JP4472817B2 - Electric cylinder - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electric cylinder that moves an operating rod forward and backward according to the rotation of an electric motor, and pushes and pulls a control object by the operating rod. Specifically, the present invention is suitable for an application in which a large load acts on the operating rod. Further, the present invention relates to a small and lightweight electric cylinder.
[0002]
[Prior art]
Conventionally, a large number of electric cylinders composed of a combination of a servo motor and a ball screw have been proposed. For example, they are used in jacks for lifting a structure, workpiece clamping devices in machine tools, and the like. As a specific structure of such an electric cylinder, an operating rod to be advanced and retracted is fixed to one end of a screw shaft of a ball screw, while a servo motor is rotated by using a timing belt, a gear or the like for a ball nut of a ball screw. It is known that the transmission rod is advanced and retracted according to the amount of rotation of the ball nut. There is also known a structure in which a servo motor is formed in a hollow shape and a ball nut is directly fixed to the rotor of the servo motor.
[0003]
[Problems to be solved by the invention]
By the way, when an electric cylinder is used as a jack or a clamp device, for example, when an operating rod fixed to the tip of a screw shaft pressurizes a work, a reaction force of the applied pressure acts on the operating rod. Must be supported so that the reaction force can be sufficiently loaded.
[0004]
However, in the conventional electric cylinder, the operating rod is fixed to one end of the screw shaft of the ball screw, and the load acting on the operating rod is loaded only by the ball screw, so the supporting rigidity of the operating rod is not sufficient. When the moment load acts on the operating rod due to the reaction force of the applied pressure, there is a problem that the operating rod is displaced and the workpiece cannot be clamped appropriately.
[0005]
In addition, in the conventional electric cylinder, the screw shaft of the ball screw advances and retreats together with the operating rod. Therefore, if the amount of advancement and retraction of the operating rod becomes longer, the screw shaft must be lengthened, and the occupied dimension of the entire electric cylinder becomes larger. In addition to an increase in size, there is a problem that the weight of the apparatus increases.
[0006]
The present invention has been made in view of such problems, and an object of the present invention is to firmly support the operating rod against a moment load acting on the operating rod, An object of the present invention is to provide an electric cylinder capable of reducing the size and weight of the entire apparatus while lengthening the advance / retreat amount.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, the electric cylinder of the present invention has a groove groove and is formed in a channel shape, and a ball rolling groove is formed along the longitudinal direction of the inner surface of the groove groove. A slide that has a track rail and an infinitely circulated ball train and that fits into the groove groove of the track rail via these balls and moves in the groove groove of the track rail along the ball rolling groove. A member, a support plate fixed to one end of the track rail so as to close the groove, a feed screw that is rotatably supported only by the support plate and screwed to the slide member, and the support plate A motor that is fixed to the track rail and rotates the feed screw, and is fixed to the slide member and protrudes from one end of the groove groove of the track rail, and the slide member is moved. An operating rod that advances and retreats in response, the operating rod is formed in a hollow shape and disposed on the same axis as the feed screw, and the feed rod is moved into the hollow portion of the operating rod according to the movement of the slide member. The screw is configured to be accommodated.
[0008]
According to such technical means, when the motor is driven, the rotation is transmitted to the feed screw via the power transmission means, and the slide member is formed in a channel shape according to the rotation amount of the feed screw. The operating rod fixed to the slide member moves forward and backward along the groove groove of the rail. At this time, the slide member moves while being guided by the inner surface of the groove groove of the track rail. However, since this track rail is formed in a channel shape, it has high rigidity against the moment load, and the moment load is applied to the operating rod. Even if this works, it is not easily deformed. Therefore, according to the electric cylinder of the present invention, it is possible to prevent the operating rod from being displaced as much as possible by the reaction force acting on the advance / retreat of the operating rod.
[0009]
Further, since the slide member and the feed screw for advancing and retracting the operating rod are accommodated in the concave groove of the track rail, the electric cylinder of the present invention can have an extremely compact structure with few appearance irregularities. It can be configured to be extremely small and light.
[0010]
Further, since the motor for driving the feed screw is fixed to the rigid rail with the support plate, and the rotation of the motor is transmitted to the feed screw through the power transmission means, the operating rod It is possible to replace only the motor without touching the feed screw and the slide member for advancing and retreating, and it is possible to reduce the labor required for maintenance work.
