AT515794B1 - Dismountable and portable device for supporting and holding balancing belts - Google Patents

Abstract

Collapsible and portable device for supporting and holding Balancierbändern (1), consisting of a band support (2) and a longitudinal direction (1 ') of the Balancierbandes (1) arranged band holding device (4), which with the Balancierband (1) by a connecting element (5), wherein the belt holding device (4) consists of a bottom body (15) with at least three bores (16) for receiving holding elements (17), wherein the bottom body (15) at least one vertical bore with right bore angle to the bottom body longitudinal axis (18 ), and at least one oblique bore having a projected bore angle of 40-70 ° to the Bodenkörperlängsachse (18), and at least one further vertical bore and / or oblique bore, wherein each two perpendicular holes and / or two oblique holes form at least a pairwise crossed pair of holes , which has a projected bore angle of 40-70 ° to the transverse body transverse axis (1 9) on the left and right side of the bottom body (15), and all possible individual bores which do not form a pair of bores, have a right-hand bore angle to the bottom body transverse axis (19).

Description

Description: The invention relates to a dismountable and portable device for supporting and holding Balancierbändern, consisting of a belt support and arranged in the longitudinal direction of the Balan¬cierbandes tape holding device, which is connected to the Balancierband by a Ver¬ binding element.

Balancierbänder are usually betes¬tigt between two trees at low altitude. If no suitable trees are available, a balancer can also be attached to other fastening points, such as, for example, anchor bolts. It requires pads to support the balance belt at the same height above the ground, so as to provide sufficient height for balancing on the balance belt, and that the balancer in the center of the balance belt will not come into contact with the ground.

There is known a device for supporting and holding balancing belts from WO2010 / 040352A1. For hard or rock interspersed soils screwing the drilling anchor into the ground is practically impossible. In solid soils, the drilling anchor can only be screwed in with great force and time, but the holding force is usually not sufficient for higher loads, such as the jumping of the balancer or the tensioning of long balancing belts with high prestressing forces. In soft or sandy soils, the holding force is usually not sufficient even for normal applications. The screwing in of the drilling anchor is time-consuming and removal is no longer possible if the sheet-metal spiral has been deformed by the tensile forces of the balancing belt or the ground has hardened by drying out. The earth anchor DE362665C has no device for supporting balancing belts and has the disadvantage that it is particularly prone to soft bottoms for levering the device in the rear area and therefore, as shown in the illustrations, an additional rear bracing needed. It also has an unfavorable distribution of power transmission to the soil and is only suitable for horizontal Zugkräf¬te, while Balancierbänder a tensile force of about 20-30 ° upwards is necessary. The anchor DE202011103143U1 is designed for attachment to angled building elements and is not suitable for natural soils.

The object of the invention is therefore to provide a collapsible and portable device for Stüt¬zen and holding Balancierbändern, in which the above-mentioned disadvantages do not occur.

According to the invention the object is solved by the features cited in claim 1. The band holding device formed from bottom body and holding elements has the advantage that the holding elements can be driven by sledgehammer through the holes of the bottom body in a short time in hard and interspersed with stones bottoms. The bottom body enters into a positive and non-positive connection with the holding elements when it is subjected to tensile stress by the balancing belt, which passes on the tensile forces to the ground over the entire length of the holding elements driven in the ground.

The defined arrangement of the bores causes five effects to provide a high holding force of the belt retainer in the ground. Of these, four effects reduce the tendency for the belt holding device to be levered up out of the ground, which is caused by the pulling force of the balancing belt:

First, in the plane of projection perpendicular to the bottom transverse axis, at least one projected bore angle of 40-70 ° to the bottom body longitudinal axis on the underside thereof in the direction of balancing strip by the holding element inserted into this oblique bore causes the above-described prying of the strip holding device to be reduced. This effect shows enhanced in soft soil effect.

Secondly, in the plane of projection perpendicular to the bottom transverse axis of the body, all right angles to the longitudinal axis of the body cause a horizontal compaction of the soil in the pulling direction of the balancing belt by the holding elements inserted into this perpendicular hole, under tensile load by the balancing belt, resulting in high holding forces. This effect shows increased effect in solid soils.

Third, the angle of at least 20 ° projected in the projection plane perpendicular to the bottom transverse axis causes at least two holes of the bottom body a spread along the bottom longitudinal axis of the Hal¬teelemente introduced into these holes in the ground and thereby acts in solid and soft soils the above beschrie¬benen levering the Belt holding device against.

