JP5136356B2 - Fluid pressure coupler, shaft coupling device, and torque limiter - Google Patents

Description

  The present invention relates to a fluid pressure coupler, a shaft coupling device, and a torque limiter.

  Conventionally, as a shaft coupling device, there is one described in Japanese Utility Model Laid-Open No. 6-18733 (Patent Document 1).

  The shaft coupling device includes a shaft member and a flange member having an inner peripheral surface that frictionally engages with the outer peripheral surface of the shaft member, and the flange member has an annular hydraulic expansion chamber. The hydraulic expansion chamber exists so as to surround the inner peripheral surface.

  The shaft coupling device fills the hydraulic expansion chamber with oil, expands the hydraulic expansion chamber in the radial direction by the oil pressure of the oil, and reduces the diameter of the inner peripheral surface of the flange member. The shaft member and the flange member are connected by frictional engagement between the inner peripheral surface of the member and the outer peripheral surface of the shaft member.

  In such a background, there are fluid pressure couplers shown in FIGS. 3 and 4 for filling the hydraulic expansion chamber of the shaft coupling device with oil.

  As shown in FIG. 3, the fluid pressure coupler 200 includes a male coupler 260 and a female coupler 261, and the female coupler 261 is attached to the receiving structure 291 of the coupler connecting member 290, while the male coupler 260 is a female coupler 261. It is inserted into the coupler 261.

  The receptacle structure 291 has a bottomed hole 293 and an oil sealing passage 263 that opens to the peripheral surface of the hole 293, and the coupler connecting member 290 has a hydraulic expansion chamber (not shown). The oil sealing passage 263 of the receptacle structure 291 opens into the hydraulic expansion chamber.

  From the male coupler 260 connected to the female coupler 261, oil 262 for hydraulic expansion is sealed in a hydraulic expansion chamber (not shown) in the coupler connecting member 290 through the oil sealing passage 263. ing.

  As shown in FIG. 4, the female coupler 261 includes an upper connection portion 271, a lower connection portion 272, a first backup ring 274, a second backup ring 275, a first spacer 276, a second spacer 277, and a first O-ring 278. And a second O-ring 279.

  The upper connecting portion 271 and the lower connecting portion 272 are disposed in the hole 293 of the receiving port structure 291 of the coupler connecting member 290 having the hydraulic expansion chamber. The hole 293 has a cylindrical hole portion and a screw hole portion, and the inner diameter of the cylindrical hole portion is smaller than the inner diameter of the screw hole portion. The screw hole portion is located closer to the opening side of the hole than the cylindrical hole portion. The screw hole portion communicates with the cylindrical hole portion via a step portion 283. The lower connection portion 272 has a cup shape. The lower connecting portion 272 is disposed in the cylindrical hole portion with the opening side of the cup facing the opening side of the hole. The bottom portion of the lower connection portion 272 is in contact with the bottom portion of the hole 293. On the other hand, the upper connection portion 271 is a cylindrical member and has an external thread on the outer peripheral surface thereof. The upper connection portion 271 is disposed in the screw hole portion. The upper connection portion 271 is fixed to the screw hole by screwing. An end surface on the lower connection portion 272 side of the upper connection portion 271 is in contact with the step portion 283.

  One opening of the upper connection portion 271 is an opening of the lower connection portion 272 in a state where the upper connection portion 271 is in contact with the step portion 283 and the lower connection portion 272 is in contact with the bottom surface of the cylindrical hole portion. Opposite to. In this state, the central axis of the upper connecting portion 271 substantially coincides with the central axis of the lower connecting portion 272. Further, in this state, the upper connection portion 271 is located at a distance from the lower connection portion 272 in the axial direction of the upper connection portion 271.

  The hole of the upper connection portion 271 has an annular recess that opens to the lower connection portion 272 side. Specifically, the hole of the upper connecting portion 271 has a first cylinder inner peripheral surface and a second cylinder inner peripheral surface. The inner peripheral surface of the first cylinder is connected to the inner peripheral surface of the second cylinder via a step portion extending in the radial direction. The inner diameter of the inner peripheral surface of the first cylinder is smaller than the inner diameter of the inner peripheral surface of the second cylinder.

