encloses the bolt 16, and the housing member 7 is provided with a guide hole 7d (see FIG. 2) in the axial direction. When the floating sheet 8 advances and retreats in the axial direction, the cylindrical collar 17 slides in the guide hole 7d, whereby the movement of the floating sheet 8 in the axial direction is guided and the rotation around the shaft is prevented.

  In the above configuration, the floating sheet 8 to which the second seal ring 9 is fixed is allowed to move in the axial direction in the fitting hole 7a provided in the housing member 7 which is a holding member having a fixed flow path formed in the axial direction. This is a fixed seal portion having a fixed shaft portion 8a that fits in a closed state and having a second seal surface 9b having a fixed flow path 8e opened on the side end surface. In the present embodiment, the floating sheet 8 is mounted on the casing 3 via the housing member 7 as a holding member. However, the floating sheet 8 may be mounted directly on the casing 3.

  In the housing member 7, a sliding state detection unit 13 is disposed at a position axially symmetric with the above-described guide mechanism. The sliding state detector 13 is used to detect the sliding state of the fixed shaft portion 8a fitted in the fitting hole 7a. The sliding state detection unit 13 includes a detection member 15 that moves together with the floating sheet 8 that is a fixed seal portion. The detection member 15 is fitted in a detection hole 14a (see FIG. 3) provided in the detection block 14, and a first enlarged diameter portion 14b having an enlarged inner diameter is provided on the upstream side of the detection hole 14a. . The first enlarged diameter portion 14b is connected to an air pressure supply source 21 via a piping portion 3d provided in the casing 3, and a flow rate sensor 22 is connected to the piping portion 3d.

  By supplying an air pressure of a predetermined pressure to the first enlarged diameter portion 14b via the piping portion 3d by the air pressure supply source 21, an air pressure of a predetermined pressure is applied to the first enlarged diameter portion 14b. That is, the first diameter-expanded portion 14b and the piping portion 3d constitute a pressurized space that communicates with the detection hole 14a and is given a predetermined air pressure. In the present embodiment, the sliding state of the fixed shaft portion 8a fitted in the fitting hole 7a is detected by measuring the flow rate of air flowing out from the pressurized space through the detection hole 14a. It has become.

  Next, the operation of the rotary joint 1 will be described with reference to FIG. The fluid to be fed is supplied into the fitting hole 7a through the flow path hole 3b, and further flows into the fixed flow path 8e, whereby the fluid pressure of this fluid is changed to the upstream side end surface of the fixed shaft portion 8a. Act on. As a result, the fixed shaft portion 8a slides toward the rotating portion 1a in the fitting hole 7a, and the second seal ring 9 has a projected area of the side end surface of the fixed shaft portion 8a with respect to the first seal ring 5. It is pressed by the fluid force of the magnitude multiplied by the fluid pressure. This fluid force brings the second seal surface 9b and the first seal surface 5b into close contact with each other, thereby preventing leakage of the fluid fed from the fixed flow path 8e to the rotating flow path 4e rotating around the axis. A face seal portion 10 to be prevented is formed.

  When the floating sheet 8 is slid in the axial direction, the bolt 16 screwed to the flange portion 8 b and the cylindrical collar 17 that encloses the bolt 16 slide in the guide hole 7 d provided in the housing member 7 in the axial direction. As a result, the movement of the floating sheet 8 in the axial direction is guided and the rotation around the axis is prevented.

  In the operating state of the rotary joint 1, the sealing surface of the face seal portion 10 is brought into and out of contact with the advancement of the floating sheet 8 due to the pressure of the supplied fluid and the advancement and retraction operation of the spindle shaft 2. That is, in the state where the floating sheet 8 is moved backward and the first seal surface 5b and the second seal surface 9b are separated from each other, the fluid force is supplied to the flow path hole 3b, so that the fluid force is fixed to the fixed shaft portion. It acts on the side end face of 8a and presses in the axial direction. As a result, the floating sheet 8 moves forward (in the direction of arrow a), and the first seal surface 5b and the second seal surface 9b come into contact with each other and are brought into close contact with each other to form the surface seal portion 10. The fluid is supplied from the fixed flow path 8e to the rotating flow path 4e in the rotating state in this state.

