Do-it-yourself eccentric drawings. Quick-release eccentric vise. Upper cross clamp

eccentric clamps, in contrast to screw ones, they are fast-acting. It is enough to turn the handle of such a clamp less than 180 ° to secure the workpiece.

The scheme of the eccentric clamp is shown in Figure 9.

Figure 9 - Scheme of the action of the eccentric clamp

When the handle is turned, the radius of rotation of the eccentric increases, the gap between it and the part (or lever) decreases to zero; the clamping of the workpiece is carried out due to the further "compaction" of the system: eccentric - part - fixture.

To determine the main dimensions of the eccentric, one should know the value of the clamping force of the workpiece Q, the optimal angle of rotation of the handle for clamping the workpiece, and the tolerance for the thickness of the workpiece to be fixed.

If the angle of rotation of the lever is unlimited (360°), then the value of the eccentricity of the Cam can be determined by the equation

where S 1 is the installation gap under the eccentric, mm;

S 2 - stroke margin of the eccentric, taking into account its wear, mm;

workpiece thickness tolerance, mm;

Q – workpiece clamping force, N ;

L - clamping device rigidity, N /mm(characterizes the amount of pressing of the system under the influence of clamping forces).

If the angle of rotation of the lever is limited (less than 180°), then the eccentricity value can be determined by the equation

The radius of the outer surface of the eccentric is determined from the condition of self-braking: the angle of eccentric lifting, composed by the clamped surface and the normal to the radius of its rotation, must always be less than the angle of friction, i.e.

(f=0.15 for steel),

where D and R- respectively the diameter and radius of the eccentric.

The workpiece clamping force can be determined by the formula

where R - force on the eccentric handle, N (usually taken ~ 150 N );

l - handle length, mm;

– angles of friction between the eccentric and the workpiece, between the trunnion and the eccentric support;

R 0 - radius of rotation of the eccentric, mm.

For an approximate calculation of the clamping force, you can use the empirical formula Q12 R(at t=(4- 5) R and P=150 N) .

More complicated than shown above, eccentrics are calculated with an involute curve, in which the angle of elevation is always unchanged, as well as with a curve outlined by the Archimedes spiral, in which the angle of elevation decreases as the handle is turned.

Some of the eccentric clamps used in fixtures are shown in Figure 10.

Very often, clamping workpieces directly with an eccentric is not rational, since the eccentricity (pressure value) is only a few millimeters. It is much more expedient to combine eccentric clamps with lever or some other clamps, or to design them as folding ones.

Literature

6base..

test questions

What you need to know to determine the basic dimensions of the eccentric?

Why is it very often irrational to clamp workpieces directly with an eccentric?

a, b - for preloaded flat workpieces; b - for fixing flat workpieces using a rocking beam; G - for tightening the shells with a flexible clamp

Figure 10 - Examples of eccentric clamps of various designs

Lecture 6 Lever clamps

Lever clamps are widely used in assembly and welding fixtures, most often for fixing sheet blanks located horizontally. Such clamps are fast-acting, create high clamping forces, the value of which, if necessary, can be adjusted within a fairly wide range using spring shock absorbers. The designs of these clips can be easily normalized, thus providing the versatility of their application.

The disadvantage of lever systems is the possibility of accidental, and in case of poor design, spontaneous opening of the grips. Therefore, such clamps should be used only when accidental unfastening of the workpiece will not lead to an accident or danger to workers. It is possible to reduce the possibility of accidental opening of the lever clamp by using massive handles, the gravity of which in the working position has the same direction as the force of the worker applied to the handle when fixing the part. Various fixing devices increase the reliability of lever systems even more: hecks, locks, etc. The scheme of operation of the lever system is shown in Figure 1. 2 the handle is attached 3. To the latter via connecting strips 4, seated on 5 axles, hinged arm 6, sitting on axis 7 and having an adjustable stop 8 (set stop overhang 8 fixed with a lock nut 0 ). The stroke of the handle-bracket is limited by the stop 10. When flipping the handle 3 to the right around the fixed hinge 2 link 4 raises the working lever 6, allowing installation of the assembled part. When the handle moves back, the workpiece is clamped.

Figure 11 - Scheme of action of the lever clamp

Screw 8 is used to change the setting gap (for the possibility of adjusting the pressing force when changing the thickness of the workpieces to be fixed or the wear of the clamp).

The calculation of the magnitude of the clamping force, which depends on the scheme of the lever system, is carried out according to the rule of shoulders (you can also use the graphic-analytical method - the construction of power polygons).

For levers of the 1st kind (Figure 12, a) and 2nd kind (Figure 12, b) clamping force Q can be calculated according to the equations:

For levers of the 1st kind;

For levers of the 2nd kind,

where R- force applied to the end of the handle, N;

a - leading arm of the lever;

b - driven lever arm;

f is the coefficient of friction in the hinge;

r- hinge pin radius.

a-1st kind; b- 2nd kind

Figure 12 - Scheme of levers

For more complex mechanisms, the clamping force also depends on the angle - the angle of the “tilt” of the levers (Figure 13). The greatest clamping force is provided at tilt angles close to zero.

Lever clamps, as a rule, are used in combination with others, forming more complex lever-screw, lever-spring and other amplifiers, which make it possible to transform either the magnitude of the pressing force, or the magnitude of the clamping stroke, or the direction of the transmitted force. Such amplifiers in terms of design can be very diverse.

Without a vise, it is impossible to imagine an auto repair or home workshop, regardless of what material you have to work with: metal, plastic or wood. Usually everywhere they use a classic vise with a crank, which slowly clamp and unclench the parts.

It is absolutely easy and in a short time to make home-made metal vise with an eccentric clamp, which are compact in size, and also allow you to quickly and reliably fix workpieces. The speed of the vise will be especially useful when performing large volumes of work that are monotonous and monotonous.
You can make the simplest metal vice with an eccentric clamp with your own hands from inexpensive improvised materials - scrap metal residues, which are almost always found in a home workshop or garage. Therefore, we will not dwell on the materials. If there is a need to specify their features, we will clarify this in the process of work.
We need the most common tools for work:

• welding machine;
• grinder with a cutting disc;
• drilling machine or drill;
• thread tap:
• a hammer;
• ticks;
• locksmith vise, etc.

Let's start making vise

In order for the work to be argued, it does not prevent oneself from mentally imagining the end result of the work we are just starting: ready-made quick-clamping eccentric vices that delight us with their compactness, color variety and amazing ability to quickly and reliably clamp any workpiece.

Well, now - to work, so that the dream turns into reality. We find the rest of the useless channel, mark it with a ruler and a marker, and cut off the necessary piece with a grinder. It will become the basis for the movable and fixed jaw of our vise.

After marking, we cut off two equal-length pieces from a suitable-sized equal-angle corner, which in a vice will become the base of the jaws of our home-made vise.

