Linear drive and linear drive arrangement

The invention claimed is: 1. A linear drive, comprising: a lever element which has a through bore, a first portion spaced apart from the through bore and a second portion arranged between the first portion and the through bore, a rod element which extends along a rod axis and through the through bore, a bearing element which supports the rod element, the bearing element configured to allow a movement of the rod element along the rod axis and to block a movement perpendicular to the rod axis, a shape memory alloy element which extends along a first axis and length of which is adjustable by application of electrical power, wherein a first end of the shape memory alloy element is connected to the first portion of the lever element, a second end of the shape memory alloy element opposite the first end is stationarily connected to a first fixed bearing, and the shape memory alloy element is configured to exert a tensile force acting along the first axis on the lever element when electrical power is applied, a restoring element extending along a second axis, wherein a first end of the restoring element is connected to the second portion of the lever element, a second end of the restoring element opposite the first end is stationarily connected to a second fixed bearing, and the restoring element exerts a restoring force on the lever element acting along the second axis and counter to the tensile force, wherein in a first state, in which electrical power with a first power value is applied to the shape memory alloy element, the shape memory alloy element is shortened in such a way that the lever element is tilted owing to the tensile force exerted by the shape memory alloy element and, as a result, there is a non-positive connection between the lever element and the rod element, in a second state, in which electrical power with a second power value, which is greater than or equal to the first power value, is applied to the shape memory alloy element, the shape memory alloy element is further shortened in such a way that the tilted lever element is displaced parallel in the direction of the tensile force exerted by the shape memory alloy element and, as a result, brings about a movement of the rod element along the rod axis, in a third state, in which electrical power with a third power value, which is smaller than the first power value, is applied to the shape memory alloy element, the tilted lever element is at least partially tilted back and, as a result, the non-positive connection between the lever element and the rod element is released, and in a fourth state, in which electrical power with a fourth power value, which is smaller than or equal to the third power value, is applied to the shape memory alloy element, the at least partially tilted back lever element is displaced parallel in the direction of the restoring force exerted by the restoring element. 2. The linear drive as claimed in claim 1 , wherein the first axis and the second axis are arranged parallel to each another. 3. The linear drive as claimed in claim 2 , wherein the rod axis is arranged parallel to the first axis and parallel to the second axis. 4. The linear drive as claimed in claim 1 , wherein the bearing element is configured to block a movement of the rod element in direction of the restoring force acting on the lever element. 5. The linear drive as claimed in claim 1 , wherein the bearing element has a first bearing on a first side of the lever element and a second bearing on a second side of the lever element opposite the first side. 6. The linear drive as claimed in claim 1 , wherein the third power value and the fourth power value are equal to zero. 7. The linear drive as claimed in claim 1 , wherein the restoring element is configured as an additional shape memory alloy element which, when electrical power is applied, exerts an additional tensile force on the lever element, which acts counter to the tensile force exerted by the shape memory alloy element connected to the first portion. 8. The linear drive as claimed in claim 1 , furthermore further comprising an initial position contact which contacts the lever element, which is at least partially tilted back and displaced parallel to and in direction of the restoring force, and thereby signals the fourth state. 9. The linear drive as claimed in claim 8 , wherein the initial position contact contacts the lever element at an initial position contact portion of the lever element, which is arranged such that the initial position contact portion is arranged between the through bore and the second portion of the lever element. 10. The linear drive as claimed in claim 1 , further comprising an end position contact which contacts the tilted lever element, which is displaced parallel to and in direction of the tensile force, and thereby signals the second state. 11. The linear drive as claimed in claim 10 , wherein the end position contact contacts the lever element at an end position contact portion of the lever element, which is arranged such that the first portion and the second portion of the lever element are arranged between the end position contact portion and the through bore. 12. The linear drive as claimed in claim 1 , wherein the lever element in addition to the first portion and the second portion has a third portion and a fourth portion, wherein the first portion and the second portion are arranged on a first side with respect to the rod element, the third portion and the fourth portion are arranged on a second side opposite the first side with respect to the rod element, and the fourth portion is arranged between the third portion and the through bore, and wherein the linear drive furthermore has the following components: a second shape memory alloy element which extends along a third axis and the length of which is adjustable by application of electrical power, wherein a first end of the second shape memory alloy element is connected to the third portion of the lever element, a second end of the second shape memory alloy element opposite the first end is stationarily connected to a third fixed bearing, and the second shape memory alloy element is configured to exert a second tensile force acting along the third axis on the lever element when electrical power is applied, the second tensile force acts in the opposite direction to the tensile force exerted by the shape memory alloy element connected to the first portion, a second restoring element extending along a fourth axis, wherein a first end of the second restoring element is connected to the fourth portion of the lever element, a second end of the second restoring element opposite the first end is stationarily connected to a fourth fixed bearing, and the second restoring element exerts a second restoring force which acts along the fourth axis and acts counter to the second tensile force exerted by the second shape memory alloy element, wherein, when electrical power is applied to the second shape memory alloy element and without electrical power being applied to the shape memory alloy element, the movement of the rod element is reversed. 13. The linear drive as claimed in claim 1 , further comprising: a second shape memory alloy element which extends along the first axis and the length of which is adjustable by application of electrical power, wherein a first end of the second shape memory alloy element is connected to the first portion of the lever element, a second end of the second shape memory alloy element opposite the first end is stationarily connected to a third fixed bearing, and the second shape memory alloy element is co