INSERTA CLAMP

Abstract

The present invention relates to a general purpose clamping device which is called the inserta clamp. It comprises a straight shank with the lower end attached to a short cylindrical sleeve and a movable arm sliding over the shank. Feeding through the free end of the movable arm is a threaded rod with clamping pad and turning handle at the lower end and upper end respectively. The present invention is designed to hold a workpiece tightly, quickly and conveniently on the working surface of a table, workbench or machine tool. And the invention can be relocated easily over the workbench made of wood or metal, or over the working surface of a machine tool. Attachments are provided to enhance the functionality of the invention.

Description

REFERENCE

U.S. PATENT DOCUMENTS
	2,764,195	Sep. 25, 1956	William Heimes
	2,877,815	Mar. 17, 1959	William A. Fonken
	3,623,718	Nov. 30, 1971	Eugene J. Thomeczek, Sr.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a general purpose clamping device and more particularly to an inserta clamp. The invention is designed to hold a workpiece tightly, quickly and conveniently on the working surface of a table, a workbench, or a machine tool. Yet the invention can be relocated easily for different configuration and can be removed without trouble after work. The working surface of the table or workbench can be made of wood or metal, whereas the working surface of a machine tool is a metal surface with or without tooling holes.

The present invention comprises a straight shank with the lower end attached to a short cylindrical sleeve and a movable arm sliding over the shank. Feeding through the free end of the movable arm is a threaded rod with clamping pad at the lower end and turning handle at the upper end. Attachments of various designs, including a cylindrical mounting base, Y-axis attachment are provided to enhance the functionality and flexibility of the present invention. A quick release button is equipped at the upper end of the straight shank to enable the easy insertion and easy removal of the movable arm or the Y-axis attachment to or from the shank. The clamping pad is designed so that it can be rotated freely and swiveled through a limiting angle.

To clamp a workpiece on the working surface of a machine tool with tooling holes, the present invention is inserted with the short cylindrical sleeve into one of the tooling holes on the working surface. For those working surfaces without tooling holes, the present invention is inserted to the cylindrical mounting base which is mounted on the working surface with screws. Same method can be used for wooden workbench too. For application on other metal working surfaces, a short cylindrical metal tube with the right diameter can be spot welded on the working surface for the insertion of the cylindrical sleeve at the lower end of the straight shank. When inserted onto the shank of the present invention, the Y-axis attachment can be used for two-dimensional (X and Y axes) clamping of two or more workpieces simultaneously. With these attachments, the functionality and flexibility of the present invention is greatly enhanced.

2. Description of the Related Art

In the field of bonding, welding and machining, clamps are used for holding workpieces together or holding workpiece on a workbench. Various types of clamps are available, such as bar clamps, C-clamps, F-clamps and screw clamps. These clamps generally comprise a fixed arm with fixed clamping pad and a movable arm with clamping pad, or a fixed arm with fixed clamping pad at one end and a movable clamping pad attached directly to the other end of the fixed arm. Bar clamp utilizes a sliding arm over the fixed arm to clamp a workpiece. Different types of quick locking and quick releasing mechanism for the sliding arm are available in the field. C-clamp consists of a C-shape fixed arm with clamping pad at one end and a threaded rod with clamping pad and cranking handle at the other end. The movable arm of a F-clamp is a straight arm with one end sliding over the L-shape fixed arm and the other end feeding a threaded rod with clamping pad. Screw clamp utilizes two parallel clamping arms opened and closed by two parallel screws. To clamp a workpiece to the surface of a workbench, these conventional clamps must be used at the edge of the workbench so that one of the clamping arms will cross over the edge and reach the bottom of the working surface of the bench. For small workpiece on small workbench, this characteristic does not affect the effectiveness of these clamps. However, when the workpiece and the workbench are relatively large, the middle part of the workpiece will be out of the reach of the clamping arms and clamping pads. To overcome this problem, one has to make use of clamping bars, beams or any suitable fixture to hold these conventional clamps over the middle part of the workpiece and hence clamping pressure can be applied on the workpiece. This is a logical way to solve the problem, but it is also a very time consuming and inconvenient way to get the job done. Better ways of solving this problem had been devised in the past. For example, U.S. Pat. No. 2,764,195 Adjustably Mounted Bench Clamp by W. Heimes, utilizes a L-shape clamp beam inserting into a circular face plate and a sleeve. The face plate and the sleeve are mounted by screws through a cylindrical hole on the work bench so that the upper surface of the face plate is flush with the bench top. The protrusion of the L-shape clamp beam above the bench top is controlled and locked by a spring-loaded plunger and hand knob mounted to the sleeve under the workbench. According to the design of this prior art, user has to mount the face plate and the sleeve to both the top and the bottom surfaces of a pre-drilled hole on the workbench. To adjust the clamping gap or to remove the L-shape clamp beam, the user has to go underneath the workbench to disengage the plunger with the hand knob. When the workpiece and the workbench are relatively large, it would be very inconvenient to do so. Another example, U.S. Pat. No. 2,877,815 Canting Holddown Clamp by W. A. Fonken, has similar but simpler design as the above-mentioned Bench Clamp. It has the inconvenience of mounting the bushings to the bottom surface of the workbench but the convenience of adjusting the clamping gap or to relocate the L-shape shank simply from the top of the workbench. Yet another example, U.S. Pat. No. 3,623,718 Clamp Assembly by Eugene J. Thomeczek, Sr., comprises an elongated rack with horizontal slots for the detent of a clamping bar at a desired distance from the bench top. A clamping bolt is fed through the elongated slot of the clamping bar and screw into the threaded hole on the workbench or through a hole on the bench into the nut underneath to clamp the workpiece. This clamp is very simple in design and easier to use and relocate on a bench top. The only inconvenience is to prepare threaded holes or holes with nuts underneath the bench top for the clamping bolt.