In the middle of the shelf of one of the corners - the future movable vice jaw, we outline the center of the hole, which we drill on a drilling machine.

On the jumper of the channel blank along its central axis, closer to one end, we outline the boundaries of the slot along which the movable jaw of our vise will move. Marked points by punching and drilling holes, which will be the ends of the slot.

Using a grinder, we cut a strip of metal in the channel bar between these two holes and knock it out with a tapering hammer. This slot will set the limits of movement of the movable vise jaw.

We cut off two pieces with a grinder from a suitable metal strip, the length of which is equal to the width of the corner shelf. They will serve as limiters for the movable sponge as it moves along the slot.

Next, we connect the corner and the channel with a bolt and nut to the position that they will occupy in the finished vice.

We clamp this structure in a metalwork vise and weld limiters to the corner transversely on both sides of the channel, holding them with pliers. In order not to accidentally weld them to the channel shelves, we place a thin piece of rubber, plastic or other dielectric material between them for the duration of welding.

Then, from a hammer with a round head that has served its purpose, we cut off with a grinder a cylindrical blank in height approximately equal to the diameter - the workpiece of the future eccentric clamp.

We mark at its end a point with some eccentricity - an indent from the central longitudinal axis of the cylinder. According to the mark, we drill a through hole parallel to the axis of our workpiece.

From a thick strip of metal, after marking, we cut out two pieces in length and height equal to the shelf of an equal-angle corner. These are future overlays for quick-clamping vise jaws.

We drill two holes in these overlays in the center closer to the edges. We deploy them from the front side under the heads of the mounting screws. With the help of a grinder, we apply a notch and clean them. We try the quality of fastening the lining to the shelves of the corners (sponges) with two bolts and nuts.

We weld one corner (fixed sponge) transversely to the channel lintel from the side opposite the slot. We reinstall the linings on the fixed and movable jaws and finally screw them in place using a wrench and a screwdriver.

From a rather thick metal, we cut out a strip equal in size to the length of the corner, and in width to the distance between the ends of the shelves diagonally. We also weld it to ensure the strength and rigidity of the fixed sponge.

Now we take a thicker strip of metal and drill a hole from one end and cut a thread in it with a tap. Then we cut off a piece from it with a threaded hole of a rectangular shape, slightly different from a square.
This homemade rectangular nut will hold the eccentric on the movable jaw, and allow them to move along the channel jumper (guide) in one direction or another.

So that the nut does not rotate under the channel jumper, on both sides of it, we cut off and weld two guide rods-limiters longitudinally along the entire slot with a small gap.

In the eccentric on the side, approximately in the middle of its height, we drill a blind hole and cut a thread in it for attaching the handle.
We assemble the movable vise jaw with pre-welded stops, screwing the finished notched overlay to the corner with two bolts.

We find a piece of sheet iron of sufficient thickness to ensure rigidity. We outline on it the contours of the base of an octagonal shape with two marks for mounting holes. Using a grinder, cut it out.
We weld a channel (guide) with a fixed sponge to it. We process welds and surfaces with a grinder to remove rust, metal sagging, roughness and rounding edges.

We seal the sponge pad and the longitudinal slot with a margin on the sides with construction tape.

With their help, with one movement of the eccentric handle, you can fix any workpieces in them quickly, reliably and without any extra effort.

Notes at the end

Since you have to work with a grinder, a welding machine, a drilling machine, you must use personal protective equipment, at least goggles to protect your eyes and gloves on your hands.
In order for the moving parts of the eccentric vice to work without jamming, they can be lubricated with graphite grease from time to time, and the eccentric lever can be equipped with a wooden handle for convenience.

/ 13.06.2019

Do-it-yourself eccentric clamp made of metal. Eccentric clamp

Eccentric clamps are easy to manufacture for this reason, they are widely used in machine tools. The use of eccentric clamps can significantly reduce the time for clamping the workpiece, but the clamping force is inferior to threaded clamps.

Eccentric clamps are available in combination with clamps and without them.

Consider an eccentric clamp with a clamp.

Eccentric clamps cannot work with large tolerance deviations (±δ) of the workpiece. With large tolerance deviations, the clamp requires constant adjustment with screw 1.

Calculation of the eccentric

The material used for the manufacture of the eccentric are U7A, U8A With heat treatment up to HR from 50....55 units, steel 20X with carburizing to a depth of 0.8... 1.2 With hardening HR c 55...60 units.

Consider the scheme of the eccentric. Line KN divides the eccentric into two? symmetrical halves consisting, as it were, of 2 x wedges screwed onto the "initial circle".

The axis of rotation of the eccentric is displaced relative to its geometric axis by the amount of eccentricity "e".

For clamping, the section Nm of the lower wedge is usually used.

Considering the mechanism as a combined one consisting of a lever L and a wedge with friction on two surfaces on the axis and the point "m" (clamping point), we obtain a force dependence for calculating the clamping force.

where Q is the clamping force

P - force on the handle

L - handle arm

r - distance from the axis of rotation of the eccentric to the point of contact With

blank

α - slope angle of the curve

α 1 - angle of friction between the eccentric and the workpiece

α 2 - angle of friction on the axis of the eccentric

To prevent the eccentric from moving away during operation, it is necessary to observe the condition of self-braking of the eccentric

where α - sliding friction angle at the workpiece contact point ø - coefficient of friction

For approximate calculations Q - 12P Let's consider the scheme of a double-sided clamp with an eccentric

Wedge clamps

Wedge clamping devices are widely used in machine tools. Their main element is one, two and three-beveled wedges. The use of such elements is due to the simplicity and compactness of designs, speed of action and reliability in operation, the possibility of using them as a clamping element acting directly on the workpiece being fixed, and as an intermediate link, for example, an amplifier link in other clamping devices. Usually self-braking wedges are used. The self-braking condition of a single-sided wedge is expressed by the dependence

α > 2ρ

where α - wedge angle

ρ - the angle of friction on the surfaces Г and Н of the contact of the wedge with the mating parts.

Self-braking is provided at an angle α = 12°, however, in order to prevent vibrations and load fluctuations during the use of the clamp from weakening the fastening of the workpiece, wedges with an angle α are often used.

Due to the fact that a decrease in the angle leads to an increase in

self-braking properties of the wedge, it is necessary, when designing the drive to the wedge mechanism, to provide devices that facilitate the removal of the wedge from the working state, since it is more difficult to release the loaded wedge than to put it into working condition.

This can be achieved by connecting the actuator stem to the wedge. When the rod 1 moves to the left, it passes the path "1" to idle, and then hitting the pin 2, pressed into the wedge 3, pushes the latter. During the reverse stroke of the rod, it also pushes the wedge into the working position with a blow to the pin. This should be taken into account in cases where the wedge mechanism is driven by a pneumatic or hydraulic actuator. Then, to ensure the reliability of the mechanism, it is necessary to create different pressures of liquid or compressed air from different sides of the drive piston. This difference when using pneumatic actuators can be achieved by using a pressure reducing valve in one of the tubes supplying air or fluid to the cylinder. In cases where self-braking is not required, it is advisable to use rollers on the contact surfaces of the wedge with the mating parts of the device, thereby facilitating the introduction of the wedge into its original position. In these cases, the locking of the wedge is mandatory.