  When the spindle shaft 2 moves forward (arrow d direction) relative to the fixed portion 1b, the floating seat 8 moves backward (arrow b direction), and the flange portion 8b returns to a position close to the housing member 7. . Then, by relatively retreating the spindle shaft 2 (in the direction of the arrow c) from this state, the first seal surface 5b and the second seal surface 9b are returned to a separated state.

  As described above, in order for the rotary joint 1 to function normally, the floating seat 8 and the spindle shaft 2 are required to smoothly contact and separate. In the contact / separation operation of the floating sheet 8 and the spindle shaft 2, the process of moving the floating sheet 8 forward by the fluid force is most easily influenced by the accumulation of foreign matters in the sliding gap. When a sliding failure occurs in the forward process of the floating sheet 8, a good surface seal portion 10 in which the first seal surface 5b and the second seal surface 9b are in close contact with each other is not formed. This causes a serious problem that leaks in large quantities.

  In the present embodiment, the above-described sliding state detection unit 13 is provided in the rotary joint 1 in order to detect the occurrence of such a failure in a timely manner and to appropriately detect a precursor of the failure. ing. In the fluid feeding operation by the rotary joint 1, the sliding state detection unit 13 detects the sliding state when the fixed shaft portion 8a of the floating sheet 8 is pressed downstream.

  Hereinafter, the detailed configuration and function of the sliding state detection unit 13 provided for such a purpose will be described with reference to FIGS. First, the structure of the sliding state detector 13 will be described with reference to FIG. In FIG. 3A, the detection block 14 is stored in the storage hole 7 c formed in the housing member 7. A detection member 15 coupled to the flange portion 8b of the floating sheet 8 is slidably fitted in a detection hole 14a formed by inserting the detection block 14 in the longitudinal direction (upstream to downstream direction). When the floating sheet 8 moves forward / backward, the detection member 15 also slides in the detection hole 14a.

  In the fitting portion where the detection block 14 is fitted into the storage hole 7c, the dimension is set so that a predetermined fitting gap Δd is secured between the inner peripheral surface 7e of the storage hole 7c and the outer peripheral surface 14c of the detection block 14. Has been. As a result, the detection block 14 is allowed to slightly swing in the direction perpendicular to the axis within the storage hole 7c. That is, in the operation in which the fixed shaft portion 8a fitted into the fitting hole 7a with a fitting gap is moved forward and backward while slightly swinging, the detection member 15 coupled and moved through the flange portion 8b is fixed to the fixed shaft portion. The same swinging as that of 8a is allowed.

  The detection member 15 is provided with an inner hole 15a which is vertically open in the longitudinal direction and whose downstream side is open to the outside. On the upstream side of the inner hole 15a, a communication port 15b that connects the outer peripheral surface of the detection member 15 and the inner hole 15a is provided. The upstream side of the detection hole 14a is a first enlarged portion 14b having an enlarged diameter, and a pipe portion 3d formed in the casing 3 is opened in the first enlarged portion 14b. The piping part 3d is connected to the pneumatic supply source 21 shown in FIG. Thereby, an air pressure of a predetermined pressure can be applied in the first enlarged diameter portion 14b which is a pressurized space. The air pressure that has entered the fitting gap is sealed by the seal member 14d, and leakage to the outside is prevented.

  In the above configuration, the flow rate of the air flowing into the first enlarged diameter portion 14b that is the pressurized space via the flow rate sensor 22 is equal to the flow rate of the air flowing out through the detection hole 14a. Therefore, the flow rate of the air flowing out from the pressurized space can be obtained by measuring the flow rate with the flow rate sensor 22.

  The position of the communication port 15b moves within the detection block 14 due to the movement of the detection member 15 as the floating sheet 8 moves forward and backward. As a result, communication / blocking of the pneumatic inner hole 15a supplied via the pipe portion 3d is switched. That is, as shown in FIG. 3B, in the state where the detection member 15 is located on the upstream side, the inner hole 15a communicates with the pipe portion 3d and the first enlarged diameter portion 14b via the communication port 15b. Become. In this communication state, the air pressure supplied from the air pressure supply source 21 via the pipe portion 3d flows into the inner hole 15a via the communication port 15b and is released to the outside. In this flow path, the flow path resistance is small, and therefore the detected value of the flow rate by the flow sensor 22 is an upper value (Q1) corresponding to a relatively large flow rate.

