DE1267043B - Band clamp for hoses u. like - Google Patents

Description

Band clamp for hoses and the like The invention relates to a band clamp for clamping hoses and the like, consisting of a flat metal strip, which tightly encloses the hose leaving a short circumferential section free and on both sides of the short section to form a radially protruding, is bent from three substantially straight sections consisting of loop.

There are already band clamps known that consist of a closed There are metal band, which is bent substantially circular and at least on the circumference has two outwardly facing loops. The loops consist of two themselves adjoining the circular arc-shaped sections of the band clamp, parallel to outwardly facing side pieces and one connecting the outer ends of these pieces, transversely to this running cross piece. The band clamp can be pushed over the hose and tightened at the point of attachment by pulling the side bars on their inner Ends are pressed together with a pair of pliers. During this tensioning or tightening the band clamp bend the side pieces and also the cross piece, so that the Loop a substantially circular shape open to the surface of the tube receives.

The reaction forces exerted by the hose lead to tensile stress in the part of the tape that tries to bend the loop open at its open end. The metal strip, whose bending resistance is parallel to its broad side by one running axis is only slight, stressed in bending and leads to loosening the clamp connection, so that leaks occur at the connection point of the hose and the hose can slide off its socket. Such a hose connection is particularly at risk if the diameter of the hose to be clamped lies in its outer tolerance range and the side bars of the loop when tensioning can only be squeezed a little so that they are at an angle of about 90 ° to the subsequent curved section of the tape point.

The invention is based on the object of a cheap to manufacture To create band clamps that have a high clamping force due to the shape of their loop has and ensures a secure seal even if the diameter of the hose to be clamped lies in the outer tolerance range of the nominal width.

This object is achieved in that the to Circumferential section adjacent sections of the loop are bent back so far, that they have a blunt tube surface between them and one to the adjacent tube surface Include acute angles, between the sections and these with each other connecting bridge-like section are also included acute angles.

Due to the favorable shape of the loop achieved advantageous distribution of forces can the band clamp according to the invention with very little Cost of materials and correspondingly reduced costs are produced, while at the same time the advantage is achieved that the bending moments occurring in comparison with known Band clamps of the type mentioned are greatly reduced, whereby the clamping force and thus the sealing effect is considerably increased despite the low material thickness.

It is recommended that the length of the bridge-like section is essentially to be chosen at least twice as large as the length of each section. the Sections subject to pressure are relatively short, while those subject to tension are relatively short much more resilient bridge-like section is made longer.

It is also useful that the edges of the short gap section from the next point of the bridge-like section about half to two Third of the length of one of the sections removed are. Leading to a flat profile of the clamping loop, d. i.e., the protrusion of this loop beyond the circumference is much less than a circular or U-shaped clamping loop, so that it is less easy to bump and injure yourself can. The installation space required is also relatively small.

A simple tool for tensioning the band clamp according to the invention and to form the final trapezoidal shape is the subject of another invention.

A preferred embodiment of the invention is described in the following part the description with reference to drawings. It shows F i g. 1 is a front view a preferred embodiment of the novel band clamp before deforming and Clamping, F i g. 2 is a side view of FIG. 1, Fig. 3 one on a larger scale Shown front view of the band clamp, which is on a metal tube of a connecting part arranged high-pressure hose is clamped, F i g. 4 is an enlarged partial view the trapezoidal loop before deforming and tensioning, FIG. 5 an enlarged View of a clamping loop in the tightened position, FIG. 6 one the F i g. 5 similar view, in which a previously used known clamping loop is shown, F i g. 7 shows how the spreading forces are shown in the case of those previously used, for example in FIG. 6 act as band clamps, F i g. 8 is a graph showing the results of comparative experiments shows that with the previously usual, in F i g. 6 band clamps shown and those have been achieved according to the invention, FIG. 9 one of the F i g. 8 similar illustration, in which the pressure resistances of the known and the new clamping loops are compared are, F i g. 10 is an illustration showing how the forces in the inventive Band clamps according to FIGS. 3 and 5 act, and F i g. 11 a graphical representation in which the expansion dimensions of the known and the new, determined by tests clamping loops according to the invention are opposed to each other.

In the figures there is one made of a flat, narrow and thin band, preferably made of steel or other material with the same properties Band clamp shown. The tape has a high tensile strength, is resilient and maintains the shape it is bent into.

Such a band clamp consists of a circular or cylindrically curved band 1, the ends of which in a suitable manner, for. By welding the overlapped ends as shown at 2. The band clamp is with a bent loop. provided, which has a straight, bridge-like section 3, which is also referred to as a bridge section and has relatively shorter legs or sections 4 , which are connected to the circular section. The in F i g. The circular portion shown in Figure 1 is sized to easily slip over the end of a hose or other object to be clamped. The new, trapezoidal clamping loop is then pulled together at the clamping or fastening point of the hose. In Fig. 3 shows a high-pressure hose 5 which is provided with an internal reinforcement and which surrounds a tubular metal connection or a pipe socket. When the band clamp is positioned on the hose i, a pair of jaws 10 can be engaged in the corners between the outwardly extending legs 4 of the loop and the circumference of the band clamp. At the same time, a holding force is exerted on a counterholder or block 12, which presses on the bridge section 3 in the direction of arrow 12a and ensures that the legs 4 and the loop assume the inwardly curved angular position shown, and prevents the bridge section 3 from moving sags on the outside.