With large production programs, quick-acting clamps are widely used. One of the types of such manual clamps are eccentric, in which clamping forces are created by turning the eccentrics.

Significant efforts with a small area of ​​contact with the working surface of the eccentric can cause damage to the surface of the part. Therefore, usually the eccentric acts on the part through the lining, pushers, levers or rods.

Clamping eccentrics can be with a different profile of the working surface: in the form of a circle (round eccentrics) and with a spiral profile (in the form of a logarithmic or Archimedean spiral).

A round eccentric is a cylinder (roller or cam), the axis of which is located eccentrically with respect to the axis of rotation (Fig. 176, a, biv). Such eccentrics are the easiest to manufacture. A handle is used to rotate the eccentric. Eccentric clamps are often made in the form of crank rollers with one or two bearings.

Eccentric clamps are always manual, therefore the main condition for their correct operation is to maintain the angular position of the eccentric after it has been rotated for clamping - “eccentric self-braking”. This property of the eccentric is determined by the ratio of the diameter O of the cylindrical working surface to the eccentricity e. This ratio is called the characteristic of the eccentric. At a certain ratio, the condition of self-braking of the eccentric is fulfilled.

Usually, the diameter B of a round eccentric is set from design considerations, and the eccentricity e is calculated based on self-braking conditions.

The line of symmetry of the eccentric divides it into two parts. One can imagine two wedges, one of which, when the eccentric is turned, fixes the part. The position of the eccentric when it contacts the surface of the smallest part.

Usually, the position of the section of the profile of the eccentric, which is involved in the work, is chosen as follows. so that with the horizontal position of the lines 0 \ 02, the eccentric would touch the point c2 of the clamped fly of medium size. When clamping parts with maximum and minimum dimensions, the parts will touch, respectively, points cI and c3 of the eccentric, symmetrically located relative to point c2. Then the active profile of the eccentric will be the arc С1С3. In this case, the part of the eccentric, limited on the figure by a dashed line, can be removed (in this case, the handle must be rearranged to another place).

The angle a between the clamped surface and the normal to the radius of rotation is called the angle of elevation. It is different for different angular positions of the eccentric. It can be seen from the scan that when the part and the eccentric touch points a and B, the angle a is equal to zero. Its value is greatest when the eccentric is touched by point c2. At small angles of the wedges, jamming is possible, at large angles - spontaneous weakening. Therefore, clamping when touching the detail of the eccentric points a and b is undesirable. For a calm and reliable fastening of the part, it is necessary that the eccentric comes into contact in the section C \ C3 with the part, when the angle a is not equal to zero and cannot fluctuate over a wide range.

It is difficult to imagine a carpentry workshop without a circular saw, since the most basic and common operation is the longitudinal sawing of workpieces. How to make a homemade circular saw will be discussed in this article.

Introduction

The machine consists of three main structural elements:

• base;
• sawing table;
• parallel stop.

The base and the sawing table itself are not very complex structural elements. Their design is obvious and not so complicated. Therefore, in this article we will consider the most complex element - the parallel emphasis.

So, the parallel stop is the movable part of the machine, which is the guide for the workpiece and it is along it that the workpiece moves. Accordingly, the quality of the cut depends on the parallel stop, because if the stop is not parallel, then either the workpiece or the saw curve may jam.

In addition, the rip fence of a circular saw must be of a fairly rigid construction, as the worker is exerting force by pressing the workpiece against the fence, and if the fence is allowed to move, this will lead to non-parallelism with the consequences indicated above.

There are various designs of parallel stops, depending on the methods of its attachment to the circular table. Here is a table with the characteristics of these options.

Rip fence design	Advantages and disadvantages
Two-point attachment (front and back)	Advantages:· Pretty rigid construction · Allows you to place the stop in any place of the circular table (to the left or right of the saw blade); Does not require the massiveness of the guide itself Flaw:· For fastening, the master needs to clamp one end in front of the machine, and also go around the machine around and fix the opposite end of the stop. This is very inconvenient when selecting the required position of the stop and is a significant drawback with frequent readjustment.
Single point attachment (front)	Advantages:· Less rigid construction than when fixing the fence in two points · Allows you to place the fence in any place of the circular table (to the left or right of the saw blade); · To change the position of the stop, it is enough to fix it on one side of the machine, where the master is located during the sawing process. Flaw:· The design of the stop must be massive in order to provide the necessary rigidity of the structure.
Fastening in the groove of the circular table	Advantages:· Fast changeover. Flaw: Complexity of the design, Loosening of the circular table structure, Fixed position from the line of the saw blade, Quite a complex design for self-manufacturing, especially from wood (made only from metal).

In this article, we will analyze the option of creating a design of a parallel stop for a circular with one attachment point.

Preparation for work

Before starting work, it is necessary to determine the necessary set of tools and materials that will be needed in the process.

The following tools will be used for work:

1. Circular saw or can be used.
2. Screwdriver.
3. Bulgarian (Angle grinder).
4. Hand tools: hammer, pencil, square.

In the process, you will also need the following materials:

1. Plywood.
2. Massive pine.
3. Steel tube with an inner diameter of 6-10 mm.
4. Steel rod with an outer diameter of 6-10 mm.
5. Two washers with an increased area and an inner diameter of 6-10 mm.
6. Self-tapping screws.
7. Joiner's glue.

The design of the stop of the circular machine

The whole structure consists of two main parts - longitudinal and transverse (meaning - relative to the plane of the saw blade). Each of these parts is rigidly connected to the other and is a complex structure that includes a set of parts.

The pressing force is large enough to ensure structural strength and securely fix the entire rip fence.

From a different angle.

The general composition of all parts is as follows:

• The base of the transverse part;

1. Longitudinal part

, 2 pcs.);
• The base of the longitudinal part;

1. clamp

• Cam handle

Making a circular

Preparation of blanks

A couple of things to note:

• planar longitudinal elements are made from, and not from solid pine, like other parts.

At 22 mm, we drill a hole in the end for the handle.

It is better to do this with drilling, but you can just fill it with a nail.

In the circular saw used for work, a home-made movable carriage is used from (or as an option, you can make a false table “in haste”), which is not very a pity to deform or spoil. We drive a nail into this carriage in the marked place and bite off the hat.

As a result, we get an even cylindrical workpiece, which must be processed with a belt or eccentric grinder.

We make the handle - this is a cylinder with a diameter of 22 mm and a length of 120-200 mm. Then we glue it into the eccentric.