  As shown in FIG. 4, the first backup ring 274, the first O-ring 278, and the first spacer 276 are disposed in the annular recess. Specifically, the first backup ring 274, the first O-ring 278, and the first spacer 276 are fitted and fixed to the inner peripheral surface of the second cylinder of the upper connection portion 271 by press-fitting.

  The first O-ring 278 is sandwiched between the first backup ring 274 and the first spacer 276. The first backup ring 274 is in contact with the stepped portion. The first spacer 276 is located closer to the lower connection part 272 than the first O-ring 278.

  Further, the bottomed hole of the lower connection portion 272 has an annular recess that opens to the upper connection portion 271 side. Specifically, the bottomed hole of the lower connecting portion 272 has a first cylinder inner peripheral surface and a second cylinder inner peripheral surface. The inner peripheral surface of the first cylinder is connected to the inner peripheral surface of the second cylinder via a step portion extending in the radial direction. The inner diameter of the inner peripheral surface of the first cylinder is smaller than the inner diameter of the inner peripheral surface of the second cylinder.

  As shown in FIG. 4, the second backup ring 275, the second O-ring 279, and the second spacer 277 are disposed in the annular recess. Specifically, the second backup ring 275, the second O-ring 279, and the second spacer 277 are fitted and fixed to the inner peripheral surface of the second cylinder of the lower connection portion 272 by press-fitting. The second O-ring 279 is sandwiched between the second backup ring 275 and the second spacer 277. The second backup ring 275 is in contact with the step portion of the lower connection portion 272. The second spacer 277 is located closer to the upper connection portion 271 than the second O-ring 279.

  The first spacer 276 is located at a distance from the second spacer 277 in the axial direction of the first spacer 276.

  As described above, the oil sealing passage 263 opens on the side surface of the hole 293 of the fluid pressure coupler connecting member 290.

In the conventional fluid pressure coupler, since the oil sealing passage 263 is open to the side surface of the hole 293 of the fluid pressure coupler connecting member 290, the oil sealing passage is a bottomed hole of the receiving structure of the fluid pressure coupler connecting member. Compared to the case of opening at the bottom, the male coupler 260 (see FIG. 3) is less susceptible to the reaction force from the injected oil, and the male coupler 260 is less likely to come off the female coupler 261 during refueling. There is.
Japanese Utility Model Publication No. 6-18733

  3 and 4 has the advantage that the male coupler 260 is less likely to come off the female coupler 261 during refueling, while the first spacer 276 is inserted into the male coupler when the male coupler 260 is inserted. It may be dragged by 260 and may be displaced toward the opening of the oil sealing passage 263 to block the oil flow route and prevent oil injection. In addition, when the male coupler 260 is pulled out after the end of oiling, the second spacer 277 is displaced toward the opening of the oil sealing passage 263 to block the oil flow route, and the next oil injection is performed. At this time, the male coupler 260 may become difficult to insert or oil injection may be hindered. As a result, the oil preload in the hydraulic expansion chamber is unlikely to become a desired oil pressure, and the preload may not be sufficiently applied.

  Here, if the size management of the backup rings 274 and 275, the first O-rings 278 and 279, and the spacers 276 and 277 is severely performed in an attempt to avoid this problem, the yield of the fluid pressure coupler is reduced and the manufacturing cost is reduced. Increase.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a fluid pressure coupler in which a spacer does not hinder fluid injection at all and has a high manufacturing yield rate.