Fourthly, the angle of at least 40 ° projected in the plane of projection perpendicular to the body longitudinal axis between at least two holes of the bottom body causes further spreading along the bottom transverse axis of the supporting elements inserted in these holes in the ground and thereby counteracts the above-described levering of the belt holding device. This effect is more effective in solid soils. Fifth, the angles of all bores to the bottom body longitudinal axis at the bottom in direction Balancierband are less than or equal to 90 °, whereby the introduced into these holes Hal¬teelemente also counteract the above-described Levering the band holding device: Angle over 90 ° to the bottom body longitudinal axis at the bottom in the direction Balan¬cierband As the size increases, the tendency to pry up the retaining members and their tendency to be pulled out of the ground increases.

Due to the sum of these measures a sufficiently high holding force for the use of Balan¬cierbändern can be achieved with appropriate dimensioning on solid, soft or sandy soils.

In variants with multiple oblique holes at an angle of 40-70 ° to the Bodenkörperlängsachse the above-mentioned first effect is enhanced. These variants are therefore optimized for soft and sandy soils. For higher loads, the bottom body is equipped with a höhe number of defined in claim 1 holes.

According to the invention the object is achieved with a variant of the bottom body by the features cited in claim 2. The advantage over the minimum variants of the base body with only three retaining elements of claim 1 is that at least three Bohrun¬gen have a right angle to the longitudinal bore Bodenkörperlängsachse, whereby the above-mentioned second effect is enhanced. This embodiment of the band holding device is therefore optimized for hard and solid soils.

In the tensile forces occurring, which act obliquely downward at an angle of about 20-30 °, is counteracted by the defined spacing ratios of the holes above be¬ described levering: the greater the distance of the Bandverbindungselemen¬tes to the holes, the lower the tendency for the above-mentioned levering the band holding device.

By equal distances between the holes for the holding elements along the Längsach¬se the bottom body, the holding force is improved by a uniform distribution of tensile forces on the ground.

According to claim 3, it is also advantageous if the ratio of the distance from the connecting element to the center of the distance between the foremost and the rearmost hole and the distance from the center of the distance between the foremost and rearmost hole to the rearmost hole is greater than or equal to 1.5: 1 is.

The advantage of the defined pitch ratios is the effect of claim 2 described above, see the second paragraph.

A further inventive variant according to claim 4 is that the Bodenkörper at the spacings between the holes along the Bodenkörperlängsachse are the same. The advantage of the defined spacing conditions consists in the above-described effect of claim 2, see the third paragraph.

A further advantageous embodiment of the invention according to claim 5 is that the holding elements have an opening for receiving a transverse mandrel at the upper end. With the introduction of a transverse mandrel in an opening at the upper end of the Halteele¬mentes results in a simple and quick method for dismantling the tape holding device, see description below of Fig. 7.

According to claim 6, it is also advantageous that the holding elements below the opening have a downwardly flat radially extending groove.

The radial groove has the advantage that the bottom body can not slip upwards over the retaining elements when subjected to tensile stress by the balancing belt, since they form a stop for the bores of the floor body upwards. Due to the flat leakage of the groove down the expulsion from the ground is not hindered.

A further advantageous embodiment according to claim 7 is obtained if an extension tube is arranged at the front end of the bottom body of the band holding device, which has an opening for a connecting element at the ends.

The advantage of an extension tube connected to the bottom body is that a greater distance between the force application point of the balancing belt to the Bohrun¬gen and the retaining elements inserted therein, the tendency for the above-mentioned levering of the band holding device decreases. As a result, the holding force is further increased, especially on soft and sandy ground.

According to claim 8, it is also advantageous if two or more bottom body are connected in series by one or more coupling parts, wherein the coupling part has a transverse opening for the passage of a connecting element and an opening for the implementation of a holding element.

If two or more bottom bodies are connected to one another in series by means of the coupling part, holding forces for very high loads, such as jumps of the balancer or tensioning of long balancing belts with high pretensioning forces, can also be achieved on sand. The inventive design of the connecting openings does not result in any additional connecting elements needed, which would not already be present when using without coupling part. Another advantage of this coupling part is that an extension of the bottom body is formed by the rigid series arrangement quasi, whereby a levering the Bandhalte¬ device is further counteracted from the ground. Thus, higher holding forces can be achieved over parallel belt retainers.