  On the other hand, as shown in FIG. 3C, when the detection member 15 moves to the downstream side with the movement of the floating sheet 8 which is the fixed seal portion, the communication port 15b is positioned inside the detection hole 14a. It becomes a blocked state. In this state, the communication port 15b is disconnected from the first enlarged diameter portion 14b, and the inner hole 15a is disconnected from the piping portion 3d. In this shut-off state, the air pressure supplied from the air pressure supply source 21 via the piping part 3d remains in the first diameter-expanding part 14b without being discharged to the outside via the communication port 15b. Therefore, the flow rate of the air flowing out from the first enlarged diameter portion 14b through the detection hole 14a is small, and the detected value of the flow rate by the flow sensor 22 is a lower value (Q2) that is significantly smaller than the upper value (Q1). .

  Next, the configuration of the fluid feeding mechanism in the present embodiment will be described with reference to FIG. This fluid feeding mechanism has a function of feeding the fluid supplied from the fluid supply source 20 to the equipment 23 such as a machine tool by the rotary joint 1 in which the sliding state detection unit 13 is incorporated.

  In FIG. 4, a fluid such as a coolant supplied from the fluid supply source 20 is fed via a rotary joint 1 to a rotating flow path that rotates around an axis in an equipment 23. The rotary joint 1 includes a sliding state detection unit 13, and a predetermined pressure of air pressure is applied to the preload space of the sliding state detection unit 13 by the air pressure supply source 21 through the flow sensor 22. Here, the measured value of the flow rate by the flow rate sensor 22 corresponds to the detected value of the flow rate of the air flowing out from the preload space of the sliding state detection unit 13 through the detection hole 14a as described above. The detected value of the flow rate measured and detected by the flow rate sensor 22 is taken in by the equipment side control unit 23 a attached to the equipment 23.

  The facility-side control unit 23a includes a data processing unit 24 that processes the captured data. The data processing unit 24 is based on flow rate pattern data (see FIG. 6) in which the flow rate of air flowing out of the preload space through the detection hole 14a is detected in time series by the flow rate sensor 22 (see FIG. 6). The process which judges the sliding state of the part 8a is performed. The determination result by the data processing unit 24 is notified by a notification unit 25 such as a display panel.

  It is essential that the rotary joint 1 shown in the present embodiment is attached to a facility having the data processing unit 24 having the above-described function. Here, the data processing unit 24 does not need to be fixedly provided in the facility-side control unit 23a provided in the facility 23, and the portable data processing device such as a tablet terminal has the function of the data processing unit 24. You may make it let.

  Next, referring to FIG. 5 and FIG. 6, the flow sensor 22 flows out from the preload space through the detection hole 14 a in the operation of each part and the sliding state detection in the sliding state detection by the sliding state detection unit 13. The flow rate pattern data acquired by detecting the air flow rate in time series will be described.

  5 (a) to 5 (d) show each part of the sliding state detector 13 in one forward stroke in which the floating sheet 8 moves forward from the state shown in FIG. 1 and shifts to the state shown in FIG. The state is shown for each operation step. Here, in FIGS. 5A to 5D, the upstream end of the detection member 15 that moves together with the floating seat 8 has strokes L 0 (stopped), L 1, L 2, L 3 from the end surface of the casing 3, respectively. Only shows the state of advance.

  In FIG. 6, flow rate pattern data acquired in a plurality of states in which the sliding state of the fixed shaft portion 8a of the floating sheet 8 is different are shown in FIGS. 6 (a), 6 (b), and 6 (c), respectively. That is, FIG. 6A is flow rate pattern data obtained when the sliding state of the fixed shaft portion 8a is normal and a smooth sliding operation is ensured. FIG. 6B shows flow rate pattern data obtained when the fixed shaft portion 8a is fixed by a foreign matter or the like that has entered the sliding gap in the fitting hole 7a, resulting in an abnormal state in which the forward movement is not performed. is there. Further, FIG. 6C shows flow rate pattern data that is a precursor of an abnormal state in which the forward movement of the fixed shaft portion 8a is performed but the moving speed is slower than that in a normal state.

  Hereinafter, the sliding state detection shown in FIG. 5 will be described with reference to FIG. 6A showing the flow rate pattern data during normal operation. First, FIG. 5A shows a state shown in FIG. 1, that is, a state in which the floating seat 8 is retracted and the second seal ring 9 of the fixed portion 1b is separated from the first seal ring 5 of the rotating portion 1a. Yes. In this state, since the floating sheet 8 is in the position retracted to the upstream side, the detection member 15 that moves together is also located on the upstream side.