In order to solve the above problems, the fluid pressure coupler of the present invention is:
With a male coupler,
With a female coupler,
The female coupler is
A hole having a bottom and a fluid passage that opens to the inner peripheral surface of the hole, the hole being a small-diameter hole, and a screw hole that is larger in diameter than the small-diameter hole and located on the opening side of the hole A cup-shaped lower connection portion that is movably disposed in the small-diameter hole portion of the receiving structure of the fluid pressure coupler connection member having a portion with the opening facing the screw hole portion side;
A cylindrical upper connecting portion having an outer peripheral surface having a male screw screwed into the screw hole;
The through hole of the upper connection portion has an annular recess that opens to the lower connection portion side, and the first O-ring is disposed in the annular recess so that the first O-ring is sandwiched therebetween. An annular first spacer and an annular first backup ring are disposed;
The bottomed hole of the lower connection portion has an annular recess opening to the upper connection portion side, and a second O-ring is disposed in the annular recess so as to sandwich the second O-ring. The annular second spacer and the annular second backup ring are arranged,
The first spacer is located closer to the lower connection part than the first O-ring, and the second spacer is located closer to the upper connection part than the second O-ring.
The female coupler is located between the first spacer and the second spacer, and attaches the first spacer and the second spacer in a direction in which the distance between the first spacer and the second spacer increases. It is characterized by having a spring member for biasing.

  According to the present invention, the female coupler urges the first spacer and the second spacer between the first spacer and the second spacer in a direction in which the distance between the first spacer and the second spacer is increased. Since it has a spring member, even if the first spacer in the annular recess of the upper connection portion tries to move to the second spacer side by insertion of the male coupler, the spring member attaches it to the opening side of the hole of the receptacle structure. Therefore, the first spacer does not come out of the annular recess of the upper connection portion. Therefore, the first spacer does not block the fluid passage of the receiving structure of the fluid pressure coupler connecting member.

  Similarly, even if the second spacer in the annular recess of the lower connection portion tries to move toward the first spacer, the second spring member is biased toward the bottom surface side of the hole of the receptacle structure by the spring member. The spacer does not come out of the annular recess of the lower connection part. Therefore, the second spacer does not block the fluid passage of the receiving structure of the fluid pressure coupler connecting member. Therefore, since the first and second spacers do not prevent any fluid injection, a desired amount of fluid can be introduced into the fluid pressure expansion chamber, and a desired preload can be put into the fluid pressure expansion chamber.

  Further, the female coupler has a spring member that pushes the first spacer and the second spacer in the direction in which the distance between them increases, and the first spacer does not come out of the annular recess of the upper connection portion, Since the second spacer does not come out of the annular recess of the lower connection portion, it is not necessary to strictly manage the dimensions of the backup ring, the O-ring, and the spacer. Therefore, the yield of manufacturing the fluid pressure coupler can be greatly improved, and the manufacturing cost of the fluid pressure coupler can be reduced.

The shaft coupling device of the present invention is
A fluid pressure coupler connecting member having a peripheral surface;
A connecting member having a peripheral surface,
The fluid pressure coupler connecting member is
A fluid pressure expansion chamber;
The hole has a bottomed hole, a fluid passage communicating the inner peripheral surface of the hole and the fluid pressure expansion chamber, and the hole has a small-diameter hole and a larger diameter than the small-diameter hole. A receiving hole structure having a screw hole portion located on the opening side of the hole with respect to the small-diameter hole portion,
Comprising the fluid pressure coupler of the present invention connected to the receptacle structure;
The fluid pressure expansion chamber is expanded by the fluid sealed in the fluid pressure expansion passage via the fluid pressure coupler, whereby the peripheral surface of the fluid pressure coupler connecting member is changed to the peripheral surface of the connecting member. The fluid pressure coupler connecting member and the connecting member are frictionally coupled by pressing against each other.

  According to the present invention, since the fluid pressure coupler of the present invention is provided, it is easy to adjust the preload of the fluid pressure expansion chamber to a desired preload, and the frictional force of the friction engagement is easily and accurately adjusted to a desired magnitude. Can be adjusted.