A preferred form of loop prior to clamping is shown in FIG. 4 shown. The legs 4 a of this loop converge towards the center of the clamp out, as indicated by the dashed lines, while the bridge section 3 a preferably essentially flat or straight and at right angles to a central, radial line 3 b runs.

The parts 10 can be the jaws of a pair of pliers, which is a special tool provided with a counterholder or block 12. This block 12 preferably makes a relative inward movement as the sides and inner corners of the bent loop are compressed into the final clamping position. The clamping forces exerted when tensioning the band around the hose are concentrated at the inner corners of the legs 4 of the loop, the jaws 10-10 being moved simultaneously in the direction of the arrows 10 a. This closing movement of the inner ends of the jaws 10 can simultaneously cause the block 12 to move in the direction of the band clamp and hose. The block 12 can have a slight curvature on its end face engaging the bridge section 3. When the clamping process is complete and the flexibility of the hose exerts both radial and circumferential forces, the legs 4 of the trapezoidal clamping loop are put under pressure so that they spread slightly and thereby flatten any curvature in the bridge section 3, as shown in FIG dashed lines 3c in F i g. 5 is shown.

In the case of the band clamp designed according to the invention, the dependency is the holding pressure of the bending stiffness of the metal used is significantly lower than with the previously known band clamps. The spreading forces become a pressure resistance the leg 4 and a tensile resistance of the bridge section opposite. One further improvement of the clamping or holding force is achieved in that the Forces trying to bend open the loop close to the circumference of the tensile stressed, annularly curved band is resisted. It is obvious that the closer you get, the greater the resistance against spreading of the loop Bringing bridge section 3 to the circumference of the band clamp and the closer the Legs 4 of the loop are folded onto the band clamp, d. H. the more pointed the Angle between the legs and the circumference of the band clamp.

The closer the bridge section with the legs 4 to the circumference of the Clamp lies, the lower is rliP FPr1Pnina nrlr r ATifenrai, 7iina rüa hP; 71l aiiftra + an can, and theoretically the greater the holding force. It has been found that adjustability, taking into account diameter differences of the hose, sustained, resilient holding effect and other factors are best can be achieved with such loops that are approximately the same as those shown in FIGS. 5 and 10 shown Have shape.

To take advantage of the novel shape of the inventively designed To show the band clamp is shown in FIG. 6 shows a hitherto customary loop, which may be generally partially cylindrical or somewhat oval. This known loop is generally first bent into a U-shape and then closed a clamping loop 15 shown at C is formed. It can be seen that the Resistance to the increase in the circumference or expansion of the ring section 16 essentially concentrated on the part of the loop farthest from the Center of the hose. The legs of such a loop act as a relatively stiff lever, which has a spreading force only the rigidity of the Oppose the ribbon at the arch W.

This is shown schematically in FIG. 7 shown, with the at a hose attached band clamp forces the loop open in the direction the arrows F act. The bending resistance must mainly be at the apex of the Angle at point W are applied.

It can be seen that this is only due to the flexural resistance of the belt at the point W 'based holding force is the lower, the further this point from Ring circumference 16a is removed. In contrast to the one shown in FIGS. 6 and 7 shown Form offers the in the F i g. 3 and 5 shown trapezoidal or arched stone shape the loop according to the invention has a much greater resistance to spreading forces.

If you look at the F i g. 5 and 10 with the F i g. 6 and 7 compares will it can be seen that the forces which open the circumferential section N of the band clamp try to get closer to the band circumference as opposed to resistance. Furthermore you can the in Fi g.10 designated with F forces tend to the angle between the legs and to spread the bridge section slightly, the straight legs 4 on pressure are claimed, while the obviously non-extendable bridge section is exposed to tensile stress. It should be noted that a small There is a tendency to spread the neck opening or the circumferential section N slightly, whereby the bridge portion 3 is flattened and straightened, as shown in FIG dashed lines 3 e is shown, but without any significant spreading of the circumferential section N.

In the F i g. 8 and 9 are the results of comparative experiments between the trapezoidal loop designed according to the invention and the previously usual loops shown.

These curves correspond to static tests in which one with protrusions or grooved pipe stubs inserted into each end of a hose section and clamped with the novel band clamp and subjected to a series of tests while similar sections of the same were fastened with known band clamps Hose were tested in the same way. The pressure was released until the Connection increased by about 17.6 kg / cm2 per minute. When a. Failure due to leakage or pulling out of the grooved pipe nipple occurred, the pressure was registered.

The changes hang in the pressures sustained by each clamp for example on the hose tolerances. Slight deviations in hose sizes and the strength of the reinforcement provided therein gave different results.

