JP3158309U - Biaxial clamping device - Google Patents

Abstract

A device for first clamping a first shaft by tightening a single screw and further clamping a second shaft by tightening the screw further improves the positioning accuracy of the clamping operation, and A biaxial clamping device capable of improving workability is provided. A case 10 includes a case 10, a clamp body 20 held by the case, and a fastening bolt 33 screwed into the case. By tightening the fastening bolt 33, the tip of the bolt pushes the clamp body 20 first. The shaft 31 is held between the first shaft contact surface provided on the case side and the first shaft contact surface provided on the clamp body, and then the second shaft insertion hole penetrating the second shaft insertion hole of the clamp body. The biaxial shaft 32 holds the second shaft by being easily elastically deformed by the slit 23 provided in the side portion of the second shaft insertion hole. [Selection] Figure 1

Description

  The present invention relates to an apparatus for differentially clamping the two shafts in two stages differentially by one tightening means with one connecting part slidably fitted on two substantially orthogonal shafts.

In a measuring device positioning device, a machine tool processing standard setting device, or a structure made of a rod-shaped material, a method of fixing each shaft in a predetermined positional relationship by means of a connecting part that can slide on a substantially orthogonal shaft. Many are used.
However, there is a problem that work efficiency is poor because each shaft is usually tightened with individual screws.

As a method for solving the above problem, for example, in Patent Document 1, a clamp device in which two support shafts arranged in parallel by one screw are connected so as to be rotatable and fixed is devised.
However, in the structure of Patent Document 1, the number of parts is high and the cost is high. Even when the two shaft diameters are the same, the base cylinder 5 and the first fastening cylinder 12 need to be thickened. Since both shafts are clamped at almost the same time, there is a problem in that the tightening operation cannot be performed in order, for example, the height is first adjusted and then the horizontal position is adjusted.

Moreover, in patent document 2, the coupling tool which connects and fixes a rod-shaped member with one set of volt | bolt and nut is devised.
However, in the method of Patent Document 2, since the shaft is pushed obliquely, the shaft may not be fixed at a right angle, and both shafts are clamped at the same time. Tightening work is not possible.

Japanese Utility Model Publication No. 62-167717 Japanese Utility Model Publication No. 58-53907

  The present invention improves the positioning accuracy of the clamping operation by providing a device that first clamps the first shaft by tightening one screw and then clamps the second shaft by tightening the screw. In addition, workability is improved.

  A device that clamps two shafts that intersect at substantially right angles in a two-stage differential manner with one tightening means, and includes a case, a clamp body held by the case, and a case The fastening bolt is a screwed fastening bolt, and by tightening the fastening bolt, the tip of the bolt pushes the clamp body, and first the first shaft is provided on the case side and the first shaft provided on the clamp body. Structure in which the second shaft penetrating the second shaft insertion hole of the clamp body is easily elastically deformed by a slit provided in a side portion of the second shaft insertion hole. In this case, the second shaft is held by the second shaft clamping device.

  In the biaxial clamping device, the slit provided in the side portion of the second shaft insertion hole is one slit connecting the inner peripheral surface of the second shaft insertion hole and the outer surface of the clamp body. is there.

  The slits provided at the side of the second shaft insertion hole are at least four non-through slits provided substantially symmetrically with respect to the center of the second shaft hole, and the non-through slits are inserted into the second shaft. A slit that is provided from the inner peripheral surface of the hole toward the outer surface of the clamp body and does not reach the outer surface of the clamp body, and a second shaft insertion hole that is provided from the outer surface of the clamp body toward the second shaft insertion hole. The slits that do not reach the inner peripheral surface of the bolt are alternately arranged in the direction in which the bolt tightening force acts.

The slits provided on the side of the second shaft insertion hole are at least four non-through slits provided substantially parallel to the central axis of the second shaft insertion hole, two of which are the second shaft A pair of non-penetrating slits in the same plane from the entrance to the exit, and the other two are in the same plane different from the plane from the exit of the second axis toward the entrance. It is a biaxial clamping device characterized by being a pair of non-penetrating slits.
Here, for ease of explanation, both end surfaces of the second shaft insertion hole are expressed as the entrance and exit of the second shaft, but the insertion direction of the second shaft is not limited.