The torque limiter of the present invention is
By expanding the fluid pressure expansion chamber with the fluid in the fluid pressure expansion chamber and frictionally coupling the fluid pressure coupler connection member and the connection member, the fluid pressure coupler connection member and the connection member Torque is transmitted between the fluid pressure expansion chamber and the fluid pressure coupler connecting member and the coupling member by releasing the frictional coupling between the fluid pressure coupler connecting member and the coupling member. It is characterized in that the transmission of torque with the member is released.

  According to the present invention, since the fluid pressure coupler of the present invention is provided, it is easy to adjust the preload of the fluid pressure expansion chamber to a desired preload, and the frictional force of the friction engagement is easily and accurately adjusted to a desired magnitude. Can be adjusted.

  According to the fluid pressure coupler of the present invention, the fluid passage through which the fluid is injected is not obstructed by the first and second spacers. Therefore, a desired amount of fluid can be introduced into the fluid pressure expansion chamber, and the preload in the fluid pressure expansion chamber can be set to a desired preload.

  Further, according to the fluid pressure coupler of the present invention, there is a spring member that pushes the first spacer and the second spacer in the direction in which the distance between them increases, so that the first spacer is an annular recess in the upper connecting portion. And the second spacer does not escape from the annular recess of the lower connection portion. Therefore, it is not necessary to severely manage the dimensions of the backup ring, the O-ring and the spacer, the yield of manufacturing the fluid pressure coupler can be greatly improved, and the manufacturing cost of the fluid pressure coupler can be reduced.

  Hereinafter, the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a schematic cross-sectional view in the axial direction of a torque limiter according to an embodiment of the present invention.

  This torque limiter includes a shaft member 1 as an example of a connecting member, a cylindrical member 2 as an example of a fluid pressure coupler connecting member, a shear valve 6, a ball bearing 17 and a ball bearing 18.

  The shaft member 1 includes a main body portion 8 having a substantially cylindrical outer peripheral surface 20, and a locking portion 9 having a substantially L-shaped cross section protruding from the outer surface of the main body portion 8. The outer peripheral surface 20 of the shaft member 1 has one spiral-shaped groove 35 for preventing oil sealing. The spiral groove 35 is open on both sides of the shaft member 1 in the axial direction. Further, the pitch of the spiral groove 35 is 1/5 or less of the shaft diameter (outer diameter) of the shaft member 1.

  The cylinder member 2 includes a first cylinder member 10 and a second cylinder member 11. The first cylindrical member 10 has a substantially cylindrical inner peripheral surface 21 that abuts on the outer peripheral surface 20 of the shaft member 1. Between the outer peripheral surface 20 of the shaft member 1 and the inner peripheral surface 21 of the first cylindrical member 10, a lubricant for preventing seizure is applied. The second cylindrical member 11 has a substantially cylindrical inner peripheral surface 24 that abuts on the substantially cylindrical outer peripheral surface 23 of the first cylindrical member 10. Further, the second cylinder member 11 has a hydraulic pressure extending in the axial direction of the substantially shaft member 1 over substantially the entire axial length of the shear valve mounting hole 30 and the inner peripheral surface 24 of the second cylinder member 11. An expansion chamber 26 is provided. The hydraulic expansion chamber 26 constitutes a fluid pressure expansion chamber.

  The shear valve 6 is fitted in the shear valve mounting hole 30. In a state where the shear valve 6 is fitted in the shear valve mounting hole 30, one end portion of the shear valve 6 protrudes outward in the radial direction from the outer peripheral surface of the second cylindrical member 11. The locking portion 9 having a substantially L-shaped cross section has a radially extending portion and an axially extending portion, and the radially extending portion extends substantially in the radial direction and is a second cylindrical member. 11 is opposed to the end face in the axial direction. The axially extending portion is connected to the radially extending portion and extends in the axial direction along the outer peripheral surface of the second cylindrical member 11. The one end portion of the shear valve 6 is locked with a clearance by the axially extending portion of the locking portion 9.