In FIG. 8 these results are represented by the characteristic curves C and K. specified. The pressure values to the left of the ordinate are given in kg / cm2, and the Results of the various tests are on the vertical lines 1, 2, 3, 4 and 5 indicated. Line C shows the failure of the aforementioned known band clamp at about 42.2 kg / cm2 pressure in the first two attempts, while the characteristic curve K the failure of the loop according to the invention at another section of this Hose at about 63.5 kg / cm2. More tries like them on the lines 3, 4 and 5 indicated were made with different tubing, wherein the same type of tubing was used for both types of loops in each experiment. In tests 3, 4 and 5, the loop designed according to the invention stopped the connection pressures from 84.5 to 97.5 kg / cm2, while with the same hoses the known loops could only withstand pressures of up to 56.4 kg / cm2. The band clamps, with which these comparative tests were carried out had the same diameter, same width and same tape thickness. The band clamps used in the experiments had a diameter of 16.3 mm, a thickness of 0.8 mm and a width of 6.4 mm and were made from the same strip steel.

Similar comparative tests have shown that even if the band clamps with the known circular loops according to FIG. 6 made of thicker and wider Band material were produced, the band clamps designed according to the invention withstood higher pressures with the trapezoidal clamping loop. The known and the band clamps of the invention were made with sections of the same hose Subjected to trial. The test results were recorded, with the corresponding Characteristic curves C and K of FIG. 9 show these comparative results. It can be seen that the holding force of the inventively designed, trapezoidal Loop is larger even with a weaker steel band than with the known ones, circular loops of the band clamps made of stronger material. the The test results given by the characteristic curve K were achieved with band clamps, which have a diameter of 20.7 mm, a thickness of 0.8 mm and a width of 6.4 mm. The known band clamps used for comparative tests, the test results of which are given in characteristic curve C, had the same diameter and a thickness of 0.9 mm and a width of 8.65 mm and were made of the same steel material manufactured like that of the clamps of characteristic curve K.

Another series of experiments, which is more specifically on the holding force of the Clamp training according to the invention compared to the known clamps the same Size and same material with the circular Clamping loop were judged, gives an even better comparison. The results of a series of experiments are shown in the characteristic curves in FIG. 11 specified.

At the top left in this figure are those designed according to the invention Clamping loop K and the known clamping loop C are shown. The opening where the clamp loop merges into the clamp band is indicated in each case with the arrows A denotes. In these tests, a straight longitudinal pull was applied to the two Types of clamping loops with which the band clamps were provided, exercised. the values obtained here represent forces acting in the direction of arrows B-B were exerted on the clamping loop K and the clamping loop C, as shown on the left above in FIG. 11 is shown.

The curve K of FIG. 11 corresponds to the values of the forces that are required around the loop or the circumferential section A (corresponding to the circumferential section N of FIG. 5) to open a predetermined amount. The one for the same opening dimension The forces required for the known band clamps are shown by curve C. Obviously there is an approximate uniformity of both curves. The trials showed that to spread the peripheral portion A by a certain amount at the loop K according to the invention approximately twice the force is required as in the well-known loop C.

The new band clamp with trapezoidal clamping loop can do both can be used in both low-pressure and high-pressure systems.

Obviously, this particular loop design can also be used for others Purposes than used with band clamps. For example, it is possible they are used to re-tension tensioning straps or other mechanical devices, z. B. to be used with ties of bundled objects or containers.

To produce the tape according to the invention. clamp can be normal Tape material can be used, e.g. B. Low carbon steel belts with a normal hardness of 65 HRB, whereby the band material also with a thin Coating can be provided to protect it against rusting without causing the clamping deformation destroys the coating.

The legs 4 of the loop widen when the loop is finished Ring out slightly before clamping the band clamp and the length of the Leg is at most about half the length of the bridge section 3. The radial distance, d. H. the height of the bridge section from the connection sections the leg 4 with the band clamp is about half or two thirds of the Length of these legs. The corners, which the legs with the band clamp and the Bridge sections connect, are rounded and form an acute angle between the legs and the band clamp, as shown in FIG. 5 and schematically from F i G. 10 can be seen.

The contraction of the trapezoidal clamping loop on the hose or tightening the band clamp on any object can be done in a simple manner Way by a single movement using a hand or power tool, that can be carried in the hand.

Claims (1)

Claims: 1. Band clamp for clamping hoses and. Like., Consists of a flat metal strip that releases the hose of a short circumferential section and on both sides of the short section forming a radially protruding from three essentially straight sections existing loop is bent, characterized in that the on the peripheral portion (N) adjacent sections (4) of the loop are bent back so far that they between them a blunt tube surface and a point to the adjacent tube surface Include angles, between the sections (4) and these with each other connecting bridge-like section (3) also included acute angles are. z. Band clamp according to claim 1, characterized in that the length of the bridge-like section (3) is essentially at least twice as large as the length of each section (4). 3. band clamp according to claim 1 or 2, characterized characterized in that the edges of the short gap section (N) from the next Place the bridge-like section (3) about half to two thirds of the Length of one of the sections (4) are removed. 4. Band clamp according to the claims 1 to 3, characterized in that the acute angle between the bridge-like Part (3) and the parts (4) are smaller than 45 °. Considered References: U.S. Patents Nos. 282,466, 2,614,304, 2810943, 2816338.