[0011]
Furthermore, since the operating rod is formed in a hollow shape and is disposed on the same axis as the feed screw, the operating rod moves back into the groove groove of the track rail as the feed screw rotates. However, the leading end of the feed screw is accommodated in the hollow portion of the operating rod, and the operating rod and the feed screw do not interfere with each other. For this reason, it is not necessary to form a space corresponding to the stroke of the actuating rod between the rear end of the actuating rod and the slide member, and the track rail is shortened correspondingly, thereby reducing the size and weight of the entire device. Is possible. In addition, the bracket that fixes the operating rod to the slide member can also be reduced in size, reducing the weight of the mass that reciprocates in the track rail as the feed screw rotates, and the high-speed reciprocating motion of the operating rod. It is also possible to improve the positioning accuracy and reduce the load on the motor that rotationally drives the feed screw.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the electric cylinder of the present invention will be described in detail with reference to the accompanying drawings.
1 to 4 show a first embodiment of an electric cylinder according to the present invention. FIG. 1 is a plan view, FIG. 2 is a front view, FIG. 3 is a right side view, and FIG. 4 is a left side view. ing. In these drawings, reference numeral 1 denotes a track rail formed in a channel shape, reference numeral 2 denotes a slide member which moves while being guided by the track rail 1, and reference numeral 3 denotes a support fixed to one end of the track rail 1 in the longitudinal direction. Reference numeral 4 denotes a servomotor fixed so as to be adjacent to the track rail 1 via the support plate 3, reference numeral 5 denotes a feed screw rotatably supported on the support plate 3, and reference numeral 6 denotes the servomotor 4. Reference numeral 7 denotes a gear train that transmits rotation to the feed screw 5, and an operating rod that advances and retreats according to the movement of the slide member 2.
[0013]
First, as shown in FIGS. 5 and 6, the track rail 1 is formed in a channel shape with a pair of side walls 11, 11 standing on both sides of the base portion 10, and is provided along the longitudinal direction. The slide member 2 is accommodated in the groove 12. Two ball rolling grooves 13, 13 are formed along the longitudinal direction of the track rail 1 on the inner surface of each side wall 11, and the slide member 2 is recessed along the ball rolling groove 13. 12 is moved. The base portion 10 is provided with a plurality of fixing bolt insertion holes 14 so that the track rail 1 can be directly fixed to a frame of an apparatus using the electric cylinder.
[0014]
On the other hand, the slide member 2 is formed in a substantially rectangular shape that is loosely fitted in the groove 12 of the track rail 1 and faces the ball rolling groove 13 formed on the track rail 1 on both outer surfaces thereof. A load ball groove 20 is formed, and the ball 8 rolls between the ball rolling groove 13 of the track rail 1 and the load ball groove 20 of the slide member 2 while applying a load. The slide member 2 is provided with an infinite circulation path 21 of the ball 8 corresponding to each load ball groove 20, and the slide member 2 is caused to endlessly circulate through the load ball groove 20, so that the slide member 2 is turned into the track rail 1. Can move along the stroke without any restriction.
[0015]
The slide member 2 has a through hole 22 through which the feed screw 5 is inserted. The feed screw 5 is screwed into the slide member 2 through a ball 9 in the through hole 22. That is, a spiral ball rolling groove 50 is formed with a predetermined lead on the outer peripheral surface of the feed screw 5, while the ball rolling of the feed screw 5 is performed on the inner peripheral surface of the through hole 22 of the slide member 2. A load ball groove 23 facing the groove 50 is formed in a spiral shape, and the feed screw 5 and the slide member 2 are mutually connected via the ball rolling groove 50 and the ball 9 rolling between the load ball groove 23. It is screwed. The slide member 2 is provided with a return tube 24 for returning the ball 9 spirally rolled between the ball rolling groove 50 and the load ball groove 23 to the original position. Is configured to endlessly circulate between the feed screw and the slide member. Therefore, when the feed screw 5 is rotated, the ball 9 rolls while applying a load between the ball rolling groove 50 of the feed screw 5 and the load ball groove 23 of the slide member 2. The slide member 2 moves in the concave groove 12 of the track rail 1 with a stroke corresponding to the number of rotations.