A further advantageous embodiment of the invention according to claim 9 is that the tape holding device has a cover which consists of a tube with a longitudinal section, at the ends of tube caps are arranged, which have frontally Schlit¬ze through which a webbing is guided ,

The advantage of a cover is the reduction of the risk of injury to the Bandhal¬tevorrichtung. The longitudinal section of the tube has the positive effect that the cover along this longitudinal section can be pushed tightly over the bottom body and clamped there by itself by the material tension of the tube, which is preferably made of plastic or sheet metal. This increases safety because it can no longer be inadvertently removed by small children or strong winds, for example. By attaching two pipe caps and a webbing, the cover is also usable as Tragba¬re, stable and secure transport box for the entire device. The slots on the face of the tube caps provide a fixation of the position of the strap on the tube caps. The webbing can also be used as an adjustable carrying strap.

With reference to the drawings, the invention is explained in more detail, with other solutions that differ from the solutions described, as well as all possible combinations of all the features are possible without departing from the scope of the invention.

The apparatus according to the invention is shown schematically in a perspective view. [0017] FIG. 2A: the belt holding device according to the invention in elevation [0018] FIG. 2B: the belt holding device according to the invention in a side elevational view [0019] FIG [0022] FIG. 3D: The strip holding device according to the invention as a variant in elevation [0022] FIG. 3B: The strip holding device according to the invention as a variant in side elevation FIG strip holding device according to the invention as a variant in plan view FIG. 3D: The strip holding device according to the invention as a variant in perspective [0025] FIG. 4A: the strip holding device according to the invention as a variant in elevation [0026] FIG. 4B: the strip holding device according to the invention as a variant in side elevation [0027] FIG. 4C: The strip holding device according to the invention as a variant in plan view FIG. 4D: D The strip holding device according to the invention as a variant in perspective [0029] FIG. 5A: The strip holding device according to the invention as a variant in elevation FIG. 5D: The band holding device according to the invention as a variant in perspective [0033] FIG. 6: The holding element according to the invention with mandrel and point FIG. 7: The holding element according to the invention with mandrel during expulsion [0035] FIG. 8: The extension tube according to the invention in perspective FIG. 10: The cover according to the invention FIG. 11: The cover according to the invention as a transport box FIG. 1 shows schematically in a perspective view the dismountable and portable one. FIG Device for supporting and holding balancing straps 1. It consists of a strap 2 for supporting the balancing belt 1 at a sufficient height above the ground 48, and a belt holding device 4 arranged in the longitudinal direction 1 'of the balancing belt 1 for holding the balancing belt 1 and transmitting the tensile forces to the ground 48. The balancing belt 1 is connected to the front end of the ground body by means of connecting element 5 15 of the band holding device 4 is connected.

2A to 2D, and the variants 3A to 3D, 4A to 4D and 5A to 5D show the inventive band holding device 4 respectively in elevation A, side elevation B, floor plan C and Perspective D. It consists in each case of a longitudinal direction T of Balancierbandes 1 stretched bottom body 15 with holes 16 for receiving retaining elements 17th

The elevation A of the respective FIGS. 2A, 3A, 4A and 5A corresponds to the projection plane perpendicular to the bottom body transverse axis 19. The side elevation B of the respective FIGS. 2B, 3B, 4B and 5B corresponds to the projection plane perpendicular to the bottom body longitudinal axis 18.

All bore angles 18a 'to 18m', 19a 'to 19m' and all angular differences 18x ', 19x' are projected into the above-mentioned projection planes.

The horizontal bottom transverse axis 19 always runs transversely to the horizontal Bodenkörper¬ longitudinal axis 18, as shown in FIGS. 2C, 3C, 4C and 5C. Perpendicular bores are at right angles to the horizontal bottom longitudinal axis 18, oblique holes have a projected angle of 40-70 ° to the horizontal bottom longitudinal axis 18 at the bottom thereof in the direction of balancing belt 1. Bore pairs have a projected drilling angle of 40-70 ° to the bottom body transverse axis 19 on the left and right sides of the floor body 15.

The distances a, b, c, d of the holes 16 are measured from the intersections of the bore axes with the body longitudinal axis 18.

Differences between the diameters of the bores 16 and the holding elements 17 are to be taken into account in the embodiment such that all mentioned angles 18a 'to 18m', 19a 'to 19m' correspond to the angles of the longitudinal axes of the holding elements 17 under tensile loading by the balancing belt 1.