BRIEF SUMMARY OF THE INVENTION

It is the intention of the present invention to provide a clamping device to hold a workpiece tightly, quickly and conveniently anywhere on the working surface of a table, a workbench, or a machine tool regardless of the size of the workpiece and the working surface. Another intention is to enable the present invention to clamp workpiece anywhere on the working surface without the use of clamping bars, beams or fixtures. Yet another intention of the present invention is to enable the clamping of a workpiece against the working surface without crossing over the edge and reaching the bottom of the work table, workbench or machine tool. It is also the intention of the present invention to lock itself on the working surface by means which can be applied and removed on the top surface only, there is no need to work underneath the work table, workbench or machine tool. Another intention of the present invention is to make a clamping device which can be used on various types of working surface, such as wood, metal or machine tool, and yet it can be relocated easily over the surface. Further intention of the present invention is to expand the functionality and flexibility of a clamping device by adding the quick release button to the shank, the cylindrical mounting base and the Y-axis attachment.

The present invention comprises a straight shank with the lower end attached to a short cylindrical sleeve and a movable arm sliding over the shank. Feeding through the free end of the movable arm is a threaded rod with clamping pad at the lower end and turning handle at the upper end. The clamping pad is designed so that it is free to rotate omni-directionally and free to swivel at certain angle to meet perfectly with the uneven surface of the workpiece. The turning handle is used to turn the threaded rod downward or upward through the movable arm to clamp or release the workpiece.

To clamp a workpiece on a working surface, the straight shank with the short cylindrical sleeve is attached to the surface and then the movable arm is moved up or down along the shank to a proper location so that the threaded rod can be lowered to clamp the workpiece with the clamping pad. For machine tool application, the short cylindrical sleeve at the bottom of the shank is inserted into one of the tooling holes on the working surface of the machine tool. If the size of the tooling hole is too big for the cylindrical sleeve, sleeve of the right size will be used between the shank and the hole. When pressure is applied to the workpiece through the movable arm and the clamping pad, the shank is tilted a little bit so that the short cylindrical sleeve is skewed against the wall of the tooling hole and the friction created will be sufficient to hold the workpiece against the working surface. For those working surfaces without tooling holes, the short cylindrical sleeve of the straight shank is inserted to the cylindrical mounting base which is mounted on the working surface with screws. The same method can be used on wooden work table or workbench too. To use the present invention on metal surfaces other than the machine tool, the cylindrical mounting base can also be used as described above. Besides that, a short cylindrical metal tube with an internal diameter a little bit bigger than the external diameter of the short cylindrical sleeve of the shank is spot welded on the metal surface where clamping is required. Then the short cylindrical sleeve of the shank is inserted into the short cylindrical tube and the workpiece can be clamped as mentioned above. To relocate or remove the present invention after work, the clamping pad is released from the workpiece and hence the friction between the short cylindrical sleeve and the short cylindrical tube is reduced too. Then the present invention can be removed from the working surface. The short cylindrical tube can easily be removed by breaking the spot weld with a hammer striking it or prying it with a metal rod, and then the metal surface can be polished to remove the spot weld residue with a suitable power hand tool.