[0016]
Further, as shown in FIGS. 1 and 2, the operating rod 7 is fixed to the slide member 2 via a guide member 70 having a substantially L-shaped cross section, and the operating rod 7 is connected to the slide member. It is configured to advance and retract from the inside of the groove 12 of the track rail 1 to the outside of the groove 12 according to the stroke of 2. The guide member 70 is fixed to the slide member 2 by fixing bolts 71, while one end of the operating rod 7 is fixed to the guide member 70 by welding. By forming the guide member 70 in a substantially L shape, the axis of the feed screw 5 and the axis of the actuating rod 7 are matched. As a result, the external force acting on the operating rod 7 is prevented from acting as a moment load on the track rail 1 and the feed screw 5 as much as possible. 5 and 6, reference numeral 25 denotes a tap hole into which the fixing bolt 71 is screwed.
[0017]
The operating rod 7 is formed in a hollow shape, and the inner diameter of the hollow portion 7 a is slightly larger than the outer diameter of the feed screw 5. Further, a through hole 70a continuous from the hollow portion 7a of the operating rod 7 is formed in the guide member 70 in which the operating rod 7 is integrated by welding, and the through hole 70a is a through hole formed in the slide member 2. Opposite the hole 22. Accordingly, when the slide member 2 moves backward in the concave groove 12 of the track rail 1 toward the support plate 3 side as the feed screw 5 rotates, the tip of the feed screw 5 protruding from the through hole 22 of the slide member 2 is moved. The guide member 70 is accommodated in the hollow portion 7 a of the operating rod 7 through the through hole 70 a.
[0018]
A support plate 3 is fixed to one end of the track rail 1 in the longitudinal direction so as to close the groove 12, and the feed screw 5 passes through the support plate 3 and is fitted to the support plate 3. A pair of angular contact bearings 30 are rotatably supported. The support plate 3 also serves as a bracket for fixing the servo motor 4 adjacent to the track rail 1, and the gear train 6 is provided on a surface opposite to the surface on which the track rail 1 and the servo motor 4 are fixed. Is formed in a box shape by the plates 31 and 32 and the cover 33.
[0019]
The gear train 6 includes an input gear 61 fixed to the output shaft 40 of the servo motor 4, an output gear 62 fixed to the feed screw 5, and two pieces that transmit rotational power from the input gear 61 to the output gear 62. The speed reduction gears 63 and 64 are configured to reduce the rotational speed of the servo motor 4 to 1/4, for example, and transmit it to the feed screw. The two reduction gears 63 and 64 are rotatably supported via ball bearings with respect to the stud 34 erected on the support plate 3 and are prohibited from relative rotation by a set screw. 63 is in mesh with the input gear 61, while the reduction gear 64 is in mesh with the output gear 62. Thereby, the rotation of the output shaft 40 of the servo motor 4 is transmitted to the feed screw. In this embodiment, the gear train is used as means for transmitting the rotational power from the servo motor 4 to the feed screw 5. However, it is easy to configure the rotational power to be transmitted by a pulley and a timing belt.
[0020]
Further, the end of the feed screw 5 to which the output gear 62 is fixed protrudes from the cover 33 constituting the gear box, and a handle 51 as shown by a two-dot chain line in FIG. 2 is attached to this protruding end. Thus, the feed screw 5 can be manually rotated. Thereby, even if the advance / retreat position of the operating rod 7 is out of order due to a step-out of the servo motor 4 or a power failure, the position can be adjusted manually by rotating the feed screw 5. Normally, the protruding end of the feed screw 5 is covered with a cap 52 fixed to the cover 33.
[0021]
On the other hand, a distal end plate 72 is fixed to one end in the longitudinal direction of the track rail 1 on the side opposite to the support plate 3 so as to block the groove 12, and the operating rod 7 is formed on the distal end plate 72. The through-hole 73 is inserted. Further, a felt seal member 74 slidably contacting the operating rod 7 is provided on the inner diameter of the through-hole 73, while facing the outer peripheral surface of the operating rod 7 with a slight gap on the outer side of the through-hole 73. When the scraper 75 is attached and the operating rod 7 advances and retreats, relatively large foreign matter such as spatter adhering thereto is removed by the scraper 75, and fine dust and the like are further removed on the operating rod 7 by the seal member 74. Has been removed.