Fig. 2A shows the tape holding device 4 according to the invention with four holding elements 17A to 17D in elevation. The perpendicular bores 16A and 16C, 16D have a common projected bore angle range 18a ', 18c', 18d 'of 90 ° to the horizontal Bodenkörper¬ longitudinal axis 18. The two perpendicular holes 16C, 16D form a pair of holes. The tapered bore 16B has a projected bore angle 18b 'of 40-70 ° to the horizontal bottom body longitudinal axis 18 at the bottom thereof in the direction of balancing belt 1. Between the bore angles 18a 'and 18b' of the vertical bore 16A and oblique bore 16B ent¬steht a projected angular difference 18x 'of at least 20 ° along the Bodenkörperlängs¬ axis 18th

Fig. 2B shows the tape holding device 4 according to the invention in side elevation. The Bodenkörper 15 shows the pairwise crossed pair of holes of the vertical holes 16 C, 16 D, which has a projected hole angle 19 c ', 19 d' of 40-70 ° to the Bodenkörperquerachse 19 on the left and right side of the bottom body 15. This results between the Bore angles 19c ', 19d', a projected angular difference 19x 'of at least 40 ° along the Bodenkörperquerachse 19. The single vertical bore 16A and the individual oblique bore 16B have a right bore angle 19a', 19b 'to horizontal Bodenbskörperquerachse (19).

Fig. 2C shows the tape holding device 4 according to the invention in plan view. The ratio of the distance a: b is greater than or equal to 1.5: 1. The distances d between the holes 16 along the longitudinal body longitudinal axis 18 are equal.

Fig. 2D shows the tape holding device 4 according to the invention in perspective.

Fig. 3A shows the tape holding device 4 according to the invention as a variant with three Hal¬teelementen 17E to 17G in elevation. The perpendicular bores 16F and 16G have a common projected bore angle range 18f, 18g 'of 90 ° to the horizontal bottom body longitudinal axis 18 and thus form a pair of bores 16F, 16G. The oblique bore 16E has a projected bore angle range 18e 'of 40-70 ° to the horizontal Bodenkörper¬ longitudinal axis 18 on its underside in the direction Balancierband 1 on. Since in this embodiment, no further oblique bore with the same bore angle range of 40-70 ° to the Bodenkör¬perlängsachse 18 is present, the single oblique bore 16E can not make a bore pair. Between the bore angles 18e 'and 18f of the oblique bore 16E and the perpendicular bore 16F, a projected angular difference 18x' of at least 20 ° along the bottom body longitudinal axis 18 is created.

The bottom body 15 shows the pairwise crossed hole pair of perpendicular holes 16F, 16G, the projected hole angle 19f, 19g 'of 40-70 ° to Bodenkörperquer¬achse 19 on the left and right side of the bottom body 15. This results between the bore angles 19f, 19g 'a projected angular difference 19x' along the Boεdenkörperquerachse 19 of at least 40 °. The single oblique bore 16E has a right bore angle 19e 'to the horizontal bottom transverse axis (19).

3C shows the strip holding device 4 according to the invention as a variant in plan view. The ratio of the distance a: b is greater than or equal to 1.5: 1. The distances d between the bores 16 along the bottom body longitudinal axis 18 are the same.

Fig. 3D shows the tape holding device 4 according to the invention as a variant in perspective.

Fig. 4A shows the tape holding device 4 according to the invention as a variant with three Hal¬teelementen 17H to 17J in elevation. The oblique bores 16H and 161 have a common projected bore angle range 18h ', 18i' of 40-70 ° to the bottom body longitudinal axis 18 on its underside in the direction of balancing belt 1 and thus form a pair of holes 16H, 161. The vertical bore 16J has a projected bore angle 18j ' from 90 ° to hori¬zontalen bottom longitudinal axis 18. Since there is no further perpendicular drilling with the same bore angle range of 90 ° to the longitudinal body longitudinal axis 18 in this embodiment, the bore 16J can not form a pair of bores. Between the bore angles 18i 'and 18j' of the oblique bore 161 and the vertical bore 16J, a projected angle difference 18x 'of at least 20 ° along the longitudinal axis of the body 18 is produced.

The bottom body 15 shows the pairwise crossed pair of holes of the oblique holes 16H, 161, the projected bore angle 19h ', 19i' of 40-70 ° to the bottom body transverse axis 19 on the left and right side of the bottom body 15 has. This results in a projected angular difference 19x 'along the Bodenkörperquer¬achse 19 of at least 40 ° between the Bohrungswinkeln 19h', 19i '. The single vertical bore 16J has a right drilling angle 19j 'to the horizontal bottom transverse axis 19.