  The shear valve 6 has a tube 27 that is open only at one end. The tube 27 extends substantially in the radial direction of the shaft member 1 in a state where the shear valve 6 is fitted in the shear valve mounting hole 30. In addition, in a state where the shear valve 6 is fitted in the shear valve mounting hole 30, one end portion on the closed side of the tube 27 protrudes outward in the radial direction from the outer peripheral surface of the second cylindrical member 11. The opening of the tube 27 on the side opposite to the closed side communicates with one end of the hydraulic expansion chamber 26. The shear valve 6 side of the hydraulic expansion chamber 26 is a sealed space.

  As shown in FIG. 1, the second cylindrical member 11 has a receiving structure 33 for a fluid pressure coupler. The receptacle structure 33 has a hole 31 and an oil filled passage 32 as a fluid passage, and one end of the oil filled passage 32 is open to the side surface of the hole 31. As will be described in detail later, the receptacle structure 33 is provided with a female coupler (not shown in FIG. 1) of a fluid pressure coupler.

  When oil as an example of fluid is sealed in the hydraulic expansion chamber 26, the other end of the oil sealing passage communicates with the hydraulic expansion chamber 26. This torque limiter comprises a fluid pressure coupler, which has a male coupler identical to the male coupler shown at 260 in FIG. 3 and a female coupler (detailed in FIG. 2), It is fixed to the receptacle structure 33. In the torque limiter, when oil is sealed in the hydraulic expansion chamber 26, a male coupler is inserted into the female coupler fixed to the receiving port structure, and the male coupler is connected to the female coupler and the oil sealing passage 32. Oil is sealed in the hydraulic expansion chamber 26.

  The ball bearing 17 includes an inner ring 40 fitted and fixed to the outer surface of the shaft member 1, an outer ring 41 fitted and fixed to the inner surface of the second cylindrical member 11, a raceway surface of the inner ring 40, and a raceway surface of the outer ring 41. And a ball 42 disposed between them. The ball bearing 18 includes an inner ring 44 fitted and fixed to the outer surface of the shaft member 1, an outer ring 45 fitted and fixed to the inner surface of the first cylindrical member 10, a raceway surface of the inner ring 44, and the outer ring 45. And a ball 46 disposed between the raceway surfaces. The ball bearings 17 and 18 are configured to support the shaft member 1 so as to be rotatable with respect to the cylindrical member 2 when the shaft member 1 rotates relative to the cylindrical member 2.

  FIG. 2 is a view showing the female coupler 61 arranged in the receptacle structure 33.

  As shown in FIG. 2, the female coupler 61 includes an upper connecting portion 71, a lower connecting portion 72, a first backup ring 74, a second backup ring 75, a first spacer 76, a second spacer 77, a first O-ring 78, The second O-ring 79 and a corrugated annular washer 83 as an example of a spring member are provided.

  The upper connection portion 71 and the lower connection portion 72 are disposed in the hole 31 of the receiving port structure 33 of the cylindrical member 2 having the hydraulic expansion chamber 26 (see FIG. 1). The hole 31 has a cylindrical hole portion 98 as a small-diameter hole portion and a screw hole portion 99, and the inner diameter of the cylindrical hole portion 98 is smaller than the inner diameter of the screw hole portion 99. The screw hole 99 is located closer to the opening side of the hole 31 than the cylindrical hole 98. The screw hole portion 99 communicates with the cylindrical hole portion 98 through a step portion 83.

  The lower connecting portion 72 has a cup shape. The lower connection portion 72 is disposed in the cylindrical hole portion 98 with the cup opening side facing the opening side of the hole 31. The bottom portion of the lower connection portion 72 is in contact with the bottom portion of the hole 31. On the other hand, the upper connecting portion 71 is a cylindrical member and has an external thread on the outer peripheral surface thereof. The upper connection portion 71 is disposed in the screw hole 99. The upper connecting portion 71 is fixed to the screw hole 99 by screwing. The end surface on the lower connection portion 72 side of the upper connection portion 71 is in contact with the step portion 83.