Cross section of the guide

We proceed to the manufacture of the transverse part of the guide. It consists, as mentioned above, of the following details:

• The base of the transverse part;
• Upper transverse clamping bar (with oblique end);
• Lower transverse clamping bar (with oblique end);
• End (fixing) bar of the transverse part.

Upper cross clamp

Both clamping bars - upper and lower have one end not straight 90º, but inclined ("oblique") with an angle of 26.5º (to be precise, 63.5º). We have already observed these angles when sawing blanks.

The upper transverse clamping bar is used to move along the base and further fix the guide by pressing it against the lower transverse clamping bar. It is assembled from two blanks.

Both clamping bars are ready. It is necessary to check the smoothness of the move and remove all defects that prevent smooth sliding, in addition, it is necessary to check the tightness of the inclined edges; gaps and cracks should not be.

With a snug fit, the strength of the connection (fixing the guide) will be maximum.

Assembly of the transverse whole part

Longitudinal part of the guide

The entire longitudinal part consists of:

, 2 pcs.);
• The base of the longitudinal part.

This element is made from the fact that the surface is laminated and smoother - this reduces friction (improves sliding), as well as denser and stronger - more durable.

At the stage of forming the blanks, we have already sawed them to size, it remains only to ennoble the edges. This is done with edging tape.

The edging technology is simple (you can even glue it with an iron!) And understandable.

The base of the longitudinal part

And also additionally fix with self-tapping screws. Do not forget to observe the 90º angle between the longitudinal and vertical elements.

Assembly of the transverse and longitudinal parts.

Right here VERY!!! it is important to observe the angle of 90º, since the parallelism of the guide with the plane of the saw blade will depend on it.

Installation of the eccentric

Guide rail installation

It's time to fix our entire structure on a circular machine. To do this, you need to attach the bar of the transverse stop to the circular table. Fastening, as elsewhere, is carried out with glue and self-tapping screws.

... and we consider the work finished - the do-it-yourself circular saw is ready.

Video

The video on which this material was made.

Two types of eccentric mechanisms are used in fixtures:

1. Circular eccentrics.

2. Curvilinear eccentrics.

The type of eccentric is determined by the shape of the curve in the working area.

Working surface circular eccentrics– a circle of constant diameter with an offset axis of rotation. The distance between the center of the circle and the axis of rotation of the eccentric is called the eccentricity ( e).

Consider the scheme of a circular eccentric (Fig.5.19). Line passing through the center of the circle O 1 and center of rotation O 2 circular eccentrics, divides it into two symmetrical sections. Each of them is a wedge located on a circle described from the center of rotation of the eccentric. Eccentric lift angle α (the angle between the clamping surface and the normal to the radius of rotation) form the radius of the eccentric circle R and radius of rotation r, drawn from their centers to the point of contact with the part.

The angle of elevation of the working surface of the eccentric is determined by the dependence

Eccentricity; - angle of rotation of the eccentric.

Figure 5.19 - Calculation scheme of the eccentric

where is the gap for free entry of the workpiece under the eccentric ( S1= 0.2 ... 0.4 mm); T- workpiece size tolerance in clamping direction; - power reserve of the eccentric, which protects it from crossing the dead center (= 0.4 ... 0.6 mm); y– deformation in the contact zone;

where Q is the force at the contact point of the eccentric; - rigidity of the clamping device,

The disadvantages of circular eccentrics include a change in the angle of elevation α when turning the eccentric (hence the clamping force). Figure 5.20 shows the profile of the development of the working surface of the eccentric when it is rotated through an angle ρ . In the initial stage at ρ = 0° elevation angle α = 0°. With further rotation of the eccentric, the angle α increases, reaching a maximum (α Max) at ρ = 90°. Further rotation leads to a decrease in the angle α , and at ρ = 180° the angle of elevation is zero again α =0°

Rice. 5.20 - Development of the eccentric.

The equations of forces in a circular eccentric can be written with sufficient accuracy for practical calculations, by analogy with the calculation of the forces of a flat one-sided wedge with an angle at the point of contact. Then the force on the handle length can be determined by the formula

where l- distance from the axis of rotation of the eccentric to the point of application of force W; r is the distance from the axis of rotation to the point of contact ( Q); - angle of friction between the eccentric and the workpiece; - angle of friction on the axis of rotation of the eccentric.

Self-braking of circular eccentrics is ensured by the ratio of its outer diameter D to eccentricity. This ratio is called the characteristic of the eccentric.

Round eccentrics are made of steel 20X, cemented to a depth of 0.8…1.2 mm and then hardened to a hardness of HRC 55…60. The dimensions of the round eccentric must be applied taking into account GOST 9061-68 and GOST 12189-66. Standard circular eccentrics have dimensions D = 32-80 mm and e = 1.7 - 3.5 mm. The disadvantages of circular eccentrics include a small linear stroke, the inconstancy of the angle of elevation, and, consequently, the clamping force when fixing workpieces with large dimensional fluctuations in the direction of the clamp.

Figure 5.21 shows a normalized eccentric fixture for clamping workpieces. The workpiece 3 is mounted on fixed supports 2 and is pressed against them by a bar 4. When the workpiece is clamped, a force is applied to the eccentric handle 6 W, and it rotates about its axis, leaning on the heel 7. The force arising in this case on the axis of the eccentric R is transmitted through bar 4 to the part.

Figure 5.21 - Normalized eccentric clamp

Depending on the dimensions of the plank ( l 1 and l 2) we get the clamping force Q. The bar 4 is pressed against the head 5 of the screw 1 by a spring. The eccentric 6 with the bar 4 moves to the right after unclamping the part.

Curvilinear cams, unlike circular eccentrics, are characterized by a constant angle of elevation, which provides the same self-braking properties at any angle of rotation of the cam.

The working surface of such cams is made in the form of a logarithmic or Archimedean spiral.

With a working profile in the form of a logarithmic spiral, the radius vector of the cam ( R) is determined by the dependence

p = Ce a G

where FROM- constant; e - base of natural logarithms; a - coefficient of proportionality; G- polar angle.

If a profile is used, made according to the Archimedean spiral, then

p=aG .

If the first equation is presented in logarithmic form, then it, like the second equation, in Cartesian coordinates will represent a straight line. Therefore, the construction of cams with working surfaces in the form of a logarithmic or Archimedean spiral can be performed with sufficient accuracy simply if the values R, taken from the graph in Cartesian coordinates, set aside from the center of the circle in polar coordinates. In this case, the diameter of the circle is selected depending on the required eccentric stroke ( h) (Fig. 5.22).

Figure 5.22 - Curvilinear Cam Profile

These eccentrics are made from steels 35 and 45. External working surfaces are heat treated to a hardness of HRC 55…60. The main dimensions of curvilinear eccentrics are normalized.

Good day to lovers of homemade devices. When there is no vice at hand or they simply are not available, then the easiest solution is to assemble something similar yourself, since special skills and hard-to-reach materials are not required to assemble the clamp. In this article, I will show you how to make a wooden clip.