  That is, the upstream end of the detection member 15 is at the upstream end of the first enlarged diameter portion 14b (stroke L0), and the communication port 15b is in the first enlarged diameter portion 14b. This state corresponds to the communication state shown in FIG. 3B. Therefore, in this state, the detected value by the flow sensor 22 is the above-described upper value, and in FIG. 6A, the detected value of the flow rate at the timing t0 is The flow rate is Q1 (upper value).

  FIG. 5B shows that the leading end of the communication port 15b is detected at timing t1 when the advancement of the floating sheet 8 is started at time t0 (arrow e) and the detection member 15 is advanced by the stroke L1 accordingly. The state which reached | attained the step part of the hole 14a is shown. In this state, the communication port 15b is still open in the first enlarged diameter portion 14b, and the above-described flow rate Q1 (upper value) is maintained as the detection value by the flow rate sensor 22.

  FIG. 5C shows a state in which the detection member 15 has further advanced from this state (arrow f) and the communication port 15b has completely entered the detection hole 14a. In the process of entering the communication port 15b, the air flowing out from the pressurized space including the first enlarged diameter portion 14b as the degree to which the communication port 15b is blocked by the inner peripheral surface of the detection hole 14a increases. The flow rate decreases. Then, at a timing t2 corresponding to an intermediate stroke between the stroke L1 and the stroke L2, as shown in FIG. 6A, the detected value of the flow rate by the flow rate sensor 22 decreases to the aforementioned flow rate Q2 (lower value).

  Thereafter, as shown in FIG. 5 (d), when the floating sheet 8 further advances (arrow g), the second seal ring 9 comes into contact with the first seal ring 5 at timing t3, and the face seal portion. 10 (FIG. 2) is formed. In this state, as shown in FIG. 6A, the flow rate Q2 (lower value) is maintained between the timing t2 and the timing t3.

  In FIG. 6A, a first time T1 from timing t0 to timing t1 and a second time T2 from timing t1 to timing t2 are the sliding states of the fixed shaft portion 8a in the rotary joint 1 to be detected. It is a characteristic parameter indicating the characteristic. That is, the first time T1 is a parameter indicating the ease of activation from the stationary state to the movement. The second time T2 is a transition time required for transition from the communication state defined in FIG. 3 to the cutoff state, and is a parameter indicating the speed of acceleration after startup.

  For the rotary joint 1 of each model, the quality of the sliding state is judged based on the flow rate pattern data obtained by actually moving the floating seat 8 under standard operating conditions with good maintenance. A reference parameter as a reference is obtained. When the fluid feeding mechanism having the configuration shown in FIG. 4 is in operation, the flow rate pattern data detected by the sliding state detection means combining the sliding state detection unit 13 and the flow rate sensor 22 is compared with the above-described reference parameter. The quality of the sliding state is judged.

  These data processing and determination are executed by the function of the data processing unit 24, and the determination result is notified by the notification unit 25. That is, the data processing unit 24 obtains the second time T2, which is the above-described transition time, from the flow rate pattern data, and determines the sliding state of the fixed shaft portion 8a based on the transition time. The processing function of the data processing unit 24 is the same in the second embodiment described later.

  FIG. 6B shows flow rate pattern data in an abnormal state where the fixed shaft portion 8a is in a fixed state and does not start from a stationary state. In this case, since the floating sheet 8 is in a stationary state together with the detection member 15, the sliding state detection unit 13 remains in the state shown in FIG. 5A, and the value detected by the flow sensor 22 is the timing t0. Thereafter, the flow rate Q1 (upper value) continues. In such a case, the data processing unit 24 determines that the rotary joint 1 is in an abnormal state that causes a large amount of fluid to leak, and notifies the information by the notification unit 25. Then, the operator who receives this notification performs necessary measures such as replacement of parts.

  Further, in the flow rate pattern data at the sign of the abnormal state shown in FIG. 6C, the first time T1 * from the timing t0 to the timing t1 and the second time T2 * from the timing t1 to the timing t2 are both. It is in a form delayed from the reference parameter shown in FIG. That is, in the fixed shaft portion 8a, the adhesion of the foreign matter into the sliding gap proceeds to some extent and the smooth movement of the fixed shaft portion 8a is hindered, resulting in a delay in operation time. If the first time T1 * and the second time T2 * exceed a preset warning value, the data processing unit 24 notifies the notification unit 25 of that fact. Then, the operator who receives this notification performs necessary measures such as cleaning and replacement of parts.

