JP2005121141A - Ball joint structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a ball joint structure capable of being easily assembled by dispensing with large-scale devices and improving the workability in connecting a vibration control damper with a brace. <P>SOLUTION: This ball joint structure comprises a ball stud 2 integrally connected with an end part of the vibration control damper D as a connected object, a ball receiver 3 rotatably holding a ball part 21 on the ball stud 2, and a holder 4 connected with a rear end side of the ball receiver 3 for preventing the slipping out of the ball part 21 on the ball stud 2 from the ball receiver 3. The specific external force is applied to the holder 4 to stabilize the ball part 21 on the ball stud 2, in the ball receiver 3. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an improvement in a ball joint structure.

  For example, in order to quickly calm down the shaking of a building due to an earthquake, a damping damper, which is a damper, may be connected to a brace in the wall that constitutes the building. Measures to connect this damping damper to a brace, etc. Conventionally, there are various proposals, and among them, there is a proposal to connect both ends of the damping damper under the ball joint structure (for example, see Patent Document 1).

  That is, in the proposal disclosed in Patent Document 1, the ball joint structure rotatably holds a ball portion in a ball stud connected to an end portion of a rod body, for example, in a vibration control damper that is a connected body. A ball receiving nut is screwed onto the rear end side of the ball receiver to prevent the ball portion from coming out of the ball receiver.

Therefore, in the ball joint structure proposed above, the ball receiving nut is screwed to the ball receiver with a predetermined torque so that the ball portion of the ball stud does not rattle in the ball receiver. By connecting the ball receiver to a brace or the like by an appropriate means, the damping damper can be used.
Japanese Patent Laid-Open No. 9-158529 (Claims Claims 1, Paragraphs 0002, 0008, 0009, 0012, FIG. 2)

  By the way, in the above-described ball joint structure, there is a risk that it may be pointed out that it takes time to connect the seismic damper, which is a connected body, to a brace or the like, although there is no conspicuous defect.

  That is, in the above-described ball joint structure, the ball receiving nut is screwed into the ball receiver under a predetermined tightening torque when the ball portion of the ball stud is accommodated in the ball receiver without rattling. The torque is likely to be large, and therefore a large device may be required during assembly.

  In addition, if the ball receiving nut is screwed onto the ball receiver with an unnecessarily large tightening torque, and therefore it is not easy to rotate the ball inside the ball receiver, this ball joint structure is used. There is a concern that workability when connecting the damping damper to a brace or the like is deteriorated.

  The present invention has been developed in view of such a current situation, and an object of the present invention is to make it easy to assemble without requiring a large-scale device. The object is to provide a ball joint structure that is optimal for improving the versatility by improving workability when connecting a vibration control damper as a connected body to a brace or the like.

  In order to achieve the above object, the structure of the ball joint structure according to the present invention is as follows. According to claim 1, the ball stud integrally connected to the end of the connected body and the ball portion of the ball stud are rotated. A ball holder that can be held, and a holder that is connected to the rear end side of the ball receiver and prevents the ball portion from slipping out of the ball stud from the inside of the ball receiver, and applies a predetermined external force to the holder. It is assumed that the ball portion of the ball stud is stabilized in the ball receiver.

  According to a second aspect of the present invention, the coupled body comprises a double rod type vibration damping damper having a rod body extending in both directions from a piston sliding in the cylinder body, and one ball stud is one of the vibration damping dampers. It is assumed that the other ball stud is connected to the cylinder body of the vibration damping damper and connected to the housing portion that houses the other rod body of the vibration damping damper.

  According to a third aspect of the present invention, a plate is adjacent to the back surface of the holder, and a predetermined external force is applied to the holder through the plate. It is preferable to be housed in the part.

  Therefore, in the invention of claim 1, since the ball portion of the ball stud is fixed in the ball receiver, it is only necessary to apply an external force to the holder without screwing the holder to the ball receiver. Assembling the joint structure is easy, and when connecting to the connected body that connects the ball joint structure, for example, the vibration control damper, it is not subject to mischief from the vibration control damper side. It becomes possible to connect.