A Y-axis attachment is devised to enhance the functionality and flexibility of the present invention. It comprises two rectangular metal plates with an elongated hole in the middle and spaced apart by cylindrical blocks at each end, a rectangular block fits inside but free to move between the two metal plates. Two threaded rods fed through each one of the cylindrical blocks respectively. The rectangular block is equipped with a rectangular hole in the middle. The size of the hole is a bit bigger than the cross-section of the straight shank so that the shank can be fed through it freely. Screw hole is provided on one side of the rectangular block to accept screw to secure the position of the rectangular block to the shank so that the Y-axis attachment will not move or drop along the shank. The shorter one of the threaded-rods is attached to a clamping pad while the longer one is equipped with a turning handle. The longer threaded rod is left-hand threaded and the free end of it is pivoted to the rectangular block. Hence turning the longer threaded rod clockwise with the turning handle will advance the Y-axis attachment towards the clamping pad end or the workpiece and turning it counterclockwise will retract the assembly away from the workpiece. With the Y-axis attachment slid over the shank of the present invention, it is possible to clamp a second workpiece along an axis perpendicular to the clamping direction of the first workpiece.

To facilitate the easy insertion and removal of the Y-axis attachment and the movable arm from the straight shank, a quick release button is equipped at the upper end of the shank. It is a metal push button with a loaded compression spring inside. Normally, it prevents the movable arm and the Y-axis attachment from dropping off the shank and when it is pressed, the insertion and removal of these items will be very easy.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

FIG. 1 is a perspective view of the present invention with the Y-axis attachment.

FIG. 2 is a perspective view of the present invention inserted into a tooling hole of the working surface of a machine tool (partly shown).

FIG. 3 is a perspective view of the present invention with the cylindrical base unit.

FIG. 4 is a perspective view of the present invention inserted into a short cylindrical tube spot welded on a metal working surface.

DETAILED DESCRIPTION OF THE INVENTION

With the help of the drawings and the detail description below, the features of the present invention will be apparent and fully understandable.

Referring to FIG. 1, the present invention, inserta clamp comprises a straight shank 1, a short cylindrical sleeve 2 attached and fixed to the lower end of shank 1 by taper pin 3, and a movable arm 4 with one end slid over the top end of shank 1 through rectangular hole 5 and the other end fitted with a threaded rod 6, turning handle 7 and the clamping pad 8. The straight shank 1 acts as the fixed arm of a conventional clamp. At the upper end of shank 1, a spring loaded quick release button 9 is equipped to prevent the falling off of the movable arm 4 and other attachments from shank 1, but at the same time it allows quick and easy insertion of these items onto shank 1. Movable arm 4 is a metal bar with a rectangular hole 5 at one end 10 and a cylindrical threaded hole 11 at the other end 12. The upper end of shank 1 is inserted into hole 5 of end 10 so that movable arm 4 is free to move upward and downward on the body of shank 1. The size of hole 5 is just a bit bigger than the cross section of shank 1 so that the movable arm will not be too loose on the body of shank 1. Threaded rod 6 is screwed into threaded hole 11 of end 12 of the movable arm 4. Turning handle 7 is inserted into a hole at the upper end 13 of the threaded rod 6 and a clamping pad 8 is pivoted to the lower end of threaded rod 6. Clamping pad 8 is free to rotate about the tip at the lower end of threaded rod 6 and to swivel through a limited angle in any directions. Upper end 13 of threaded rod 6 is made to be hexagonal with standard nut size so that a wrench may be used to turn the threaded rod 6 in case a large torque is required to clamp a workpiece.

With reference to FIG. 2 and FIG. 1 as well, to clamp a workpiece on the working surface of a machine tool, the inserta clamp is inserted with the cylindrical sleeve 2 into one of the tooling holes 20 on the working surface 21 (partly shown). When the threaded rod 6 is turned downwards against the workpiece, the movable arm 4 will be raised so that shank 1 will be skewed a little bit away from the workpiece. Hence cylindrical sleeve 2 will be pressed against one side of the tooling hole 20 and the frictional force generated should be strong enough to clamp the workpiece on the working surface provided that the outside diameter of the cylindrical sleeve 2 is just a bit smaller than the internal size of the tooling hole 20. If the outside diameter of the cylindrical sleeve 2 does not match the size of the tooling hole 20, replace it with another cylindrical sleeve of the right size. The cylindrical sleeve 2 can easily be removed by taking off the taper pin 3. Multiple inserta clamps can be used at different tooling holes as needed for various shape and sizes of workpieces.