  One opening of the upper connection portion 71 is an opening of the lower connection portion 72 in a state where the upper connection portion 71 is in contact with the step portion 83 and the lower connection portion 72 is in contact with the bottom surface of the cylindrical hole portion 98. Opposite to. In this state, the central axis of the upper connecting portion 71 substantially coincides with the central axis of the lower connecting portion 72. Further, in this state, the upper connecting portion 71 is located at an interval in the axial direction of the upper connecting portion 71 with respect to the lower connecting portion 72.

  The through hole of the upper connection portion 71 has an annular recess 199 that opens to the lower connection portion 72 side. Specifically, the through hole of the upper connection portion 71 has a first cylinder inner peripheral surface 100 and a second cylinder inner peripheral surface 101. The first cylindrical inner peripheral surface 100 is continuous with the second cylindrical inner peripheral surface 101 via a stepped portion 103 extending in the radial direction. The inner diameter of the first cylindrical inner peripheral surface 100 is smaller than the inner diameter of the second cylindrical inner peripheral surface 101.

  As shown in FIG. 2, the first backup ring 74, the first O-ring 78, and the first spacer 76 are disposed in the annular recess 199. Specifically, the first backup ring 74, the first O-ring 78, and the first spacer 76 are fitted and fixed to the second cylindrical inner peripheral surface 101 of the upper connection portion 71 by press-fitting.

  The first O-ring 78 is sandwiched between the first backup ring 74 and the first spacer 76. The first backup ring 74 is in contact with the step portion 103. The first spacer 76 is located closer to the lower connection portion 72 than the first O-ring 78.

  The bottomed hole of the lower connection portion 72 has an annular recess 189 that opens to the upper connection portion 71 side. Specifically, the bottomed hole of the lower connection portion 72 has a first cylinder inner peripheral surface 110 and a second cylinder inner peripheral surface 111. The first cylindrical inner peripheral surface 110 is connected to the second cylindrical inner peripheral surface 111 via a step portion 113 extending in the radial direction. The inner diameter of the first cylindrical inner peripheral surface 110 is smaller than the inner diameter of the second cylindrical inner peripheral surface 111.

  As shown in FIG. 2, the second backup ring 75, the second O-ring 79, and the second spacer 77 are disposed in the annular recess 189. Specifically, the second backup ring 75, the second O-ring 79, and the second spacer 77 are fitted and fixed to the second cylindrical inner peripheral surface 111 of the lower connection portion 72 by press-fitting. The second O-ring 79 is sandwiched between the second backup ring 75 and the second spacer 77. The second backup ring 75 is in contact with the step 113 of the lower connection portion 72. The second spacer 77 is located closer to the upper connecting portion 71 than the second O-ring 79.

  The first spacer 76 is located at a distance from the second spacer 77 in the axial direction of the first spacer 76. As described above, the oil sealing passage 32 opens on the side surface of the hole 31 of the cylindrical member 2 that is a fluid pressure coupler connecting member.

  The corrugated annular washer 83 is disposed between the first spacer 76 and the second spacer 77 so as to be sandwiched between the first spacer 76 and the second spacer 77. The washer 83 urges the first spacer 76 and the second spacer 77 in the direction in which the distance between the first spacer 76 and the second spacer 77 increases. The entire annular washer 83 overlaps the first spacer 76 in the axial direction of the hole 31, and the entire annular washer 83 overlaps the second spacer 77 in the axial direction of the hole 31.

  Referring to FIG. 1, in the above configuration, when a load of a predetermined value or less (load in a range where torque is transmitted) is applied to shaft member 1 or cylindrical member 2, a male coupler (not shown) is attached. With the oil for hydraulic expansion inserted into the female coupler 61 and injected into the hydraulic expansion chamber 26 from the male coupler via the female coupler 61, the inner peripheral surface 21 of the first cylindrical member 10 is reduced in diameter to be inner peripheral. The surface 21 is pressed against the outer peripheral surface 20 of the shaft member 1, and the shaft member 1 and the tubular member 2 are frictionally coupled to transmit torque between the shaft member 1 and the tubular member 2.

