TH16652B - Dynamic balancer - Google Patents

Abstract

Dynamic counterweight per unbalanced rotating part, first set weight of the same size and weight. Be installed to move freely within the groove or The first rail When the machine is spinning After it will be installed on the shaft. Or parts that Likewise, a second set of counterweights of the same size and weight are installed to move freely within the groove or the second rail, located inside the first rail. Size and weight are different from the second set of weights. The locker locks and releases the counterweight at a predetermined angular velocity of flow of different viscosities, and the rail appearance is used.Read More To change the dynamics of the weight

Claims (3)

1. a machine for eliminating imbalance In rotatable parts with a rotation axis The first, second and third continuous paths (701,702,703) are installed in the same center-point around the axis of rotation (706) of the rotating part. Many 1 (704) are internally positioned and piloted by The first path (701), the second set of movable solid weights (704), is internally positioned. And was piloted by a second path (702), and a weighted solid that Many of the third (704) movable weights are internally positioned and piloted by a third path (703). Each of these first solid-weighted weights, each is Second solid Such many And each weighted character is a solid set with a number of All of them are of the same size, the first set of solid counterweights, the second set, the third set independently within the path during the respective rotation of the machine. And where Thus, the imbalance is eliminated by a solid weight. And the first, second, third such path Removed to be in a normal horizontal position. 2. The machine according to claim 1 looks at the fourth path. (701) was positioned in The inside along the radial lines of the first, second and third paths, and equipped with a single concentricity. The first, second, and third paths and the fourth set of movable solid weights (713) are internally positioned. And was piloted by a fourth such path, many of these fourth solid weights. The dimensions are smaller than the first, second and third set of solid weight. 3. The machine according to claim 2 looks at the fifth path. (711) was positioned in The inside along the radial lines of the fourth path (710) and the sixth path (712) are aligned inward according to Fifth Path radial (711) Many fifth set of movable solid weights (714) are internally positioned. And was piloted by the fifth route And weighted characteristics belong to Many of the six (715) solids are positioned internally. It was piloted by the sixth route (712). Many of these fifth solid-state weights were smaller than the weight. Many of the fourth solid weights, many of the sixth solid weights were. It is much smaller than the aforementioned fifth rigid counterweight. 4. Machine for eliminating imbalance. In a rotatable part with a rotation axis, a first continuous circular path (901) is placed around the axis of rotation (903) of the rotatable part, the first path includes the horizontal inner wall surface. Inner circumference And the surface of the wall In the outer circumference, a second continuous path (901) is placed around the axis of rotation (903) of the rotatable part, the second path includes the inner wall surface along the inner circumference. And the inner wall surface along the outer circumference, the third continuous path (901) is placed around the rotation axis (903) of the rotatable part, the third path includes the inner wall surface along the Inner circumference And the surface of the inner wall along the outer circumference Weighted characteristics Many of the first movable solids (902) were internally positioned and piloted by the first path (901), the second set of movable solid weights (902) were internally positioned and piloted by The second path (901) and the third set of movable solid weights (902) are positioned internally. It was piloted by the third path (901), the first path (901) was co-axed relative to the pivot axis (903) of the rotatable part and was mounted radially outward. Of the axis of rotation (903) of the rotating part, so that the inner wall surface along the inner circumference And the surface of the inner wall along the outer circumference The first path (901) is aligned radially outward from the spindle of the rotatable part, such second path (901) is aligned with a common axis relative to the spindle (903). Of the rotatable part and is cut outward along the radial direction of the first path (901). On the inside along the inner circumference And the inner wall surface along the outer circumference of the second path (901) is aligned radially outward from the inner wall surface along the inner circumference and the axial inner wall surface in relation to Path one (901) respectively, the second path is replaced along the axis relative to the first path, the third path (901) is aligned with the rotation axis (903). ) Of the swivel part and it is installed out. Outside along the radius of the first and second paths; therefore, the inner wall surface along the inner circumference and the inner wall surface along the outer circumference of the paths (901) are arranged outward according to Radial from the inner wall surface along the inner circumference and the inner wall