Apparatus for Training Muscles

Abstract

An apparatus (1) for exercising muscles comprises a power arm (2), which is pivotable about a pivot shaft (5), which is disposed on a holding element (6). The first articulation point (7) at which a compression spring element (9) is linked to the power arm (2) is adjustable along the power arm (2). To achieve this, one end region (8) of the compression spring element (9) is provided with a first joint surface (14), and a series of second joint surfaces (16), which are designed complementary to the first joint surface (14), is disposed across an adjustment zone (10) along the power arm (2). The first joint surface (14) is operatively connectible to one of the second joint surfaces (16), and the power arm (2) is pressed via a further spring element (18) toward the one end region (8) of the compression spring element (9) such that the two operatively connected joint surfaces are kept in contact with each other. Resulting thereby is a simple possibility of adjustment of the force to be applied to the power arm.

Claims

1. An apparatus for exercising muscles, comprising a power arm, which is equipable at one end region with actuation elements and which is pivotable by the other end region about a pivot shaft, which is disposed on a holding element, to which power arm the one end region of a compression spring element is linked at a first articulation point, which first articulation point is adjustable along the power arm, while the other end region of the compression spring element is linked on the holding element at a second articulation point, wherein the one end region of the compression spring element is provided with a first joint surface, which has a first curvature, and disposed along the power arm over an adjustment zone is a series of second joint surfaces which each have a second curvature, designed complementary to the first curvature, so that the one end region of the compression spring element with the first joint surface is able to be brought into operative connection to one of the second joint surfaces, and the power arm is pressable, via a further spring element designed as pull spring, toward the one end region of the compression spring element, in such a way that the two joint surfaces in operative connection are kept in contact.

2. The apparatus for exercising muscles according to claim 1, wherein the first curvature of the first joint surface is designed concave and the second curvatures of the second joint surfaces are designed convex.

3. The apparatus for exercising muscles according to claim 1, wherein the first joint surface and the second joint surfaces are designed cylindrical, and the respective cylinder axes are aligned parallel to the pivot shaft.

4. The apparatus for exercising muscles according to claim 3, wherein the second joint surfaces are formed by cylindrical shafts, which are disposed in a row and spaced apart from one another over the adjustment zone on the power arm, and the first joint surface is formed in the root of a fork, which is placed at the one end region of the compression spring element.

5. The apparatus for exercising muscles according to claim 4, wherein the cylindrical shafts are placed in two crosspieces opposite one another and disposed along the adjustment zone of the power arm.

6. The apparatus for exercising muscles according to claim 1, wherein the compression spring element is a gas pressure spring.

7. The apparatus for exercising muscles according to claim 1, wherein the first joint surface with the first curvature and the respective second joint surface with the second curvature are only led into one another.

8. The apparatus for exercising muscles according to claim 8, wherein the pull spring is an elastic band, whose one end region is attachable on the holding element in the area of the second articulation point and whose other end region is detachably attached to the power arm.

9. The apparatus for exercising muscles according to claim 1, wherein provided on the power arm along the adjustment zone is a scale.

10. Apparatus for exercising muscles according to claim 1, wherein the holding element is attachable to a supporting frame.

Description

[0016] An embodiment of the invention will be explained more closely in the following, by way of example, with reference to the attached drawings.

[0017] FIG. 1 shows in a three-dimensional representation the apparatus for exercising muscles according to the invention;

[0018] FIG. 2 shows a side view of the apparatus for exercising muscles according to FIG. 1;

[0019] FIG. 3 shows a view from the front of the apparatus for exercising muscles according to FIG. 1;

[0020] FIG. 4 shows a sectional representation of the apparatus for exercising muscles along line IV-IV according to FIG. 2;

[0021] FIG. 5 shows a sectional representation along line V-V according to FIG. 3 through the adjustment zone of the apparatus for exercising muscles;

[0022] FIG. 6 shows a side view of the apparatus for exercising muscles with power arm pressed downward;

[0023] FIG. 7 shows a side view of the apparatus for exercising muscles with power arm pivoted in; and

[0024] FIG. 8 shows a view from the front of the apparatus for exercising muscles according to FIG. 7 with power arm pivoted in.

[0025] As can be seen from FIG. 1, the apparatus 1 for exercising muscles has a power arm 2. The one end region 3 of the power arm 2 is designed in such a way that actuation elements (not shown) can be inserted in a known way, whereby the power arm 2 can be operated in a suitable way by the exercising person. The other end region 4 of the power arm 2 is pivotable about a pivot shaft 5, which is disposed on a holding element 6. At a first articulation point 7, the one end region 8 of a compression spring element 9 is coupled to the power arm 2. This first articulation point 7 and thus the one end region 8 of the compression spring element 9 is adjustable along an adjustment zone 10 on the power arm 2, as will be described later in detail. The other end region 11 of the compression spring element 9 is coupled at a second articulation point 12 on the holding element 6. In the embodiment example shown here, the compression spring element 9 is designed as gas pressure spring 13.

[0026] For exercising muscles, the power arm 2 can be pivoted about the pivot shaft 5, whereby the gas pressure spring 13 generates a counter force to the operating force and presses the power arm 2 back into the original position again, which is obtained with the reaching of the completely driven-out gas pressure spring 13.

[0027] As can be seen from FIG. 2, the one end region 8 of the compression spring element 9 has a first joint surface 14 with a first curvature 15, while disposed along the power arm 2 over the adjustment zone 10 is a series of second joint surfaces 16 each with a second curvature 17, which curvatures are designed complementary to the first curvature 15. As will be described later, the one end region 8 of the compression spring element 9 with the first joint surface 14 thereby comes into operative connection with one of the second joint surfaces 16. The first joint surface 14 and the second joint surface 16 are pressed via a further spring element 18 against the one end region 8 of the compression spring element 9, so that both the first joint surface 14 and second joint surface 16, which are in operative connection, are kept in contact with one another.