In order to assemble your clamp, you need to find a strong type of wood so that it can withstand heavy loads. In this case, an oak plank is well suited.

In order to proceed to the manufacturing stage necessary:
* Bolt, the size of which is better to take in the region of 12-14mm.
* A nut for a bolt.
* Bars made of oak wood.
* Part of the profile made of wood with a section of 15mm.
* Joiner's glue or parquet.
* Epoxy.
* Lacquer, can be replaced with stain.
*Metal rod 3 mm.
*Small diameter drill.
* Chisel or chisel.
*Hacksaw for wood.
*A hammer.
*Electric drill.
* Medium grit sandpaper.
*Vise and clamp.

First step. Depending on your requests, the size of the clamp can be made different, in this case, the author cuts out sticks measuring 3.5 x 3 x 3.5 cm - one piece and 1.8 x 3 x 7.5 cm - two pieces.

After that, we clamp a bar 75 mm long in a vice and drill a hole with a drill, stepping back from the edge 1-2 cm.

Next, match the hole you just made with the hole in the nut and circle the outline with a pencil. After marking, armed with a chisel and a hammer, cut out a hex for the nut.

Second step. To fix the nut in the bar, it is necessary to coat the machined groove with epoxy resin inside and immerse the same nut there, drowning it a little in the bar.

As a rule, complete drying of the epoxy resin is achieved after 24 hours, after which you can proceed to the next stage of assembly.
Third step. The bolt, which ideally fits our fixed nut in the beam, needs to be modified, for this we take a drill and drill a hole close to its hexagonal head.

After that, we move on to the bars, they must be combined together so that the bars are longer on the sides, and the bar is shorter between them. Before the three beams are clamped together, it is necessary to drill holes in the place of fastening with a thin drill so that the workpiece does not split, because this arrangement does not suit us.

Using a screwdriver, we twist the screws into the finished drilling places, having previously smeared the joints between each other with glue.

We fix the almost finished clamping mechanism with a clamp and wait for the glue to dry. For convenient use of the clamp, you need a lever with which you can clamp your workpieces, it will just serve as a metal rod and a round-profile piece of wood with a section of 15 mm sawn into two parts, in both you need to drill a hole for the rod and put it all on glue.

The final stage. To complete the assembly, you need varnish or stain, we grind our homemade clamp, and then varnish it in several layers.

On this, the manufacture of the clamp with your own hands is ready and it will go into working condition when the varnish dries completely, after which you can work with this device with complete confidence.

It is difficult to imagine a carpentry workshop without a circular saw, since the most basic and common operation is the longitudinal sawing of workpieces. How to make a homemade circular saw will be discussed in this article.

Introduction

The machine consists of three main structural elements:

• base;
• sawing table;
• parallel stop.

The base and the sawing table itself are not very complex structural elements. Their design is obvious and not so complicated. Therefore, in this article we will consider the most complex element - the parallel emphasis.

So, the parallel stop is the movable part of the machine, which is the guide for the workpiece and it is along it that the workpiece moves. Accordingly, the quality of the cut depends on the parallel stop, because if the stop is not parallel, then either the workpiece or the saw curve may jam.

In addition, the rip fence of a circular saw must be of a fairly rigid construction, as the worker is exerting force by pressing the workpiece against the fence, and if the fence is allowed to move, this will lead to non-parallelism with the consequences indicated above.

There are various designs of parallel stops, depending on the methods of its attachment to the circular table. Here is a table with the characteristics of these options.

Rip fence design	Advantages and disadvantages
Two-point attachment (front and back)	Advantages:· Pretty rigid construction · Allows you to place the stop in any place of the circular table (to the left or right of the saw blade); Does not require the massiveness of the guide itself Flaw:· For fastening, the master needs to clamp one end in front of the machine, and also go around the machine around and fix the opposite end of the stop. This is very inconvenient when selecting the required position of the stop and is a significant drawback with frequent readjustment.
Single point attachment (front)	Advantages:· Less rigid construction than when fixing the fence in two points · Allows you to place the fence in any place of the circular table (to the left or right of the saw blade); · To change the position of the stop, it is enough to fix it on one side of the machine, where the master is located during the sawing process. Flaw:· The design of the stop must be massive in order to provide the necessary rigidity of the structure.
Fastening in the groove of the circular table	Advantages:· Fast changeover. Flaw: Complexity of the design, Loosening of the circular table structure, Fixed position from the line of the saw blade, Quite a complex design for self-manufacturing, especially from wood (made only from metal).

In this article, we will analyze the option of creating a design of a parallel stop for a circular with one attachment point.

Preparation for work

Before starting work, it is necessary to determine the necessary set of tools and materials that will be needed in the process.

The following tools will be used for work:

1. Circular saw or can be used.
2. Screwdriver.
3. Bulgarian (Angle grinder).
4. Hand tools: hammer, pencil, square.

In the process, you will also need the following materials:

1. Plywood.
2. Massive pine.
3. Steel tube with an inner diameter of 6-10 mm.
4. Steel rod with an outer diameter of 6-10 mm.
5. Two washers with an increased area and an inner diameter of 6-10 mm.
6. Self-tapping screws.
7. Joiner's glue.

The design of the stop of the circular machine

The whole structure consists of two main parts - longitudinal and transverse (meaning - relative to the plane of the saw blade). Each of these parts is rigidly connected to the other and is a complex structure that includes a set of parts.

The pressing force is large enough to ensure structural strength and securely fix the entire rip fence.

From a different angle.

The general composition of all parts is as follows:

• The base of the transverse part;

1. Longitudinal part

, 2 pcs.);
• The base of the longitudinal part;

1. clamp

• Cam handle

Making a circular

Preparation of blanks

A couple of things to note:

• planar longitudinal elements are made from, and not from solid pine, like other parts.

At 22 mm, we drill a hole in the end for the handle.

It is better to do this with drilling, but you can just fill it with a nail.

In the circular saw used for work, a home-made movable carriage is used from (or as an option, you can make a false table “in haste”), which is not very a pity to deform or spoil. We drive a nail into this carriage in the marked place and bite off the hat.

As a result, we get an even cylindrical workpiece, which must be processed with a belt or eccentric grinder.

We make the handle - this is a cylinder with a diameter of 22 mm and a length of 120-200 mm. Then we glue it into the eccentric.

Cross section of the guide

We proceed to the manufacture of the transverse part of the guide. It consists, as mentioned above, of the following details:

• The base of the transverse part;
• Upper transverse clamping bar (with oblique end);
• Lower transverse clamping bar (with oblique end);
• End (fixing) bar of the transverse part.

Upper cross clamp

Both clamping bars - upper and lower have one end not straight 90º, but inclined ("oblique") with an angle of 26.5º (to be precise, 63.5º). We have already observed these angles when sawing blanks.