  By tightening one tightening bolt, the two shafts can be operatively fastened and fixed, so workability is good.

  Positioning with respect to the two axes can be performed sequentially. For example, first, the position in the left-right direction can be accurately determined, and then the position in the front-rear direction can be determined next. Can be positioned with high accuracy.

  Since the number of parts is small, it can be manufactured at a relatively low cost. Since both shafts are tightened with circular arcs, the contact surface pressure is low, and as a result, the shafts are less likely to wear out. it can.

According to claim 3 or claim 4, since the non-penetrating slit is provided almost symmetrically with respect to the radial direction or the axial center direction of the tightening shaft, the elastic deformation amount of the hole is symmetrical with respect to the axial center. The positioning system can be further improved, and uneven wear of the shaft can be prevented.

1 is a perspective view of a biaxial clamping device according to the present invention. It is the front view and side view of a case by this invention. It is the front view and side view of the clamp body by this invention (shape of Claim 2). It is the front view and side view of the clamp body by this invention (shape of Claim 3). It is the front view and side view of the clamp body by this invention (shape of Claim 4).

A basic configuration of the present invention will be described with reference to FIGS.
FIG. 1 is a perspective view showing a state in which two substantially orthogonal axes are fixed by a clamping device according to the present invention.

The rectangular parallelepiped case 10 is provided with a square hole 14 for accommodating the rectangular parallelepiped clamp body 20 so as to be slidable in the vertical direction in FIG. 1, and a first shaft 31 is provided below the square hole. A first shaft contact surface 11 having a semi-cylindrical surface with a curvature slightly larger than the outer diameter of the first shaft is provided.
A female screw 13 is machined on the upper portion of the case 10 (the side facing the first shaft contact surface 11).
Further, clearance holes 12 for allowing the second shaft 32 to pass through loosely are provided on both side surfaces slightly above the center of the square hole in a direction perpendicular to the first shaft contact surface 11.

A first shaft contact surface 21 having a semi-cylindrical surface with a slightly larger curvature than the outer diameter of the first shaft is provided at the lower portion of the clamp body 20.
In addition, a second shaft insertion hole 22 for allowing the second shaft 32 to slidably pass through is provided in a direction slightly perpendicular to the first shaft abutting surface 21 slightly above the center of the clamp body.
One through slit 23 that connects the inner peripheral surface of the second shaft insertion hole 22 to the outer surface of the clamp body is processed.
A circular recess 28 is provided on the upper surface of the clamp body so that the tip of the fastening bolt 33 can be inserted.

  In the above configuration, as shown in FIG. 1, the first shaft 31 is passed between the first shaft contact surface 11 provided on the case 10 and the first shaft contact surface 21 provided on the clamp body 20, and When the tightening bolt 33 is tightened with the second shaft 32 penetrating the escape hole 12 provided in the case and the second shaft insertion hole 22 provided in the clamp body, the clamp body 20 is first lowered in FIG. The first shaft 31 is clamped and fixed between the first shaft contact surface 11 provided on the case and the first shaft contact surface 21 provided on the clamp body.

  When the tightening bolt 33 is further tightened, the clamp body 20 is elastically deformed, and the groove width of the through slit 23 is narrowed. That is, the inner diameter in the vertical direction of the second shaft insertion hole 22 provided in the clamp body is reduced, and the second shaft 32 is tightened and fixed.

  As described above, it is possible to tighten both the first shaft and the second shaft by tightening one tightening bolt, and first the first shaft is fixed, and then the second shaft is tightened by further tightening the bolt. Since it is fixed, highly accurate positioning can be performed while sequentially adjusting the position.

One or both of the first shaft contact surface 11 provided on the case and the first shaft contact surface 21 provided on the clamp body have a depth that is less than a semi-cylindrical. When tightened, the lower end of the clamp body does not hit the flat part of the square hole provided in the case.
The recess 28 provided in the clamp body guides the tip of the tightening bolt 33 so that the clamp body 20 does not come out of the case 10 even if the tightening bolt is slightly loosened.