4C shows the belt holding device 4 according to the invention as a variant in plan view. The ratio of the distance a: b is greater than or equal to 1.5: 1. The distances d between the bores 16 along the bottom body longitudinal axis 18 are the same.

Fig. 4D shows the tape holding device 4 according to the invention as a variant in perspective.

Fig. 5A shows the tape holding device 4 according to the invention as a variant with three Hal¬teelementen 17K to 17M in elevation. All of the bores 16K, 16L, 16M have a common projected bore angle 18k ', 181', 18m 'of 90 ° to the body longitudinal axis 18. The perpendicular bores 16K and 16L form a bore pair, the vertical bore 16M remains as a single bore.

Fig. 5B shows the tape holding device 4 according to the invention as a variant in Seitenriss.Der bottom body 15 shows the pairwise crossed bore pair 16K, 16L, a proji¬zierten bore angle 19k ', 191' of 40-70 ° to the Bodenkörperquerachse 19 on the left and right side of the bottom body 15 has. This results in a projected angular difference 19x 'along the bottom body transverse axis 19 of min¬destens 40 ° between the Bohrungswinkeln19k', 191 '. The single vertical bore 16M has a right-hand bore angle 19m 'to the horizontal bottom-body transverse axis 19.

5C shows the strip holding device 4 according to the invention as a variant in plan view. The ratio of the distance a: b is greater than or equal to 1.5: 1. The distances d between the bores 16 along the bottom body longitudinal axis 18 are the same.

Fig. 5D shows the tape holding device 4 according to the invention as a variant in perspective.

Fig. 6 shows a holding element 17, which has an opening 32 for receiving a transverse mandrel 33 at the upper end 31, such as a nail or steel pin. The holding element 17 further has below the opening 32 a downwardly flat expiring radial groove 34 which forms a stop for the bore 16 of the bottom body 15 at tensile load upwards, but does not hinder the expulsion of the holding element 17 from the ground.

Fig. 7 illustrates the retaining member 17 with transverse mandrel 33 when driven out of the ground 48. A simple rope or belt loop 50, each with a knot 51 at each end, is placed on one side about the upper end 31 of the retaining element 17 and inserted ¬Res a Querdorns 33 secured in the opening 32 on the retaining element 17. The other end of the loop 50 is placed around the stem of a sledgehammer just below the hammerhead. By simply beating up the retaining element 17 is pulled jerkily from the bottom 48.

Fig. 8 shows in perspective the bottom body 15 with extension tube 35 which is inserted into the front end of the bottom body 15. The bottom body 15 and the balancing belt 1 are each connected to a connecting element 5 at one end of the extension tube 35 through openings 36.

Fig. 9 shows schematically the coupling part 37, in each case once before and once after the serial connection of two floor members 15 through the coupling part 37. When connecting two floor members 15 by means of coupling part 37, this is inserted into the floor members 15 to be connected and to a floor member 15 a connecting element 5, which is inserted through the transverse opening 38 of the coupling part 37 and the opening of the bottom body 15 for the connecting element 5, connected. The other bottom body 15 is connected by a holding member 17, which is guided by a bore 16 of the bottom body 15 and the opening 39 of the coupling part 37.

Fig. 10 illustrates the cover 43 with a longitudinal section 44 which is slid over the tape holding device 4.

Fig. 11 shows the cover 43 with end-capped tube caps 45 which are secured to the cover 43 by a strap 47 and fixed in position by slots 46 in the tube caps 45.

Claims (9)