The upper transverse clamping bar is used to move along the base and further fix the guide by pressing it against the lower transverse clamping bar. It is assembled from two blanks.

Both clamping bars are ready. It is necessary to check the smoothness of the move and remove all defects that prevent smooth sliding, in addition, it is necessary to check the tightness of the inclined edges; gaps and cracks should not be.

With a snug fit, the strength of the connection (fixing the guide) will be maximum.

Assembly of the transverse whole part

Longitudinal part of the guide

The entire longitudinal part consists of:

, 2 pcs.);
• The base of the longitudinal part.

This element is made from the fact that the surface is laminated and smoother - this reduces friction (improves sliding), as well as denser and stronger - more durable.

At the stage of forming the blanks, we have already sawed them to size, it remains only to ennoble the edges. This is done with edging tape.

The edging technology is simple (you can even glue it with an iron!) And understandable.

The base of the longitudinal part

And also additionally fix with self-tapping screws. Do not forget to observe the 90º angle between the longitudinal and vertical elements.

Assembly of the transverse and longitudinal parts.

Right here VERY!!! it is important to observe the angle of 90º, since the parallelism of the guide with the plane of the saw blade will depend on it.

Installation of the eccentric

Guide rail installation

It's time to fix our entire structure on a circular machine. To do this, you need to attach the bar of the transverse stop to the circular table. Fastening, as elsewhere, is carried out with glue and self-tapping screws.

... and we consider the work finished - the do-it-yourself circular saw is ready.

Video

The video on which this material was made.

Good day to lovers of homemade devices. When there is no vice at hand or they simply are not available, then the easiest solution is to assemble something similar yourself, since special skills and hard-to-reach materials are not required to assemble the clamp. In this article, I will show you how to make a wooden clip.

In order to assemble your clamp, you need to find a strong type of wood so that it can withstand heavy loads. In this case, an oak plank is well suited.

In order to proceed to the manufacturing stage necessary:
* Bolt, the size of which is better to take in the region of 12-14mm.
* A nut for a bolt.
* Bars made of oak wood.
* Part of the profile made of wood with a section of 15mm.
* Joiner's glue or parquet.
* Epoxy.
* Lacquer, can be replaced with stain.
*Metal rod 3 mm.
*Small diameter drill.
* Chisel or chisel.
*Hacksaw for wood.
*A hammer.
*Electric drill.
* Medium grit sandpaper.
*Vise and clamp.

First step. Depending on your requests, the size of the clamp can be made different, in this case, the author cuts out sticks measuring 3.5 x 3 x 3.5 cm - one piece and 1.8 x 3 x 7.5 cm - two pieces.

After that, we clamp a bar 75 mm long in a vice and drill a hole with a drill, stepping back from the edge 1-2 cm.

Next, match the hole you just made with the hole in the nut and circle the outline with a pencil. After marking, armed with a chisel and a hammer, cut out a hex for the nut.

Second step. To fix the nut in the bar, it is necessary to coat the machined groove with epoxy resin inside and immerse the same nut there, drowning it a little in the bar.

As a rule, complete drying of the epoxy resin is achieved after 24 hours, after which you can proceed to the next stage of assembly.
Third step. The bolt, which ideally fits our fixed nut in the beam, needs to be modified, for this we take a drill and drill a hole close to its hexagonal head.

After that, we move on to the bars, they must be combined together so that the bars are longer on the sides, and the bar is shorter between them. Before the three beams are clamped together, it is necessary to drill holes in the place of fastening with a thin drill so that the workpiece does not split, because this arrangement does not suit us.

Using a screwdriver, we twist the screws into the finished drilling places, having previously smeared the joints between each other with glue.

We fix the almost finished clamping mechanism with a clamp and wait for the glue to dry. For convenient use of the clamp, you need a lever with which you can clamp your workpieces, it will just serve as a metal rod and a round-profile piece of wood with a section of 15 mm sawn into two parts, in both you need to drill a hole for the rod and put it all on glue.

The final stage. To complete the assembly, you need varnish or stain, we grind our homemade clamp, and then varnish it in several layers.

On this, the manufacture of the clamp with your own hands is ready and it will go into working condition when the varnish dries completely, after which you can work with this device with complete confidence.

Two types of eccentric mechanisms are used in fixtures:

1. Circular eccentrics.

2. Curvilinear eccentrics.

The type of eccentric is determined by the shape of the curve in the working area.

Working surface circular eccentrics– a circle of constant diameter with an offset axis of rotation. The distance between the center of the circle and the axis of rotation of the eccentric is called the eccentricity ( e).

Consider the scheme of a circular eccentric (Fig.5.19). Line passing through the center of the circle O 1 and center of rotation O 2 circular eccentrics, divides it into two symmetrical sections. Each of them is a wedge located on a circle described from the center of rotation of the eccentric. Eccentric lift angle α (the angle between the clamping surface and the normal to the radius of rotation) form the radius of the eccentric circle R and radius of rotation r, drawn from their centers to the point of contact with the part.

The angle of elevation of the working surface of the eccentric is determined by the dependence

Eccentricity; - angle of rotation of the eccentric.

Figure 5.19 - Calculation scheme of the eccentric

where is the gap for free entry of the workpiece under the eccentric ( S1= 0.2 ... 0.4 mm); T- workpiece size tolerance in clamping direction; - power reserve of the eccentric, which protects it from crossing the dead center (= 0.4 ... 0.6 mm); y– deformation in the contact zone;

where Q is the force at the contact point of the eccentric; - rigidity of the clamping device,

The disadvantages of circular eccentrics include a change in the angle of elevation α when turning the eccentric (hence the clamping force). Figure 5.20 shows the profile of the development of the working surface of the eccentric when it is rotated through an angle ρ . In the initial stage at ρ = 0° elevation angle α = 0°. With further rotation of the eccentric, the angle α increases, reaching a maximum (α Max) at ρ = 90°. Further rotation leads to a decrease in the angle α , and at ρ = 180° the angle of elevation is zero again α =0°

Rice. 5.20 - Development of the eccentric.

The equations of forces in a circular eccentric can be written with sufficient accuracy for practical calculations, by analogy with the calculation of the forces of a flat one-sided wedge with an angle at the point of contact. Then the force on the handle length can be determined by the formula

where l- distance from the axis of rotation of the eccentric to the point of application of force W; r is the distance from the axis of rotation to the point of contact ( Q); - angle of friction between the eccentric and the workpiece; - angle of friction on the axis of rotation of the eccentric.

Self-braking of circular eccentrics is ensured by the ratio of its outer diameter D to eccentricity. This ratio is called the characteristic of the eccentric.

Round eccentrics are made of steel 20X, cemented to a depth of 0.8…1.2 mm and then hardened to a hardness of HRC 55…60. The dimensions of the round eccentric must be applied taking into account GOST 9061-68 and GOST 12189-66. Standard circular eccentrics have dimensions D = 32-80 mm and e = 1.7 - 3.5 mm. The disadvantages of circular eccentrics include a small linear stroke, the inconstancy of the angle of elevation, and, consequently, the clamping force when fixing workpieces with large dimensional fluctuations in the direction of the clamp.