  On the other hand, a load greater than a predetermined value is applied to the shaft member 1 or the cylindrical member 2 (a load larger than the range in which torque is transmitted), and the outer peripheral surface 20 of the shaft member 1 is When the position of the shaft member 1 and the cylindrical member 2 about the axis changes, the locking portion 9 cuts the one end portion of the shear valve 6 to expand the hydraulic pressure in the hydraulic expansion chamber 26. This oil is discharged to the outside through the shear valve 6 with one end cut off. In this way, the pressing force of the inner peripheral surface 21 of the first cylindrical member 10 against the outer peripheral surface 20 of the shaft member 1 is eliminated, and the transmission of torque is interrupted by releasing the frictional coupling between the shaft member 1 and the cylindrical member 2. It is like that. In this way, when an overload occurs in the shaft member 1 or the cylindrical member 2, the transmission of torque is interrupted to protect the expensive machine connected to the torque limiter device.

  According to the fluid pressure coupler of the above embodiment, the female coupler 61 includes the first spacer 76 and the second spacer 77 between the first spacer 76 and the second spacer 77, and the first spacer 76 and the second spacer 77. 77, the first spacer 76 in the annular recess 199 of the upper connecting portion 71 is inserted into the first coupler 76 (not shown) by inserting a male coupler (not shown). Even if the second spacer 77 is to be moved, the first spacer 76 is urged toward the opening side of the hole 31 of the receptacle structure 33 by the washer 83 as the spring member. Never get out of it. Therefore, the first spacer 76 does not block the oil sealing passage (lateral hole) 32 of the receiving port structure 33.

  Similarly, even if the second spacer 77 in the annular recess 189 of the lower connection portion 72 tries to move to the first spacer 76 side, the bottom surface of the hole 31 of the receptacle structure 33 is formed by a washer 89 as a spring member. Therefore, the second spacer 77 does not come out of the annular recess 189 of the lower connection portion 72. Therefore, the second spacer 77 does not block the oil sealing passage 32 of the receiving port structure 33 of the cylindrical member 2. Therefore, since the first and second spacers 76 and 77 do not hinder oil injection at all, a desired amount of oil can be introduced into the fluid pressure expansion chamber 26 (see FIG. 1), and the fluid pressure expansion chamber. The 26 preload does not become smaller than the desired preload.

  Also, there is a washer 89 as a spring member that pushes the first spacer 76 and the second spacer 77 in the direction in which the distance between them increases, and the first spacer 76 comes out of the annular recess 199 of the upper connection portion 71. In addition, since the second spacer 77 does not come out of the annular recess 189 of the lower connection portion 72, the dimensions of the backup rings 74 and 75, the O-rings 78 and 79, and the spacers 76 and 77 need to be strictly controlled. Absent. Therefore, the yield of manufacturing the fluid pressure coupler can be greatly improved, and the manufacturing cost of the fluid pressure coupler can be reduced.

  In the fluid pressure coupler of the above embodiment, the spring member is an annular corrugated washer 89. However, in the present invention, the spring member may be a biasing member such as a coil spring or a string winding spring. Any member may be used as long as it can bias the first spacer and the second spacer so as to increase the distance between the first spacer and the second spacer.

  Further, in the fluid pressure coupler of the above embodiment, the shear valve 6 and the receiving port structure 33 are present at different positions in the axial direction of the torque limiter. The valve and the receiving port structure may exist at substantially the same position, and may exist at different positions in the circumferential direction of the torque limiter.

  Further, in the fluid pressure coupler of the above embodiment, the hydraulic expansion chamber 26 and the receiving port structure 33 exist in the cylindrical member 1, but in the present invention, the hydraulic expansion chamber and the receiving port structure exist in the shaft member. Also good. In this case, for example, a torque having a hydraulic expansion chamber and a receiving port structure on the shaft member by forming a receiving port structure in a portion exposed to the outside on the outer peripheral surface of the shaft member, indicated by 145 in FIG. A limiter can be realized.