1. Demountable and portable device for supporting and holding Balancierbändern (1), consisting of a band support (2) and a longitudinal direction (1 ') of the Balancierbandes (1) arranged band holding device (4), which with the Balancierband (1) by a connecting element (5), characterized in that the band holding device (4) consists of a longitudinal body (1 ') of Balancierbandes (1) stretched Boden¬ body (15) with at least three holes (16) for receiving retaining elements (17), wherein the bottom body (15) at least one vertical bore (16A, 16F, 16J) with right bore angle (18a ', 18f, 18j') to the bottom body longitudinal axis (18) in the Pro¬jektionsebene perpendicular to the Bodenkörperquerachse (19) , and at least one oblique bore (16B, 16E, 16H) with a projected bore angle (18b ', 18e', 18h ') of 40-70 ° to the bottom body longitudinal axis (18) at its underside in the direction Balancier¬band (1) the projection plane perpendicular to the Bodenkörperquerachse (19), and at least one further vertical bore (16C, 16D, 16G) and / or oblique bore (161), wherein each two perpendicular bores (16C, 16D; 16F, 16G) and / or in each case two oblique bores (16H, 161) form at least one pair of holes crossed in pairs, which has a projected bore angle (19c ', 19d', 19f, 19g ', 19h', 19i ') of 40 -70 ° to the transverse body transverse axis (19) on the left and right side of the Boden¬ body (15) in the projection plane perpendicular to the Bodenkörperlängsachse (18), and all possible individual holes (16A, 16B, 16E, 16J) bil no pair of holes bil ¬den, in the projection plane perpendicular to the bottom body longitudinal axis (18) have a right boring angle (19a ', 19b', 19e ', 19j') to the bottom body transverse axis (19). 2. Breakable and portable device for supporting and holding Balancierbändern (1), consisting of a band support (2) and a longitudinal direction (1 ') of the Balancierbandes (1) arranged band holding device (4) which with the Balancierband (1) by a connecting element (5) is connected, characterized in that the band holding device (4) consists of a bottom body (15) stretched in the longitudinal direction (1 ') of the balancing belt (1) with bores (16) for receiving holding elements (17). wherein the bottom body (15) has at least three perpendicular bores (16K, 16L, 16M) with a right-hand boring angle (18k ', 18Γ, 18m') to the bottom body longitudinal axis (18) in the projection plane perpendicular to the bottom body transverse axis (19), two perpendicular bores respectively form at least a pairwise crossed pair of bores (16K, 16L), which in the projection plane perpendicular to the bottom body longitudinal axis (18) has a projected boring angle (19k ', 19Γ) of FIG 0-70 ° to the Bodenkörperquerachse (19) on the left and right side of the bottom body (15), and all possible individual holes (16M) that do not form a pair of holes in the projection plane perpendicular to Bodenkörper¬ longitudinal axis (18) has a right angle ( 19m ') to the transverse body transverse axis (19), and that the ratio of the distance (a) from the connecting element (5) to the center of the distance (c) between the foremost and rearmost bores (16M, 16K) and the distance (b) from the center of the Distance (c) between the foremost and rearmost bore (16M, 16K) to the rearmost bore (16K) is greater than or equal to 1.5: 1, and that the distances (d) between the bores (16) along the Bodenkörperlängsachse (18) equal. A demountable and portable balancing belt supporting and holding device (1) according to claim 1, characterized in that at the bottom body (15) the ratio of the distance (a) from the connecting element (5) to the center of the distance (c) between the front and rear 16D, 16A, 16G, 16E, 16J, 16H) and the distance (b) from the center of the distance (c) between the foremost and rearmost bores (16D, 16A, 16G, 16E, 16J, 16H) to the rearmost bore (16A, 16E, 16H) is greater than or equal to 1.5: 1. 4. Demountable and portable device for supporting and holding Balancierbändern (1) according to claim 1, characterized in that the bottom body (15), the distances (d) between the holes (16) along the Bodenkörperlängsachse (18) are equal. 5. Demountable and portable device for supporting and holding Balancierbändern (1) according to one of claims 1 to 4, characterized in that the holding elements (17) at the upper end (31) has an opening (32) for receiving a transverse mandrel (33) aufwei¬sen. 6. Demountable and portable device for supporting and holding Balancierbändern (1) according to one of claims 1 to 5, characterized in that the holding elements (17) below the opening (32) aufwei¬ a downwardly flat radial groove (34) sen. 7. A detachable and portable device for supporting and holding Balancierbändern (1) according to one of claims 1 to 6, characterized in that at the front end of the bottom body (15) of the band holding device (4) an extension tube (35) is angeord¬net, which has at the ends an opening (36) for a connecting element (5). A demountable and portable balancing belt supporting and holding device (1) according to any one of claims 1 to 7, characterized in that two or more floor bodies (15) are connected in series by one or more coupling parts (37), the coupling part (8) 37) has a transverse opening (38) for the passage of a connecting element (5) and an opening (39) for the passage of a holding element (17). 9. A detachable and portable device for supporting and holding Balancierbändern (1) according to one of claims 1 to 8, characterized in that the band holding device (4) has a cover (43), which consists of a tube with a longitudinal section (44 ) consists, at the ends of tube caps (45) are arranged, which have frontally slits (46) through which a webbing (47) is guided. 4 sheets of drawings