[0028] As can be seen from FIG. 1, a blocking element 31 can be provided having the form of a hollow cylinder which is provided with a longitudinal slot over the entire length. As can be learned from FIG. 2, this blocking element 31 can be placed on the gas pressure spring rod 30 when the gas pressure spring 13 is in the completely driven-out position. In this state the power arm 2 is locked; it cannot be pivoted. This apparatus for exercising muscles can thereby serve for the exercise of chin-ups, for example.

[0029] As can be seen in particular from FIG. 5, the second joint surfaces 16 are formed by cylindrical shafts 19, which are disposed in series and spaced apart from one another over the adjustment zone 10 on the power arm 2.

[0030] The first joint surface 14 is formed in the root 20 of a fork 21, which fork 21 is attached at one end region 8 of the compression spring element 9. Through this design the first joint surface 14 has a concave shape, while the second joint surfaces 16 are designed convex. The axes of the cylindrical shafts 19 are aligned parallel to the pivot shaft 5, about which the power arm 2 is pivotable with respect to the holding element 6.

[0031] As has already been mentioned, the power arm 2 is pressed via the further spring element 18 toward the compression spring element 9. Thereby achieved is that the first joint surface 14 and the respective second joint surface 16, which are only led into one another, remain in contact with one another. By means of this adjustment zone 10, the articulation point 7 can be adjusted with respect to the pivot shaft 5. When the power arm 2 is in the position in which the compression spring element 9, which is designed as gas pressure spring 13, is in the completely driven-out position, the power arm 2 can be pivoted further against the spring force of the further spring element 18. The fork 21 with the second joint surface 16 moves out of the cylindrical shaft 19 and the first joint surface 14. The one end region 8 of the compression spring element 9 can be moved together with the fork 21 along the series of cylindrical shafts 19 and allows itself, through the pivoting back of the power arm 2, to be moved again into the desired position on the corresponding cylindrical shaft 19, whereby once again the further spring element 18 causes the first joint surface 14 and the newly selected second joint surface 16 of the corresponding cylindrical shaft 19 to remain again in contact. The spacing of the first articulation point 2 <sic. 7> to the pivot shaft 5 can thereby be adjusted in a simple way. The force to be applied to the power arm can thus be accordingly adjusted.

[0032] Ensured through the width of the fork 21 and the spacing of the individual cylindrical shafts 19 with respect to one another is that no malfunctions can occur during adjustment. The fork 21 will always be in engagement with a cylindrical shaft 19, whereby safe operation is guaranteed. Even with incorrect clicking into place, the fork 21 of the compression spring element 9 under load automatically jumps onto the nearest cylindrical shaft 21.

[0033] The further spring element 18 is preferably designed as elastic band 22, whose one end region 23 (FIG. 2) can be attached in the region of the second articulation point 12 on the holding element 6, while the other end region 24 can be detachably attached on the power arm 2. For this purpose a hook 25 can be attached on this other end region 24 on the elastic band 22, which hook can be hooked onto a pin 26 provided on the power arm.

[0034] FIG. 3 shows a view from the front of the apparatus 1 according to the invention. Visible is the power arm 2, which is held in the holding element 6 in a way pivotable about the pivot shaft 5. Likewise visible is the elastic band 22, with which the power arm 2 is pressed against the compression spring element 9, as has been described previously.

[0035] Visible from the sectional representation according to FIG. 4 is how the fork 21 is engaged with a cylindrical shaft 19 in a flexible way. Thereby visible is that the cylindrical shafts 19 are held in two crosspieces 27, which are disposed on the power arm 2.

[0036] Visible from FIG. 6 is the pressed position of the power arm 2. The gas pressure spring 13 is located in the driven-in state. It can thereby be seen that the fork 21 is supported in an optimal way on the corresponding cylindrical shaft 19. A slipping away of the fork 21 out of the cylindrical shaft 19 can be excluded. The secure operation is ensured. As is apparent from this FIG. 6, it is advantageous if the fork 21 is provided in each case with a recess 28 on the outside, whereby space is made for the cylindrical shaft which is adjacent to the cylindrical shaft 19 with which the fork 21 is engaged.

[0037] As can be learned from FIGS. 7 and 8, the power arm 2 can be pivoted about the pivot shaft 5 completely away from the gas pressure spring 13. To achieve this, the elastic band 22 is unhooked from the power arm 2. The power arm 2 can then be pivoted, whereby the fork 21 is moved out of the respective cylindrical shaft 19. The power arm 2 can thereby be brought into a parked position. The gas pressure spring 13 is pivoted toward the holding element 6. The apparatus 1 can thereby be brought into a space-saving position. The elastic band 22 is then located in front of the gas pressure spring 13.

[0038] The holding element 6 and thus the apparatus 1 for exercising muscles can also be fixed in a known way to a supporting frame (not shown). The holding element 6 and thus the apparatus 1 for exercising muscles can then be adjusted with respect to this supporting frame, for example with respect to the height from the floor or also with respect to an angular position to this supporting frame.

[0039] As can also be seen from FIG. 1, a scale 29 can be put on a first crosspiece 27 of the power arm 2, whereby a reproducible adjustment is possible in a simple way, for example of the force to be applied for pivoting of the power arm.

[0040] With this inventive solution, with an apparatus for exercising muscles having a power arm able to be actuated, the force to be applied to the power arm can be adjusted in a simple way, so that the force to be applied to the power arm can have differing magnitudes.