  According to the second aspect of the present invention, when the coupled body is made of a vibration damping damper, it can be installed at a predetermined position without hindering the operation of the vibration damping damper.

  In the invention of claim 3, since the state in which the holder fixes the ball portion of the ball stud in the ball receiver can be maintained by the plate, the connected body in an assembled state in which the ball joint structure is connected. In this case, the plate is accommodated in the holder, so that the ball joint structure can be made compact. become.

  As a result, according to the present invention, it is easy to assemble without requiring a large-scale device, and further, for example, to improve workability when connecting the vibration damper to a brace, It is most suitable for expecting the improvement of the versatility.

  In the following, the present invention will be described based on the illustrated embodiment. As shown in FIG. 1, the ball joint structure 1 according to the present invention is connected to a vibration damper D as a connected body in the illustrated embodiment. Although not shown, it is connected to a brace B (see FIG. 3) distributed in the wall forming the building.

  Incidentally, the damping damper D, which is a coupled body, is a pair of rods that are extended in the same manner in both directions from a piston P that slides while defining two oil chambers R1, R2 in the cylinder body C. It is formed into a double rod type having a body R.

  And in this damping damper D, one ball stud 2 is connected to the end of one rod body R, and the housing portion H is connected to the cylinder body C and accommodates the other rod body R. The other ball stud 2 is connected to the other.

  In the damping damper D, although the generation of the damping force is not shown, it is of course possible that the hydraulic oil passes through the damping force generation portion disposed in the piston P in the cylinder body C. However, as shown in the figure, the damping force generator V disposed in the flow path L communicating with both the oil chambers R1, R2 in the cylinder body C while being disposed outside the so-called damper body is hydraulic oil. It is assumed that a predetermined damping force is generated when passing.

  When the damping damper D is formed as described above, the ball joint structure 1 according to the present invention is connected to the end of one rod body R, one on the left in the figure, and the other cylinder body C. Is connected to a housing portion H in which the other rod body R located on the right side in the drawing is accommodated.

  Incidentally, in the illustrated case, as described later, the ball stud 2 forming the ball joint structure 1 is connected to the rod body R and the housing portion H. It may be said that the ball stud 2 may be connected to the brace B or the like.

  However, in this case, the ball stud 2 is braced in a situation where the ball receiver 3 that rotatably holds the ball portion 21 of the ball stud 2 is fixedly connected to the vibration control damper D that is the connected body. It will be connected to B etc.

  However, it is not easy to connect the ball receiver 3, that is, the ball stud 2 in which the ball portion 21 is connected to the vibration damper D to the brace B. Therefore, in the present invention, the operation from the vibration damper D side is not easy. The possibility of connecting the ball stud 2 to the brace B etc. is feasible if the damping damper D is connected to the brace B etc. without being subjected to mischievous regulations such as receiving axial force. I must say it is inferior.

  On the other hand, the ball joint structure 1 includes a ball stud 2, a ball receiver 3, a holder 4, and a plate 5 as shown in FIGS. 2 and 4. However, the ball portion 21 of the ball stud 2 is stabilized in the ball receiver 3 by applying a predetermined external force to the holder 4.

  To explain a little, the ball stud 2 has a screw portion 22 integrally connected to the housing portion H at the end portion of the vibration damping damper D, that is, in the illustrated case, for example, at the tip end of the shaft portion 23. At the same time, the ball portion 21 is provided at the rear end of the shaft portion 23.

  The above-mentioned sphere portion 21 is formed of a so-called sphere. Therefore, basically, the sphere portion 21 can freely rotate within the sphere receiver 3, but the sphere portion 21 rotates within the sphere receiver 3. In order to assure safety, lubricating oil or the like may be interposed between the two, and measures for interposing this lubricating oil are not shown, but for example, an oil hole is drilled in the axial center portion of the ball stud 2. Of course, a free configuration can be selected.

  Next, the ball receiver 3 is configured to accommodate the ball portion 21 of the ball stud 2 so as to be rotatable. As long as the rotation of the ball portion 21 is guaranteed, a free configuration is adopted. Although it is good, in embodiment of this invention, it forms in the aspect which can be connected with the brace B etc.