[0022]
A cover plate 15 is provided between the support plate 3 and the tip plate 72 so as to cover the groove 12 of the track rail 1. The cover plate 15 is fixed to the track rail 1 by fixing bolts 16. It is fixed to the side wall 11. Rubber seals are sandwiched between the cover plate 15 and the side wall 11, the tip plate 72, and the support plate 3 of the track rail 1, respectively, and in the groove 12 of the track rail 1 sealed by the cover plate 15. Dust and cooling water are completely prevented from entering from the outside. Thereby, even if this electric cylinder is used in a poor environment where dust, cooling water, etc. scatters, the slide member 2 and the feed screw 5 arranged in the groove 12 are contaminated by dust or the like. No, the smooth movement of the slide member 2 due to the rotation of the feed screw 5 can be stably maintained over a long period of time.
[0023]
Further, rubber stopper members 17 are fixed to the inner surfaces of the support plate 3 and the tip plate 72 facing the concave groove 12 of the track rail 1, respectively. When overrun from a predetermined stroke amount, the slide member is abutted and locked.
[0024]
According to the electric cylinder of the present embodiment configured as described above, when the servo motor is rotated, the rotation is transmitted to the feed screw through the gear train, and the slide member according to the rotation of the feed screw. Strokes in the groove of the track rail, and the operating rod fixed to the slide member advances and retreats according to the stroke of the slide member.
[0025]
At this time, according to the electric cylinder of this embodiment, the slide member 2 moves backward in the concave groove 12 of the track rail 1 toward the support plate 3, and the operating rod 7 is connected to the concave groove via the tip plate 72. Even when it is pulled into the groove 12, the operating rod 7 disposed on the same axis as the feed screw 5 is formed in a hollow shape, and the inner diameter of the hollow portion 7 a is larger than the outer diameter of the feed screw 5. The tip of the feed screw 5 protruding from the through hole 22 of the slide member 2 is accommodated in the hollow portion 7a of the operating rod 7 without interfering with the operating rod 7. Become. If the operating rod is not formed in a hollow shape, in order to avoid interference between the operating rod and the feed screw, the slide member 2 may be disposed between the end of the slide member 2 and the rear end of the operating rod 7. A space corresponding to the stroke amount must be provided, and the track rail 1 needs to be at least twice as long as the stroke amount of the slide member 2. However, in this embodiment, the operating rod 7 is formed in a hollow shape, and the tip of the feed screw 5 is configured to be accommodated in the hollow portion 7a of the operating rod 7 in accordance with the movement of the slide member 2. There is no need to provide a space between the end of the slide member 2 and the rear end of the operating rod 7, and the track rail 1 can be made shorter by that much.
[0026]
Thereby, the electric cylinder of a present Example can suppress the full length along the longitudinal direction of the track rail 1, and can achieve size reduction and weight reduction of an apparatus. Further, since the distance from the slide member 2 guided by the track rail 1 to the tip of the operating rod 7 can be kept short, even if a large radial load acts on the tip of the operating rod 7, the operating rod It is also possible to suppress the displacement of the tip of 7. Furthermore, since it is not necessary to provide a space between the end of the slide member 2 and the rear end of the operating rod 7, the guide member 70 that fixes the operating rod 7 to the slide member 2 can be downsized. Further, it is possible to reduce the mass of the mass reciprocating in the concave groove 12 of the track rail 1 and to improve the repeated positioning accuracy in the forward and backward movement of the operating rod 7.
[0027]
FIG. 7 shows a second embodiment of the electric cylinder of the present invention.
In the first embodiment, the servo motor 4 is fixed in parallel to the track rail 1 by the support plate, and the rotation output of the servo motor is transmitted to the feed screw 5 using the gear train 6. In the electric cylinder of the second embodiment shown in FIG. 7, the servo motor 4 is fixed to the support plate so that the output shaft 41 of the servo motor 4 is located on the same axis as the feed screw 5, and the rotation output of the servo motor is output. It is transmitted directly to the feed screw 5 without going through the gear train 6.