  Next, the configuration and function of the sliding state detection unit 13A of the second example of the present embodiment will be described with reference to FIGS. In the sliding state detection portion 13A of the second embodiment, the second diameter is formed downstream of the detection hole 14a in place of the first enlarged diameter portion 14b provided on the upstream side of the detection hole 14a in the first embodiment. The enlarged diameter portion 14e is provided. The sliding state detection unit 13A also has the same function as the sliding state detection unit 13, and is used by being incorporated in the rotary joint 1 constituting the fluid supply mechanism shown in FIG.

  First, the structure of the sliding state detector 13A will be described with reference to FIG. In FIG. 7A, the detection block 14 is stored in the storage hole 7 c formed in the housing member 7. A detection member 15 coupled to the flange portion 8b of the floating sheet 8 is slidably fitted in a detection hole 14a formed by inserting the detection block 14 in the longitudinal direction (upstream to downstream direction). When the floating sheet 8 moves forward / backward, the detection member 15 also slides in the detection hole 14a.

  In the fitting portion where the detection block 14 is fitted into the storage hole 7c, a fitting gap Δd similar to that of the first embodiment is ensured between the inner peripheral surface 7e of the storage hole 7c and the outer peripheral surface 14c of the detection block 14. Are dimensioned to be As a result, the detection block 14 is allowed to slightly swing in the direction perpendicular to the axis within the storage hole 7c. That is, in the operation in which the fixed shaft portion 8a fitted into the fitting hole 7a with a fitting gap is moved forward and backward while slightly swinging, the detection member 15 coupled and moved through the flange portion 8b is fixed to the fixed shaft portion. The same swinging as that of 8a is allowed.

  The detection member 15 is provided with an inner hole 15a which is vertically open in the longitudinal direction and whose downstream side is open to the outside. On the upstream side of the inner hole 15a, a communication port 15b that connects the outer peripheral surface of the detection member 15 and the inner hole 15a is provided. A downstream side of the detection hole 14a is a second enlarged diameter portion 14e having an enlarged diameter, and a pipe portion 3d formed in the casing 3 is opened on the upstream side of the detection hole 14a. The piping part 3d is connected to the pneumatic supply source 21 shown in FIG. Thereby, an air pressure of a predetermined pressure can be applied to the piping portion 3d which is a pressurized space. The air pressure that has entered the fitting gap is sealed by the seal member 14d, and leakage to the outside is prevented.

  In the above configuration, the flow rate of air flowing into the piping portion 3d, which is a pressurized space, through the flow rate sensor 22 is equal to the flow rate of air flowing out through the detection hole 14a. Therefore, the flow rate of the air flowing out from the pressurized space can be obtained by measuring the flow rate with the flow rate sensor 22.

  The position of the communication port 15b moves within the detection block 14 due to the movement of the detection member 15 as the floating sheet 8 moves forward and backward. As a result, communication / blocking of the pneumatic inner hole 15a supplied via the pipe portion 3d is switched. That is, as shown in FIG. 7B, when the detection member 15 is located upstream, the communication port 15b is located inside the detection hole 14a and is closed.

  In this state, the communication port 15b and the inner hole 15a are cut off from communication with the pipe portion 3d. In this shut-off state, the air pressure supplied from the air pressure supply source 21 via the piping portion 3d stays in the piping portion 3d without being released to the outside. Therefore, the flow rate of the air flowing out from the piping portion 3d which is the pressurized space through the detection hole 14a is small, and the detected value of the flow rate by the flow rate sensor 22 is the above-described lower value.

  On the other hand, as shown in FIG. 7C, when the detection member 15 moves to the downstream side with the movement of the floating sheet 8 that is the fixed seal portion, the communication port 15b communicates with the second enlarged diameter portion 14e. Move to the position you want. As a result, the inner hole 15a is in communication with the second enlarged diameter portion 14e and the piping portion 3d through the communication port 15b. In this communication state, the air supplied from the air pressure supply source 21 via the pipe portion 3d flows into the inner hole 15a via the communication port 15b and is released to the outside. Therefore, the detected value of the flow rate by the flow rate sensor 22 is an upper value that is larger than the lower value.