Referring to FIG. 3, to clamp a workpiece on a working surface without tooling holes, the cylindrical mounting base 30 is used. The inserta clamp is inserted with the attached cylindrical sleeve 2 into the cylindrical mounting base 30, then the outside surface of the cylindrical sleeve 2 is fixed to the upper edge of the mounting base 30 by one or two spot welding 46. Four screw holes 31 are provided to lock the inserta clamp assembly by screws to anywhere suitable on the working surface of a table, workbench or machine tool. Same method will apply for wooden working surfaces except that different type of screws will be used.

Again referring to FIG. 3, the function of the inserta clamp can be expanded by adding the Y-axis attachment 32 onto shank 1. The Y-axis attachment 32 comprises two rectangular metal plates 33 and 34 with an elongated slot 35 in the middle of each plate. The two metal plates 33 and 34 are fixed to and separated by two cylindrical blocks 36 and 37, one at each end of the metal plates. Four screws 38 (only two shown) are used to fix the two metal plates 33 and 34 to the cylindrical block 37. The other end of metal plates 33 and 34 are welded to cylindrical block 36. Enclosed inside the metal plates 33, 34 and the cylindrical blocks 36, 37 is a rectangular block 39 which has a vertical rectangular hole 40 in the middle. The size of hole 40 is just a bit bigger than the cross section of the shank 1 so that shank 1 can be fed through hole 40 and free to slide inside it. On the front and rear sides of the rectangular block 39, four horizontal flanges 41 (only one shown) are provided to accept the two metal plates 33 and 34, one on each side. The distance between the two flanges 41 on the same side of the rectangular block 39 is made to fit the height of the metal plates 33 and 34 so that metal plates 33 and 34 are free to slide over the rectangular block 39 within two flanges 41. Screw 42 is fed through the elongated slot 35 of metal plate 33 and screwed into a threaded through hole on the front side of the rectangular block 39 so that screw 42 can be used to lock the rectangular block 39 and hence the whole Y-axis attachment in position on shank 1. The design of the screw 42 enables the free sliding of metal plate 33 over rectangular block 39 even when the screw is locking block 39 in fixed position on shank 1. A threaded hole is equipped along the center axis of cylindrical block 37 to accept the clamping pad 43. A left-hand threaded hole is provided along the center axis of cylindrical block 36 to feed the left-hand threaded rod 44. One end of the left-hand threaded rod 44 is equipped with a turning handle 45 and the other end of 44 is pivoted to one side of the rectangular block 39. When the left-hand threaded rod 44 is turned clockwise with the handle 45, cylindrical block 36 together with the movable portion of the Y-axis attachment 32 is moved towards the clamping pad 8 on the movable arm 4. This mechanism provides some means to clamp a second workpiece vertically with clamping pad 43 of the Y-axis attachment 32 against the first workpiece clamped horizontally under the clamping pad 8 of movable arm 4.

When the working surface is metallic without tooling holes and when making screw holes for attaching the cylindrical base 30 is not possible, the inserta clamp can be used as shown in FIG. 4. A short cylindrical metal tube 50 is spot welded (spot weld 51) on the working surface 52 at the location where clamping is required. Then the inserta clamp is inserted with the attached cylindrical sleeve 2 into the short cylindrical metal tube 50. When the threaded rod 6 is turned downwards against the workpiece, the movable arm 4 will be raised so that shank 1 will be skewed a little bit away from the workpiece. Hence cylindrical sleeve 2 will be pressed against one side of the internal wall of the short cylindrical metal tube 50 and the frictional force generated should be strong enough to clamp the workpiece on the working surface provided that the outside diameter of the cylindrical sleeve 2 is just a bit smaller than the internal diameter of metal tube 50. If the outside diameter of the cylindrical sleeve 2 does not match the size of metal tube 50, either replace the sleeve 2 or the metal tube 50 with another one of the right size. The sleeve 2 can easily be removed and replaced by taking off the taper pin as described in the previous paragraphs. Multiple inserta clamps can be used in different locations as needed for various shape and sizes of workpieces. To relocate or remove the present invention after work, the clamping pad 8 is released from the workpiece by turning the handle 7 counterclockwise and hence the friction between the cylindrical sleeve 2 and the short cylindrical metal tube 50 is reduced too. Then the inserta clamp can be removed from the metal tube 50. The short cylindrical metal tube 50 can easily be removed by breaking the spot weld 51 with a hammer striking it or prying it with a metal rod, then the metal surface 52 can be polished to remove the spot weld residue 51 with suitable power hand tool.

