Monoblock sensor body and method of its manufacturing

What is claimed is: 1. A monoblock sensor body of a load cell based on an electromagnetic force compensation mechanism, the sensor body comprising: a Roberval mechanism, comprising: a fixed column; a movable column; an upper beam; a lower beam, parallel to the upper beam, wherein the upper beam and lower beam are each connected by a first flexure point section to the movable column and by a second flexure point section to the fixed column, thereby defining a first upper, a second upper, first lower and second lower flexure point section; a lever arrangement that is coupled to the movable column on a first side by a coupling and that is connectable on a second side to the electromagnetic force compensation mechanism, the lever arrangement having at least one lever, each lever associated with a fulcrum; a plurality of mounting portions for mounting the fixed column to a housing side of a weighing module, directly or indirectly via an intermediate arrangement, and/or for mounting a load receiving member to the movable column, directly or via an intermediate arrangement, wherein at least one of the mounting portions comprises at least one mounting hole that extends preferably at least predominantly orthogonal to a load direction, especially along a length direction of the upper beam and the lower beam, each mounting hole comprising an inner thread such that, in a mounted state, a mating outer thread of a fixing screw that is screwed into the mounting hole up to an axial threading end configured to be screwed into the mounting hole, with each mounting hole having one of the flexure point sections as a relatively closest flexure point section; and at least one cavity, each cavity associated with one of the mounting portions and reducing an available solid angle of a straight propagation path that runs from the inner thread to at least one of: the closest flexure point section, a coupling and the closest fulcrum, wherein, for each cavity, a closing material boundary of the body closes the cavity over at least a bridging width versus the height-side end of the body corresponding to the closest flexure point section. 2. The monoblock sensor body of claim 1 , wherein a width of the closing material boundary at least partly overlaps a width of the mounting hole. 3. The monoblock sensor body of claim 1 , wherein the cavity extends to a lateral side of the monoblock sensor body. 4. The monoblock sensor body of claim 1 , wherein a solid angle of at least 36° in the height direction is covered, when seen in projection to a height-length plane, by at least one of: the extension of the cavity and the side opening. 5. The monoblock sensor body of claim 1 , further comprising: an elongated slit portion, seen in projection to the height-length plane, having a gap dimension of less than 2 mm orthogonal to an extension of the slit portion. 6. The monoblock sensor body of claim 5 , wherein the elongated slit portion is manufactured by wire-electric discharge mechanism. 7. The monoblock sensor body of claim 5 , wherein at least one of: the side opening and the cavity comprises: an enlarged portion, as seen in projection to the height-length plane, with a larger gap dimension than that of the elongated slit portion, in particular of a base form of a circular bore. 8. The monoblock sensor body of claim 1 , wherein at least one of the mounting portions at the movable column and the associated cavity cover both the closest flexure point section and at least part of the coupling. 9. The monoblock sensor body of claim 1 , wherein the upper and lower beam each has a length that is at least 30%, preferably at least 36%, in particular at least 42% of an overall length of the body. 10. The monoblock sensor body of claim 1 , wherein each cavity is connected with the associated mounting hole, such that the cavity and the mounting hole are joined in particular further to the inside of the body with respect to the axial threading end of the mounting hole and, in particular, with respect to the axial end of the inner thread. 11. The monoblock sensor body of claim 10 , wherein: the movable column and the fixed column each has mounting holes located at two different height positions; in particular, two mounting holes are located at each side and height position, and all of the mounting portions associated with the mounting holes have associated cavities. 12. The monoblock sensor body of claim 1 , wherein at least two mounting holes having the same closest flexure point section have associated cavities that are connected in the width direction, thereby forming a cavity that reaches from one lateral end side of the body to the other lateral end side. 13. A load cell comprising: a monoblock sensor body configured according to claim 1 ; and an electromagnetic force compensation mechanism connected to the lever arrangement of the sensor body. 14. A weighing device comprising: one or more load cells configured according to claim 13 , having a load receiving member fixedly mounted, directly or indirectly, to the movable column of the monoblock sensor body of the load cell. 15. A method of manufacturing a monoblock sensor body configured according to claim 1 , the method comprising the step of: creating, by material removal, the cavity while leaving the closing material boundary of the body. 16. The method of claim 15 , comprising the further step of: defining in the monoblock sensor body, by material removal, at least one of the Roberval mechanism and the lever mechanism in the monoblock sensor body, in particular with the same material removal technique of that of the creating step. 17. The method of claim 16 , wherein the material removal, of at least one of the creating step and the defining step, comprises at least one of: a first step of cutting, in particular drilling, a first cavity to accommodate a wire of a wire-electric discharge mechanism, to then extend the cavity by creating one or more slit portions to one or both sides in the height direction by erosion with the wire-electric discharge mechanism, or a step of cutting the cavity with water jet cutting.