Figure 5.21 shows a normalized eccentric fixture for clamping workpieces. The workpiece 3 is mounted on fixed supports 2 and is pressed against them by a bar 4. When the workpiece is clamped, a force is applied to the eccentric handle 6 W, and it rotates about its axis, leaning on the heel 7. The force arising in this case on the axis of the eccentric R is transmitted through bar 4 to the part.

Figure 5.21 - Normalized eccentric clamp

Depending on the dimensions of the plank ( l 1 and l 2) we get the clamping force Q. The bar 4 is pressed against the head 5 of the screw 1 by a spring. The eccentric 6 with the bar 4 moves to the right after unclamping the part.

Curvilinear cams, unlike circular eccentrics, are characterized by a constant angle of elevation, which provides the same self-braking properties at any angle of rotation of the cam.

The working surface of such cams is made in the form of a logarithmic or Archimedean spiral.

With a working profile in the form of a logarithmic spiral, the radius vector of the cam ( R) is determined by the dependence

p = Ce a G

where FROM- constant; e - base of natural logarithms; a - coefficient of proportionality; G- polar angle.

If a profile is used, made according to the Archimedean spiral, then

p=aG .

If the first equation is presented in logarithmic form, then it, like the second equation, in Cartesian coordinates will represent a straight line. Therefore, the construction of cams with working surfaces in the form of a logarithmic or Archimedean spiral can be performed with sufficient accuracy simply if the values R, taken from the graph in Cartesian coordinates, set aside from the center of the circle in polar coordinates. In this case, the diameter of the circle is selected depending on the required eccentric stroke ( h) (Fig. 5.22).

Figure 5.22 - Curvilinear Cam Profile

These eccentrics are made from steels 35 and 45. External working surfaces are heat treated to a hardness of HRC 55…60. The main dimensions of curvilinear eccentrics are normalized.

The eccentric clamp is a clamping element of improved design. Eccentric clamps (ECM) are used for direct clamping of workpieces and in complex clamping systems.

Manual screw clamps are simple in design, but have a significant drawback - to secure the part, the worker must perform a large number of rotational movements with a key, which requires additional time and effort and, as a result, reduces labor productivity.

These considerations force, where possible, to replace manual screw clamps with quick-acting ones.

The most widespread and

Although it differs in speed, it does not provide a large clamping force on the part, therefore it is used only with relatively small cutting forces.

Advantages:

• simplicity and compact design;
• widespread use in the design of standardized parts;
• ease of setup;
• the ability to self-brake;
• speed (operating time of the drive is about 0.04 min).

Flaws:

• the concentrated nature of the forces, which does not allow the use of eccentric mechanisms for fixing non-rigid workpieces;
• clamping forces with round eccentric cams are unstable and depend significantly on the dimensions of the workpieces;
• reduced reliability due to intensive wear of the eccentric cams.

Rice. 113. Eccentric clamp: a - the part is not clamped; b - position with clamped part

Eccentric clamp design

Round eccentric 1, which is a disk with a hole offset from its center, is shown in fig. 113, a. The eccentric is freely mounted on axis 2 and can rotate around it. The distance e between the center C of disk 1 and the center O of the axis is called the eccentricity.

A handle 3 is attached to the eccentric, by turning which the part is clamped at point A (Fig. 113, b). From this figure, you can see that the eccentric works like a curved wedge (see shaded area). In order to prevent the eccentrics from moving away after clamping, they must be self-braking and. The self-braking property of the eccentrics is ensured by the correct choice of the ratio of the diameter D of the eccentric to its eccentricity e. The ratio D / e is called the characteristic of the eccentric.

With a friction coefficient f = 0.1 (friction angle 5°43"), the characteristic of the eccentric must be D/e ≥ 20, and with a friction coefficient f = 0.15 (friction angle 8°30") D/e ≥ 14.

Thus, all eccentric clamps, in which the diameter D is 14 times greater than the eccentricity e, have the property of self-braking, i.e., provide a reliable clamp.

Figure 5.5 - Schemes for calculating eccentric cams: a - round, non-standard; b- made in the spiral of Archimedes.

The composition of eccentric clamping mechanisms includes eccentric cams, supports for them, trunnions, handles and other elements. There are three types of eccentric cams: round with a cylindrical working surface; curvilinear, the working surfaces of which are outlined along the Archimedes spiral (less often - along the involute or logarithmic spiral); end.

Round eccentrics

The most widespread, due to ease of manufacture, are round eccentrics.

A round eccentric (in accordance with Figure 5.5a) is a disk or roller rotated around an axis shifted relative to the geometric axis of the eccentric by an amount A, called eccentricity.

Curvilinear eccentric cams (according to Figure 5.5b) provide a stable clamping force and a larger (up to 150°) angle of rotation compared to round ones.

Cam materials

Eccentric jaws are made of steel 20X with carburizing to a depth of 0.8 ... 1.2 mm and hardening to a hardness of HRCe 55-61.

Eccentric cams are distinguished by the following designs: round eccentric (GOST 9061-68), eccentric (GOST 12189-66), eccentric double (GOST 12190-66), eccentric forked (GOST 12191-66), eccentric double-support (GOST 12468-67) .

The practical use of eccentric mechanisms in various clamping devices is shown in Figure 5.7

Figure 5.7 - Types of eccentric clamping mechanisms

Calculation of eccentric clamps

The initial data for determining the geometric parameters of the eccentrics are: the tolerance δ of the size of the workpiece from its mounting base to the place of application of the clamping force; angle a of rotation of the eccentric from the zero (initial) position; the required force FZ of clamping the workpiece. The main design parameters of eccentrics are: eccentricity A; diameter dц and width b of the pin (axis) of the eccentric; outer diameter of the eccentric D; width of the working part of the eccentric B.

Calculations of eccentric clamping mechanisms are performed in the following sequence:

Calculation of clamps with a standard eccentric round cam (GOST 9061-68)

1. Determine the move hto eccentric cam, mm.:

If the angle of rotation of the eccentric cam is unlimited (a ≤ 130°), then

where δ - workpiece size tolerance in the direction of the clamp, mm;

D gar = 0.2 ... 0.4 mm - guaranteed clearance for easy installation and removal of the workpiece;

J = 9800…19600 kN/m – rigidity of the eccentric EPM;

D = 0.4...0.6 hk mm - power reserve, taking into account wear and manufacturing errors of the eccentric cam.

If the angle of rotation of the eccentric cam is limited (a ≤ 60°), then

2. Using tables 5.5 and 5.6 select a standard eccentric cam. In this case, the following conditions must be met: Fz ≤ Fh max and hto≤ h(dimensions, material, heat treatment and other specifications in accordance with GOST 9061-68. There is no need to check the standard eccentric cam for strength.