[0028]
The output shaft 41 of the servo motor 4 is formed in a hollow shape, and one end of the feed screw 5 is screwed into the hollow portion 42 of the output shaft 41. In other words, the hollow portion 42 of the output shaft 41 is formed with a female screw, while the end portion of the feed screw 5 is formed with a male screw. By fastening them, the feed screw 5 and the output shaft 41 are coupled. Yes. Reference numeral 43 in the figure denotes a lock nut that prevents loosening of the fastening between the output shaft 41 and the feed screw 5. Normally, a coupling or the like is required to connect the motor output shaft 41 and the feed screw 5 arranged on the same axis, but in this way, the electric cylinder of this embodiment outputs the output of the servo motor 4. Since the shaft 41 is formed in a hollow shape, the output shaft 41 and the feed screw 5 can be directly coupled to each other, and the total length of the electric cylinder can be reduced by that much. Further, when the rotation output of the servo motor 4 is transmitted to the feed screw 5 via the gear train 6, an error is likely to occur in the rotation accuracy of the feed screw 5 and consequently the advance / retreat accuracy of the operating rod 7 due to backlash between the gears. However, in the electric cylinder of this embodiment, the output shaft 41 of the servo motor 4 and the feed screw 5 are directly coupled, so that the advance / retreat accuracy of the actuating rod 7 is improved.
[0029]
A hexagonal hole 44 is formed at the open end of the output shaft 41 of the servo motor 4 formed in a hollow shape, that is, at the end opposite to the coupling end of the feed screw 5. Can be equipped with a handle for manually rotating the feed screw 5. In the first embodiment, one end of the feed screw 5 is protruded from the gear box so that the handle 51 can be attached to the feed screw 5. In this embodiment, the servo motor 4 is thus constructed. Since the output shaft 41 is provided with a hexagonal hole 44 and a handle is fitted therein, it is not necessary to project the end of the feed screw 5 from the motor housing 45 of the servo motor 4. The overall length of the cylinder is shortened.
[0030]
【The invention's effect】
As described above, according to the electric cylinder of the present invention, the operating rod can be firmly supported against the moment load acting as the operating rod advances and retreats, and the operating rod is displaced. It becomes possible to prevent as much as possible.
[0031]
Further, the feed screw is configured to be accommodated in the hollow portion of the operating rod according to the movement of the slide member, and the operating rod is retracted into the concave groove of the track rail according to the rotation of the feed screw. However, since the leading end of the feed screw does not interfere with the rear end of the actuating rod, the track rail can be shortened to that extent, and the entire apparatus can be reduced in size and weight. In addition, it is possible to reduce the size of the bracket that fixes the operating rod to the slide member and reduce the weight of the mass that reciprocates within the track rail. It is also possible to improve and reduce the load on the motor that rotationally drives the feed screw.
[Brief description of the drawings]
FIG. 1 is a plan view showing a first embodiment of an electric cylinder according to the present invention.
FIG. 2 is a front view showing a first embodiment of the electric cylinder of the present invention.
FIG. 3 is a right side view showing a first embodiment of the electric cylinder of the present invention.
FIG. 4 is a left side view showing the first embodiment of the electric cylinder of the present invention.
FIG. 5 is a perspective view showing a track rail, a slide member, and a feed screw according to the first embodiment.
FIG. 6 is a sectional view showing an engaged state of the track rail, the slide member, and the feed screw according to the first embodiment.
FIG. 7 is a plan view showing a second embodiment of the electric cylinder of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Track rail, 2 ... Slide member, 3 ... Support plate, 4 ... Servo motor, 5 ... Feed screw, 7 ... Actuation rod, 7a ... Hollow part, 12 ... Concave groove

Claims (3)

A track rail having a groove and formed in a channel shape and having a ball rolling groove formed along the longitudinal direction of the inner surface of the groove, and a ball train that circulates infinitely. And a slide member that moves in the groove groove of the track rail along the ball rolling groove and the track rail so as to close the groove groove. A support plate fixed to one end, a feed screw that is rotatably supported only by the support plate and screwed to the slide member, and is fixed to the track rail via the support plate and rotates the feed screw a motor for, while one end of Ru is fixed to the slide member via a guide member formed in a substantially L-shape, the other end of the concave groove of the track rail without being supported on the track rail one Consists of projecting, an actuating rod which moves forward and backward according to the movement of the slide member,
The actuating rod is formed in a hollow shape and arranged on the same axis as the feed screw, and the feed screw is accommodated in the hollow portion of the actuating rod according to the movement of the slide member. A featured electric cylinder.   2. The electric cylinder according to claim 1, wherein the motor has a hollow output shaft, and the feed screw is coupled to the motor by inserting one end thereof into the output shaft.   The electric cylinder according to claim 2, wherein a handle attachment hole for manually rotating the feed screw is formed at an open end of the output shaft of the motor.

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