  Next, referring to FIG. 8 and FIG. 9, it is obtained by detecting the pressure of the flow sensor 22 in time series in the operation of each part in the sliding state detection by the sliding state detection unit 13 </ b> A and the sliding state detection. The flow pattern data will be described.

  8 (a) to 8 (d) show the operation steps of the states of the sliding state detector 13A in the forward stroke in which the floating sheet 8 advances from the state shown in FIG. 1 and shifts to the state shown in FIG. Shown for each. Here, in FIGS. 8A to 8D, the upstream end of the detection member 15 that moves together with the floating seat 8 has strokes L 0 (stopped), L 1, L 2, L 3 from the end surface of the casing 3, respectively. Only shows the state of advance.

  In FIG. 9, flow rate pattern data acquired in a plurality of states in which the sliding state of the fixed shaft portion 8 a of the floating sheet 8 is different are shown in FIGS. 9A, 9 </ b> B, and 9 </ b> C, respectively. That is, FIG. 9A shows flow rate pattern data obtained when the sliding state of the fixed shaft portion 8a is normal and a smooth sliding operation is ensured. FIG. 9B is flow rate pattern data obtained when the fixed shaft portion 8a is fixed by a foreign matter that has entered the sliding gap in the fitting hole 7a, resulting in an abnormal state in which the forward movement is not performed. . Further, FIG. 9C shows flow rate pattern data of a precursor of an abnormal state in which the moving speed of the fixed shaft portion 8a is slower than that in a normal state although the fixed shaft portion 8a is moving forward.

  Hereinafter, the sliding state detection shown in FIG. 8 will be described with reference to FIG. 9A showing the flow rate pattern data during normal operation. First, FIG. 8A shows the state shown in FIG. 1, that is, the state in which the floating seat 8 is retracted and the second seal ring 9 of the fixed portion 1b is separated from the first seal ring 5 of the rotating portion 1a. Yes. In this state, since the floating sheet 8 is in the position retracted to the upstream side, the detection member 15 that moves together is also located on the upstream side.

  That is, the upstream end of the detection member 15 is at the upstream end of the detection hole 14a (stroke L0), and the communication port 15b is positioned in the detection hole 14a. This state corresponds to the blocking state shown in FIG. Therefore, the detected value by the flow sensor 22 is the aforementioned lower value, and in FIG. 9A, the detected value of the flow rate at the timing t0 is the flow rate Q1 (lower value).

  FIG. 8B shows that the downstream end of the inner hole 15a is moved at the timing t1 when the advancement of the floating sheet 8 is started at the timing t0 (arrow h) and the detection member 15 is moved forward by the stroke L1 accordingly. The state which reached | attained the upstream end part of the 2nd diameter expansion part 14e is shown. As shown in FIG. 8C, when the detection member 15 moves downstream from this state (arrow i), inflow of air pressure from the detection hole 14a into the second enlarged diameter portion 14e is started.

  In this state, the communication port 15b is located in the second enlarged diameter portion 14e, and the air pressure that has flowed in is discharged to the outside through the communication port 15b and the inner hole 15a. Therefore, the detected value of the flow rate by the flow sensor 22 increases from the lower value. Then, at the timing t2 when the movement is performed by the predetermined stroke L2, the detection value by the flow sensor 22 converges to the flow rate Q2 (upper value) described above.

  Thereafter, as shown in FIG. 8D, when the floating sheet 8 further advances (arrow j), the second seal ring 9 comes into contact with the first seal ring 5 at the timing t3, and the face seal portion. 10 (FIG. 2) is formed. In this state, as shown in FIG. 9A, the flow rate Q2 (upper value) is maintained between the timing t1 and the timing t2.

  In FIG. 9A, a first time T1 from timing t0 to timing t1 and a second time T2 from timing t1 to timing t2 are the sliding states of the fixed shaft portion 8a in the rotary joint 1 to be detected. It is a characteristic parameter indicating the characteristic. That is, the first time T1 is a parameter indicating the ease of activation from the stationary state to the movement. The second time T2 is a parameter indicating the speed of acceleration after startup.

  For the rotary joint 1 of each model, the quality of the sliding state is judged based on the flow rate pattern data obtained by actually moving the floating seat 8 under standard operating conditions with good maintenance. A reference parameter as a reference is obtained. When the fluid feeding mechanism having the configuration shown in FIG. 4 is operated, the flow rate pattern data detected by the sliding state detection means combining the sliding state detection unit 13 and the flow rate sensor 22 is compared with the above-described reference parameter. The quality of the sliding state is judged. These data processing and determination are executed by the function of the data processing unit 24, and the determination result is notified by the notification unit 25.