  In the fluid pressure coupler of the above embodiment, the fluid is oil. However, in the present invention, it goes without saying that the fluid may be a substance having fluidity other than oil.

  In the above embodiment, the fluid pressure coupler constitutes a part of the torque limiter. However, in the present invention, the fluid pressure coupler may constitute a part of a shaft coupling device without a torque release structure. For example, the fluid pressure coupler of the present invention may be applied to a shaft coupling device that is not a torque limiter, such as a shaft coupling device having a flange structure disclosed in Japanese Utility Model Laid-Open No. 6-18733.

It is a schematic cross section of the axial direction of the torque limiter of one Embodiment of this invention. It is a figure which shows the female coupler arrange | positioned at a receptacle structure. It is a figure which shows the conventional fluid pressure coupler. It is a figure which shows the female coupler of the said conventional fluid pressure coupler.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Shaft member 2 Cylinder member 26 Hydraulic expansion chamber 31 Hole of receiving structure 32 Oil-filling passage of receiving structure 33 Receiving structure 61 Female coupler 71 Upper connecting portion 72 Lower connecting portion 74 First backup ring 75 Second backup ring 76 First spacer 77 Second spacer 78 First O-ring 79 Second O-ring 83 Washer 98 Cylindrical hole 99 Screw hole 189 Annular recess in lower connection 199 Annular recess in upper connection

Claims (3)

With a male coupler,
With a female coupler,
The female coupler is
A hole having a bottom and a fluid passage that opens to the inner peripheral surface of the hole, the hole being a small-diameter hole, and a screw hole that is larger in diameter than the small-diameter hole and located on the opening side of the hole A cup-shaped lower connection portion that is movably disposed in the small-diameter hole portion of the receiving structure of the fluid pressure coupler connection member having a portion with the opening facing the screw hole portion side;
A cylindrical upper connecting portion having an outer peripheral surface having a male screw screwed into the screw hole;
The through hole of the upper connection portion has an annular recess that opens to the lower connection portion side, and the first O-ring is disposed in the annular recess so that the first O-ring is sandwiched therebetween. An annular first spacer and an annular first backup ring are disposed;
The bottomed hole of the lower connection portion has an annular recess opening to the upper connection portion side, and a second O-ring is disposed in the annular recess so as to sandwich the second O-ring. The annular second spacer and the annular second backup ring are arranged,
The first spacer is located closer to the lower connection part than the first O-ring, and the second spacer is located closer to the upper connection part than the second O-ring.
The female coupler is located between the first spacer and the second spacer, and attaches the first spacer and the second spacer in a direction in which the distance between the first spacer and the second spacer increases. A fluid pressure coupler having a spring member. A fluid pressure coupler connecting member having a peripheral surface;
A connecting member having a peripheral surface,
The fluid pressure coupler connecting member is
A fluid pressure expansion chamber;
The hole has a bottomed hole, a fluid passage communicating the inner peripheral surface of the hole and the fluid pressure expansion chamber, and the hole has a small-diameter hole and a larger diameter than the small-diameter hole. A receiving hole structure having a screw hole portion located on the opening side of the hole with respect to the small-diameter hole portion,
The fluid pressure coupler of claim 1 connected to the receptacle structure,
The fluid pressure expansion chamber is expanded by the fluid sealed in the fluid pressure expansion passage via the fluid pressure coupler, whereby the peripheral surface of the fluid pressure coupler connecting member is changed to the peripheral surface of the connecting member. A shaft coupling device that frictionally couples the fluid pressure coupler connecting member and the coupling member by pressing against each other. The shaft coupling device according to claim 2,
By expanding the fluid pressure expansion chamber with the fluid in the fluid pressure expansion chamber and frictionally coupling the fluid pressure coupler connection member and the connection member, the fluid pressure coupler connection member and the connection member Torque is transmitted between the fluid pressure expansion chamber and the fluid pressure coupler connecting member and the coupling member by releasing the frictional coupling between the fluid pressure coupler connecting member and the coupling member. A torque limiter that releases torque transmission to and from a member.

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