Table 5.5 - Standard round eccentric cam (GOST 9061-68)

Designation	Outer eccentric cam, mm	Eccentricity,	Cam travel h, mm, not less than
			Angle of rotation limited a≤60°	Angle of rotation limited a≤130°
Note: For eccentric cams 7013-0171…1013-0178, the values ​​of Fc max and Mmax are calculated according to the strength parameter, and for the rest - taking into account the requirements of ergonomics with the maximum length of the handle L=320 mm.

3. Determine the length of the handle of the eccentric mechanism, mm

Values M max and P h max are selected according to table 5.5.

Table 5.6 - Cams eccentric round (GOST 9061-68). Dimensions, mm

Drawing - drawing of an eccentric cam

Do-it-yourself eccentric clamp

The video will tell you how to make a homemade eccentric clamp designed to fix the workpiece. Do-it-yourself eccentric clamp.

With large production programs, quick-acting clamps are widely used. One of the types of such manual clamps are eccentric, in which clamping forces are created by turning the eccentrics.

Significant efforts with a small area of ​​contact with the working surface of the eccentric can cause damage to the surface of the part. Therefore, usually the eccentric acts on the part through the lining, pushers, levers or rods.

Clamping eccentrics can be with a different profile of the working surface: in the form of a circle (round eccentrics) and with a spiral profile (in the form of a logarithmic or Archimedean spiral).

A round eccentric is a cylinder (roller or cam), the axis of which is located eccentrically with respect to the axis of rotation (Fig. 176, a, biv). Such eccentrics are the easiest to manufacture. A handle is used to rotate the eccentric. Eccentric clamps are often made in the form of crank rollers with one or two bearings.

Eccentric clamps are always manual, therefore the main condition for their correct operation is to maintain the angular position of the eccentric after it has been rotated for clamping - “eccentric self-braking”. This property of the eccentric is determined by the ratio of the diameter O of the cylindrical working surface to the eccentricity e. This ratio is called the characteristic of the eccentric. At a certain ratio, the condition of self-braking of the eccentric is fulfilled.

Usually, the diameter B of a round eccentric is set from design considerations, and the eccentricity e is calculated based on self-braking conditions.

The line of symmetry of the eccentric divides it into two parts. One can imagine two wedges, one of which, when the eccentric is turned, fixes the part. The position of the eccentric when it contacts the surface of the smallest part.

Usually, the position of the section of the profile of the eccentric, which is involved in the work, is chosen as follows. so that with the horizontal position of the lines 0 \ 02, the eccentric would touch the point c2 of the clamped fly of medium size. When clamping parts with maximum and minimum dimensions, the parts will touch, respectively, points cI and c3 of the eccentric, symmetrically located relative to point c2. Then the active profile of the eccentric will be the arc С1С3. In this case, the part of the eccentric, limited on the figure by a dashed line, can be removed (in this case, the handle must be rearranged to another place).

The angle a between the clamped surface and the normal to the radius of rotation is called the angle of elevation. It is different for different angular positions of the eccentric. It can be seen from the scan that when the part and the eccentric touch points a and B, the angle a is equal to zero. Its value is greatest when the eccentric is touched by point c2. At small angles of the wedges, jamming is possible, at large angles - spontaneous weakening. Therefore, clamping when touching the detail of the eccentric points a and b is undesirable. For a calm and reliable fastening of the part, it is necessary that the eccentric comes into contact in the section C \ C3 with the part, when the angle a is not equal to zero and cannot fluctuate over a wide range.

Eccentric screed (rasteks, minifixes, eccentric clamp - whoever calls it) is one of the most common types of furniture fasteners.

Minifixes are good because the parts pulled together with their help can be disassembled and reassembled many times, without loss of rigidity, which would not work, where with each assembly / disassembly, the mount will lose rigidity.

There is only one minus for a furniture minifix - this is the painstaking work of installing it. If you do not have expensive filler equipment, for do-it-yourself installation, you need to very carefully mark and accurately drill three different holes in three different planes, which usually takes a lot of time and effort.

This work does not tolerate oversights in markup. After all, you will not be able to adjust the connection in the end.

Also, its cost cannot be called very cheap. The price of a minifix is ​​usually 3-4 times more expensive than a confirmation.

Therefore, it should be used in the most necessary cases.

An eccentric clamp is used in places where parts are fastened (T- or L-shaped), the connection of which must be hidden from prying eyes. For example, they are attached:

• Table tops of computer and other tables made of chipboard
• Dresser tops
• Bottom and roofs and other parts where it is not possible to drill holes on the front of the part.

The installed rod of the minifix of the eccentric clamp is completely hidden in the body of the chipboard, and only the eccentric remains visible, which is installed on the inside of the product.

Types of eccentric screed

Depending on the manufacturer, there are several modifications of the minifix, which includes:

• Stock (rastex)
• Eccentric (minifix)
• Plastic or metal sleeve (depending on the manufacturer)
• Minifix stub (optional)

There are also corner (hinged) and double-sided ties. But to use them, you need to be a complete pervert, as well as think carefully about where they can be applied. In our time, they have practically ceased to be used due to uselessness.

The eccentric clamp remains popular today, the stem of which is already threaded for chipboard, without a plastic sleeve. That is, it consists of only two parts: a rod and an eccentric.

But, just in case, in this article we will analyze the installation of two types of this fastener - both with and without a sleeve.

Installation instructions for eccentric tie (without bushing)

Required tool:

• screwdriver
• Mill "Forstner" 15 mm
• Drill bit 7 mm (for stem body)
• Drill 5 mm or confirmed (for screwing in the stem)
• Ruler, awl, pencil

The standard thickness of the screed rod body is 6 mm, and the length is 44 mm. The diameter of the eccentric is 15 mm and its depth is 12.5 mm. Photo of the eccentric and stem:

As mentioned above, to install a minifix in the parts to be joined, you need to make three holes of different diameters.

So let's start building.

For quality, so that the eccentric captures the head of the rod, it should look out by 6 mm:

A hole is made for screwing the rod into the chipboard with a 5 mm (or confirmed) drill, if it is a sidewall, its center should be located at a distance of 8 mm from the edge, 10-11 mm deep (the rod must be screwed tightly and to the very end, according to the mark, this can be seen on the picture).

In another part, markings are made for two holes.

The first - at a center distance of 34 mm from the edge, under the hole with a Forstner cutter with a diameter of 15 mm. Its depth must be equal to the thickness of the eccentric (about 12 mm) so that the eccentric enters the part “flush”.

The second hole is made at the end of the part, strictly in the center, with a 7 mm drill (1 mm more than the stem body).

Installing a tie with a plastic sleeve

The principle of assembling a minifix with a sleeve is exactly the same as when installing a metal minifix, with the only difference - need another hole for the rod.

Video: installing a furniture eccentric tie