  That is, as shown in FIG. 3, the ball receiver 3 has a flange portion 31 so as to be easily connected to the brace B or the like using the bolt 6 and the nut 8, and the bolt 6 is attached to the flange portion 31. It has a hole 31a to be inserted.

  Incidentally, the flange portion 31 is formed in, for example, a substantially quadrangular shape and has the above-described holes 31a at so-called four corner portions, as is often the case with this type of flange-like member.

  The ball receiver 3 is of course formed to have a depth sufficient to accommodate the ball portion 21 of the ball stud 2 so as to be pivotable. In particular, it is formed so that the tip side can be linked.

  And when the front end side of the holder 4 is connected to the rear end portion of the ball receiver 3, that is, when the holder 4 is stowed, the front end which is the left end in the drawing is subordinate to the outer peripheral surface of the above-described ball portion 21. The concave surface 41 has a curvature that matches the curvature of the sphere 21.

  Therefore, in this holder 4, when connected so as to be inserted into the rear end side of the ball receiver 3, the rotation of the ball portion 21 within the ball receiver 3 is not obstructed. The rattling of the ball portion 21 in the ball receiver 3 can be prevented.

  At this time, the holder 4 has a rear end serving as an external force acting portion 42, and the end surface of the external force acting portion 42 slightly protrudes from the rear end surface of the ball receiver 3. If the tightening amount using the bolt 6 and the nut 8, that is, the stroke amount for bringing the ball receiver 3 and the plate 5 into close contact with each other is set, the so-called full tightening operation using the bolt 6 and the nut 8 is performed. The ball receiver 3 and the plate 5 do not need to be excessively adhered.

  Therefore, when an external force is applied to the external force acting portion 42 of the holder 4 to push the holder 4 into the ball receiver 3, the force of the ball portion 21 in the ball receiver 3 increases as the force at that time increases. The rotation of the ball portion 21 can be suppressed while preventing rattling.

  From this point of view, in the present invention, the holder 4 is connected to the rear end side of the ball receiver 3, that is, only needs to be accommodated in the rear end side of the ball receiver 3. It is not necessary to screw the ball receiving nut onto the ball receiver 3 as in the proposal disclosed in Document 1, and therefore, so-called portable tools are sufficient, and no device capable of generating a large torque is required. It becomes advantageous in becoming.

  Further, in this holder 4, the ball stud 2 is free to the ball receiver 3 as long as it is maintained in the rear end side of the ball receiver 3 without any mischievous external force action. When the ball receiver 3 is connected to the brace B or the like, there is no need to worry that the mounting operation is hindered by receiving the axial force from the vibration control damper D or the like. Is advantageous.

  From the above, the external force acting portion 42 as the rear end portion of the holder 4 may be formed in any manner as long as it can receive external force as a result. From the viewpoint of contact, etc., it is formed on a flat surface.

  The plate 5 applies an external force to the holder 4 as shown in the figure, and basically comprises a plate-like body. In the embodiment shown in FIG. It is supposed that it is formed so as to exhibit the planar shape.

  At this time, since the flange 3 has a hole 31a in the ball receiver 3, the plate 5 is also formed with a hole 51 that allows insertion of the bolt 6 described above at a corresponding portion.

  In addition, the plate 5 is connected to the rear end of the holder 4 by the temporary fixing bolt 7. At this time, the outer peripheral side of the plate 5 has a gap in the flange portion 31 of the ball receiver 3. They are opposed and do not touch.

  When the plate 5 is connected to the holder 4 with the temporary fixing bolt 7, the ball portion 21 of the ball stud 2 accommodated in the ball receiver 3 freely moves in the ball receiver 3 as described above. It is supposed to embody the state to obtain.

  Therefore, from this state, the ball joint structure 1, that is, the ball receiver 3 is in contact with the brace B or the like as shown in FIG. 5 is pushed forward toward the holder 4, that is, the rotation of the ball portion 21 in the ball stud 2 tends to be suppressed in the ball receiver 3, that is, the mischief of the ball portion 21 in the ball receiver 3. Will be prevented.