Claims

1. An inserta clamp for holding workpiece on the working surface of a table, a workbench, or a machine tool comprising:

a straight shank with the lower end attached to a short cylindrical sleeve;

a movable arm with one end sliding over the said straight shank;

a threaded rod feeding through the other end of the said movable arm to clamp workpiece with the clamping pad pivoted to its lower end and the turning handle attached to its upper end;

a cylindrical base unit with screw holes along the circumference of the flat bottom base; and

a Y-axis attachment slid over the said straight shank to hold a second workpiece along an axis perpendicular to the vertical clamping direction of the said inserta clamp.

2. An inserta clamp according to claim 1, wherein the short cylindrical sleeve is made of metal with inside diameter just big enough to accept the said straight shank to feed inside, and the outside diameter of said cylindrical sleeve is just a bit smaller than the inside diameter of the tooling hole of the machine tool, or just a bit smaller than the inside diameter of the metal tubes commonly available;

the said cylindrical sleeve is attached to the said straight shank with a taper pin which can be removed with a punch and hammer so that the said cylindrical sleeve can be removed and replaced by other cylindrical sleeve of different outside diameter to suit various application needs.

3. The inserta clamp according to claim 1 attached with the said cylindrical sleeve of the right outside diameter can be inserted into one of the tooling holes of the working surface of a machine tool to clamp a workpiece tightly against the said working surface; multiple inserta clamps can be used together at different tooling holes of the said working surface for workpiece of various shape and sizes.

4. The inserta clamp according to claim 1 attached with the said cylindrical sleeve of the right outside diameter can be inserted into the said cylindrical base unit and fixed to it by one or two spot weld along the upper edge of the said cylindrical base unit and the outside surface of the said cylindrical sleeve; the said inserta clamp assembly can be mounted on a metal or wooden working surface with proper screws through the said screw holes of the cylindrical base unit according to claim 1; then workpiece can be clamped by one or multiple numbers of the said inserta clamp assembly.

5. The inserta clamp according to claim 1 attached with the said cylindrical sleeve of the right outside diameter can be inserted into a short cylindrical metal tube which is spot welded on a metal surface without tooling holes; then one or multiple numbers of the said inserta clamp assembly can be used anywhere on the working surface to clamp a workpiece of any shape and any sizes.

6. An inserta clamp according to claim 1, wherein the straight shank is equipped with a spring loaded quick release button at the upper end of the said straight shank, the said quick release button is in position to prevent the said movable arm or other attachment to fall off the said straight shank; and the said quick release button is pressed for the quick removal and replacement of the said movable arm and the said Y-axis attachment.

7. The Y-axis attachment according to claim 1 comprising:

two rectangular metal plates with elongated slots fixed to and separated by two cylindrical blocks one at each end; a rectangular block with two upper flanges and two lower flanges to accept the said rectangular metal plates to slide between each pair of the upper and lower flanges, the said rectangular block is located inside the empty space surrounded by the said rectangular metal plates and the said cylindrical blocks; a threaded rod screwed into the threaded hole coincide with the axis of one of the said cylindrical block and a clamping pad attached to the outside end of the said threaded rod; a left-hand threaded rod with turning handle at the outside end screwed into the left-hand threaded hole coincide with the axis of the other said cylindrical block, the inside end of the said threaded rod is pivoted to the said rectangular block; and a screw feeding through the said elongated slot of one of the said rectangular metal plates and through a threaded hole on one side of the said rectangular block touching the surface on one side of the straight metal shank to fix the said Y-axis attachment to any position along the straight metal shank.

8. The Y-axis attachment according to claim 8 when inserted onto the said straight shank can be used to clamp a second workpiece against the first workpiece along a direction perpendicular to the clamping direction of the first workpiece; or

the said Y-axis attachment can be used in any other application that is possible in this configuration.