FIG. 4 is an example in which a plurality of non-through slits 24 and 25 are provided instead of the single through slit 23 shown in FIG. In order to ensure the amount of elastic deformation necessary for tightening, the non-through slit 24 extending from the insertion hole 22 toward the outer surface of the clamp body and the non-through slit 25 extending from the outer surface of the clamp body toward the insertion hole 22 are alternately arranged up and down. The left and right sides of the insertion hole 22 are provided almost symmetrically.
In order to increase the amount of deformation due to local bending, at least one pair of non-penetrating slits 24 and 25 is provided, preferably one pair of non-penetrating slits 24 and two pairs of non-penetrating slits 25 are provided as shown in FIG. Is preferred.
The slit depth is preferably such that the non-penetrating slits 24 and 25 overlap when viewed from above so that local bending is easily generated, and the groove bottom shape is rounded to avoid stress concentration.

FIG. 5 shows an example in which a plurality of non-through slits 26 and 27 are provided instead of the single through slit 23 shown in FIG.
By inserting four non-penetrating slits that are overlapped by shifting the vertical position substantially parallel to the central axis of the second shaft insertion hole, the second shaft is inserted by the vertical tightening force. The inner diameter of the hole is easily elastically deformed.
The non-penetrating slit shown in FIG. 5 has an advantage that it is easier to process than the slit shown in FIG. ,

By making the slit shape shown in FIG. 4 or 5, the elastic deformation amount of the second shaft insertion hole 22 becomes symmetric, so that the clamp body 20 and the second shaft 32 slightly change in angle when clamping. Therefore, it is possible to clamp with more accurate positioning accuracy.

DESCRIPTION OF SYMBOLS 1 Clamping device 10 according to the present invention Case 11 First shaft contact surface 12 on the case side Second shaft escape hole 13 provided on the case 13 Screw 14 provided on the case side Square hole 20 Clamp body 21 Clamp body first shaft contact Contact surface 22 Second shaft insertion hole 23 of clamp body Through slit 24 provided in second shaft insertion hole of clamp body Non-through slit 25 extending from second shaft insertion hole of clamp body toward outer surface of clamp body Outside clamp body Non-through slit 26 from the surface toward the second shaft insertion hole 26 A non-through slit 27 provided in the axial direction of the insertion hole at the side of the second shaft insertion hole of the clamp body Non-through slit 28 provided in a staggered manner Recess 31 provided in the clamp body First shaft 32 Second shaft 33 Tightening bolt

Claims (4)

  The two shafts (31, 32) intersecting at substantially right angles are differentially described in two stages by one tightening means provided in one clamp device (1) slidably inserted in each shaft. A device for clamping two shafts, comprising a case (10), a clamp body (20) held by the case, and a tightening bolt (33) screwed into the case, and by tightening the tightening bolt, The tip of the bolt presses the clamp body (20). First, the first shaft (31) is provided on the case side, and the first shaft contact surface (21) provided on the clamp body. ), And the second shaft (32) passing through the escape hole (12) of the case and penetrating the second shaft insertion hole (22) of the clamp body is connected to the second shaft insertion hole. Side slits (23, 24 and 25, or 26 and 27 Biaxial clamping apparatus characterized by holding said second axis by has a structure to easily elastically deformed by.   The slit provided on the side of the second shaft insertion hole (22) is one slit (23) connecting the inner peripheral surface of the second shaft insertion hole and the outer surface of the clamp body. The biaxial clamping device according to claim 1.   The slits provided on the side of the second shaft insertion hole (22) are at least four non-through slits provided substantially symmetrically with respect to the center of the second shaft insertion hole, A slit (24) provided from the inner peripheral surface of the second shaft insertion hole toward the outer surface of the clamp body and not reaching the outer surface of the clamp body, and from the outer surface of the clamp body toward the second shaft insertion hole. The slits (25) that are provided in a row and do not reach the inner peripheral surface of the second shaft insertion hole are alternately arranged in a direction in which the bolt tightening force acts. Biaxial clamping device.   The slits provided on the side of the second shaft insertion hole (22) are at least four non-through slits provided substantially parallel to the central axis of the second shaft insertion hole, two of which are Are a pair of non-penetrating slits (26) in the substantially same plane from the entrance of the second axis toward the exit, and the other two are separate from the plane from the exit of the second axis toward the entrance. The biaxial clamping device according to claim 1, wherein the pair of non-penetrating slits (27) are substantially in the same plane.