  FIG. 9B shows flow rate pattern data in an abnormal state in which the fixed shaft portion 8a is in a fixed state and does not start from a stationary state. In this case, since the floating sheet 8 is in a stationary state together with the detection member 15, the sliding state detection unit 13A remains in the state shown in FIG. 8A, and the value detected by the flow sensor 22 is the timing t0. Thereafter, the pressure P2 (upper value) continues. In such a case, the data processing unit 24 determines that the rotary joint 1 is in an abnormal state that causes a large amount of fluid to leak, and notifies the information by the notification unit 25. Then, the operator who receives this notification performs necessary measures such as replacement of parts.

  Further, in the flow rate pattern data at the sign of the abnormal state shown in FIG. 8C, the first time T1 * from the timing t0 to the timing t1 and the second time T2 * from the timing t1 to the timing t2 are both. It is a form delayed from the reference parameter shown in FIG. That is, in the fixed shaft portion 8a, the adhesion of the foreign matter into the sliding gap proceeds to some extent and the smooth movement of the fixed shaft portion 8a is hindered, resulting in a delay in operation time. When the first time T1 * and the second time T2 * exceed a preset warning value, the data processing unit 24 notifies the notification unit 25 of that fact. Then, the operator who receives this notification performs necessary measures such as cleaning and replacement of parts.

  As described above, in the fluid feeding mechanism shown in the present embodiment, the fluid supplied from the fluid supply source 20 is fixed to the rotary joint 1 that feeds the rotating channel of the equipment 23 through the fixed channel. Sliding state detectors 13 and 13A used for detecting the sliding state of the fixed shaft portion 8a constituting the flow path are provided. The sliding state detection unit 13 includes a detection member 15 that moves together with the fixed shaft portion 8a and a detection hole 14a in which the detection member 15 is fitted, and includes a pressurizing space to which an air pressure of a predetermined pressure is applied. The pressure in the pressure space is detected by the flow sensor 22, and the detection result is processed by the data processing unit 24 to determine the sliding state of the fixed shaft portion 8a fitted in the fitting hole 7a. As a result, it is possible to easily and objectively detect a change in the sliding state caused by foreign matter entering the sliding gap between the fixed shaft portion 8a and the fitting hole 7a and being deposited and solidified.

  The rotary joint and fluid feed mechanism of the present invention can easily and objectively detect a change in the sliding state caused by foreign matter entering the sliding gap between the fixed shaft portion and the fitting hole and solidifying. This is useful for applications in which fluid such as liquid coolant or air is fed to a rotating part such as a spindle of a machine tool.

DESCRIPTION OF SYMBOLS 1 Rotary joint 1a Rotating part 1b Fixed part 2 Spindle shaft 3 Casing 4 Rotor 4e Rotating flow path 5 First seal ring 5b First seal surface 8 Floating sheet 8a Fixed shaft part 8e Fixed flow path 9 Second seal ring 9b 2nd sealing surface 10 Surface sealing part 13, 13A Sliding state detection part 14 Detection block 14a Detection hole 14b 1st enlarged diameter part 14e 2nd enlarged diameter part 15 Detection member 15a Inner hole 15b Communication port

Claims (5)