  By the way, from the viewpoint of the function of the plate 5, in the embodiment of FIG. 2, the plate 5 is formed to have the same size as the rear end of the ball receiver 3, but as shown in FIG. It may be formed so as to be housed in the rear end portion of the ball receiver 3.

  That is, in the place shown in FIG. 4, the rear end portion of the ball receiver 3 is formed with a recessed portion 32 that accommodates the outer periphery of the plate 5 without interfering with the outer periphery of the plate 5. For example, it is assumed that the plate 5 formed in a disk shape is accommodated.

  At this time, the plate 5 is connected to the rear end portion of the ball receiver 3 with the temporary fixing bolt 7, but the back surface of the plate 5 is more external than the rear end surface of the ball receiver 3. , Projecting to the brace B side.

  Therefore, even in this embodiment, when the plate 5 is pushed toward the holder 4 side while the ball receiver 3 is in contact with the brace B or the like, the ball stud 2 in the ball receiver 3 is used. The mischievous rattling of the ball part 21 at is prevented.

  In addition, in this embodiment, the plate 5 can be made small, and therefore, it is advantageous in that the weight of the ball joint structure 1 according to the present invention can be reduced.

  As described above, in the present invention, rattling of the ball portion 21 in the ball stud 2 in the ball receiver 3 can be prevented without requiring an unpleasant tightening torque, and the ball joint structure 1 is used. It will be possible to connect the vibration control damper D, which is the connected body, to the brace B or the like.

  From this point of view, that is, as long as the damping damper D can be connected to the brace B or the like using this ball joint structure 1, as shown in FIG. It can be said that the plate 5 may be omitted.

  That is, in this embodiment, from the state where the plate 5 is not shown, the rear end of the holder 4 is brought into direct contact with the brace B or the like, as shown in the phantom diagram in the figure. However, by using the bolt 6 (see FIG. 3) and the nut 8 (see FIG. 3), the ball receiver 3, that is, the ball joint structure 1 can be connected to the brace B or the like.

  Incidentally, at this time, the tightening torque for the bolt 6 or the nut 8 is appropriately selected, and it is a matter of course that a large apparatus is not required for realizing the tightening torque.

It is a schematic sectional drawing which shows the state by which the ball joint structure by this invention is connected with the damping damper. It is sectional drawing which shows the ball joint structure by this invention. FIG. 3 is a cross-sectional view showing a state where the ball joint structure of FIG. 2 is connected to a predetermined connecting part such as a brace. It is a figure which shows the ball joint structure by other embodiment similarly to FIG. It is a figure which shows the ball joint structure by other embodiment similarly to FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Ball joint structure 2 Ball stud 3 Ball receiver 4 Holder 5 Plate 6 Bolt 7 Temporary fixing bolt 8 Nut 21 Ball part 22 Screw part 23 Shaft part 31 Flange part 31a, 51 hole 32 Recessed part 41 Concave surface 42 External force action part C Cylinder body D Damper H Housing L Flow path P Piston R Rod body R1, R2 Oil chamber V Damping force generator

Claims (4)

A ball stud that is integrally connected to the end of the body to be connected, a ball receiver that rotatably holds the ball portion of the ball stud, and a rear end of the ball receiver that is connected to the rear end side of the ball stud. A ball joint structure comprising a holder for preventing the ball stud from coming out of the ball stud, and the ball stud in the ball stud being stabilized in the ball receiver by applying a predetermined external force to the holder. The connected body comprises a double rod type damper having a rod body extending in both directions from a piston sliding in the cylinder body, and one ball stud is connected to an end of one rod body in the damper, and the other The ball joint structure according to claim 1, wherein the ball stud is connected to a housing portion that is connected to a cylinder body of the damper and accommodates the other rod body of the damper. 2. The ball joint structure according to claim 1, wherein a plate is adjacent to the back surface of the holder, and a predetermined external force is applied to the holder through the plate. 4. The ball joint structure according to claim 3, wherein the plate is accommodated in a rear end portion of the ball receiver.

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