surface Along the outer circumference of the second path (901) respectively, the third one was entered. Axial displacement relative to the second path, so that second path is installed along the axis. During the first route And the third thereof, with the first, second and third such path will be placed. In an overlapping manner 5. The machine according to claim 4 is characterized in that the fourth path (901) is aligned. There is a common axis relative to the spindle of a rotating part. The fourth path has an inner wall surface along the The inner circumference and the inner wall surface along the outer circumference, a fourth path is installed out. Thus, the inner wall surface along the inner circumference and the inner wall surface along the outer circumference of the fourth path (901) are arranged further outward. Along the radius from the surface of the inner wall along the inner circumference And the surface of the inner wall along the line The outer circle of the third path (901) respectively, the fourth path is replaced along the The axes are associated with the first, second and third paths, and the weighted solids are movable. Many of the fourth sets were positioned internally. And was piloted by Route Four, 6. The machines according to claim 4 were characterized by the first, second and third solid-weighted weights, each carrying the same weight. The counterweight is the first solid. The size differs from the size of the second solid-weighted and the second set of solid-weighted weights. There is a size different from the size of the counterweight. First and third set 8. The machine according to claim 5 is characterized by a solid weight of the first set. They are smaller than the second solid weights. The second solid is smaller than the weight. The third solid weight, and the third solid weight, is smaller than the solid weight. The fourth aforementioned set. 9. A counterweight for eliminating imbalances in the rotating housing. Contains paths First circular, many first series solid weights were arranged. Inside and piloted by the first path, the first fluid is positioned in the first circular path, the second continuous circular path, the second moving solid weights. Many are positioned internally. And being piloted by the aforementioned second route, a second fluid was supplied Placed in a second such path, the viscosity of the first liquid differs from the The viscosity of the aforementioned second fluid 1 0. The counterweight according to claim 9 is characterized in that a third continuous path is arranged. Many third set of weights are mobile solids 1 1. The counterweight in claim 10 is characterized in that the third path contains a liquid that is stable. Three with viscosity 1 2. The balancer according to claim 11 is characterized by the viscosity of the fluid in that path. Third, the viscosity of the first and second fluids 1 3. The balancer according to claim 9 is characterized in that each of the first solid-weighted weights is different from the weight of the individual solids. Two 1 4. The counterweight according to claim 9 is characterized by the size and weight of each weight. The counterweight is a solid set that differs from size. And the weight of each weight The second set of solid counterweight 1 5. The counterweight under claim 9 is characterized by the locking element capable of holding the lock. Weight movement Such a first solid character at the first angular velocity of the rotating part and to release the counterweight. Characteristics are one such solid set at the angular velocity. Two pre-defined of rotatable parts To allow the counterweight to be a solid set that One moves 1 6. The counterweight according to claim 15 is characterized in that the first and second paths occupy a different cross-shaped shape. 1 7. Balancer for eliminating imbalances in rotating parts. Which can be rotated around the spindle, consisting of first and second continuous rails (1312,1320) are positioned. The same concentricity relative to the spindle of the rotating part, the counterweight is Many of the first movable solids (1313) are positioned in the first rail. And that is prepared in a row One circle, the second set of movable solid weights (1321), is positioned in the second rail and prepared in a single circle. It is characterized by the geometric shape (elemnt) from where the cross section of the first rail was obtained. It differs from the element (element) of the geometric holes in which the cross-section of the second rail is obtained. The counterweight under claim 17 is characterized by the second rail having a quadrangular cross-section 2 0. The counterweight under claim 17 is characterized by the first fluid in the first rail 2. 1.The counterbalance in claim 20 is characterized by the second fluid in the second rail 2. 2. The balancer according to claim 21 is characterized by the second fluid viscosity as It differs from the viscosity of the first fluid 2. 3. The counterweight according to claim 17 is characterized by the locking path for retention. The movement of at least one counterweight is a solid solid. When the angular velocity of the piece The part rotates less than the predetermined angular velocity. And to allow the movement of water The counterweight is a solid set of one. When the angular velocity of the rotating part exceeds the speed Such predetermined angular