A rotating part provided with an axial rotation flow path and a fixed part provided with a fixed flow path in the axial direction and a fixed part provided with an axial fixed flow path are arranged coaxially, and fluid supplied from a fluid supply source is arranged around the axis. A rotary joint that feeds the rotating flow path of the rotating part to the rotating flow path via the fixed flow path;
A rotary seal portion having a first seal surface provided in the rotary portion and having the rotary flow channel open on a side end surface;
A fixed shaft portion that is fitted in a state in which the movement in the axial direction is allowed while maintaining a predetermined sliding gap in a fitting hole formed in the holding member, the fixed flow path penetrating in the axial direction; A fixed seal portion having a second seal surface with the fixed flow path opened on a side end surface on one side;
By supplying the fluid from the fluid supply source into the fitting hole and pressing the fixed shaft portion downstream by a fluid force, the first seal surface and the second seal surface are brought into close contact with each other. To form a face seal,
Furthermore, by measuring the flow rate of the air flowing out through the detection hole from the pressurized space that is communicated with the detection hole in which the detection member that moves together with the fixed seal portion is fitted and is given a predetermined pressure of air pressure, A sliding state detection unit used for detecting the sliding state of the fixed shaft portion fitted in the fitting hole,
The detection member has an inner hole that is vertically open in the longitudinal direction and a downstream side that is open to the outside, and a communication port that is provided on the upstream side of the inner hole and connects the outer peripheral surface and the inner hole.
The pressurizing space includes a first diameter-expanded portion provided on the upstream side of the detection hole and a pipe portion that applies air pressure to the first diameter-expanded portion,
In the state where the detection member is located on the upstream side, the inner hole is in a communication state communicating with the first enlarged diameter portion via the communication port,
In a state where the detection member moves downstream as the fixed seal portion moves and the communication port is located inside the detection hole, the communication port is disconnected from the first diameter-expanded portion. Shut off,
In the communication state and the shut-off state, the detected values of the flow rate are an upper value and a lower value, respectively.
The rotary joint according to claim 1, wherein the sliding state detection unit detects the sliding state when the fixed shaft portion is pressed downstream. A rotating part provided with an axial rotation flow path and a fixed part provided with a fixed flow path in the axial direction and a fixed part provided with an axial fixed flow path are arranged coaxially, and fluid supplied from a fluid supply source is arranged around the axis. A rotary joint that feeds the rotating flow path of the rotating part to the rotating flow path via the fixed flow path;
A rotary seal portion having a first seal surface provided in the rotary portion and having the rotary flow channel open on a side end surface;
A fixed shaft portion that is fitted in a state in which the movement in the axial direction is allowed while maintaining a predetermined sliding gap in a fitting hole formed in the holding member, the fixed flow path penetrating in the axial direction; A fixed seal portion having a second seal surface with the fixed flow path opened on a side end surface on one side;
By supplying the fluid from the fluid supply source into the fitting hole and pressing the fixed shaft portion downstream by a fluid force, the first seal surface and the second seal surface are brought into close contact with each other. To form a face seal,
Furthermore, by measuring the flow rate of the air flowing out through the detection hole from the pressurized space that is communicated with the detection hole in which the detection member that moves together with the fixed seal portion is fitted and is given a predetermined pressure of air pressure, A sliding state detection unit used for detecting a sliding state of the fixed shaft portion fitted in the fitting hole,
The detection member has an inner hole that is vertically open in the longitudinal direction and a downstream side that is open to the outside, and a communication port that is provided on the upstream side of the inner hole and connects the outer peripheral surface and the inner hole.
The detection hole is connected to a pipe part that constitutes the pressurized space on the upstream side, and a second diameter-expanded part is formed on the downstream side,
In the state where the detection member is located on the upstream side and the communication port is located inside the detection hole, the communication port is in a cut-off state in which communication with the second enlarged diameter portion is interrupted,
In a state where the detection member has moved to the downstream side with the movement of the fixed seal portion, the inner hole is in a communication state in communication with the second enlarged diameter portion via the communication port,
In the shut-off state and the communication state, the detected values of the flow rate are the lower value and the upper value, respectively.
The rotary joint according to claim 1, wherein the sliding state detection unit detects the sliding state when the fixed shaft portion is pressed downstream.   The rotary joint is attached to a facility having a data processing unit that performs a process of determining a sliding state of the fixed shaft portion based on flow rate pattern data in which the flow rate is detected in time series. Item 3. The rotary joint according to any one of Items 1 and 2.   The data processing unit obtains a transition time required for transition from the communication state to the shut-off state or from the shut-off state to the communication state from the flow rate pattern data, and based on the transition time, the fixed shaft portion The rotary joint according to claim 3, wherein a sliding state is determined. A fluid feed mechanism that feeds a fluid supplied from a fluid supply source to a rotary flow path that rotates about an axis by the rotary joint according to claim 3,
An air pressure supply source that applies the air pressure of the predetermined pressure to the pressurizing space, a flow rate sensor that measures a flow rate of air flowing out from the pressurizing space through the detection hole, and the flow rate by the flow rate sensor A data processing unit that performs processing for determining the sliding state of the fixed shaft portion based on flow rate pattern data detected in time series, and a notification unit that notifies a determination result by the data processing unit. A fluid delivery mechanism characterized by

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