阅读说明：本技术 线性致动器 (Linear actuator ) 是由 J·莱珂 于 2019-01-22 设计创作，主要内容包括：线性致动器包括电机(2),电机通过传动装置(3)来驱动心轴单元,心轴单元包括至少一个心轴(4),心轴带有心轴螺母(5),心轴(4)配备有轴承(8)。大致管状调节元件(6)与心轴单元相连。为了在电机(2)的供电中断时将调节元件(6)保持在给定位置,设置了制动器(11),其包括弹簧(15)和圆筒形元件(12)。圆筒形元件(12)具有螺纹销(12a),螺母(13)布置在螺纹销上,弹簧(15)围绕圆筒形元件(12)定位在螺母(12)一侧和圆筒形元件(12)上的止动件(14)之间,使得弹簧(15)将螺母(13)另一侧压靠在接触表面(16)上。因此,通过螺母一侧摩擦接触表面而产生制动力。因此,这是一种替代制动器结构,具有简单结构且弹簧仅施加压缩力。可根据弹簧力、螺母和接触表面之间的摩擦力及最终螺母上的螺距来调节制动力。(The linear actuator comprises an electric motor (2) driving a spindle unit by means of a transmission (3), the spindle unit comprising at least one spindle (4) with a spindle nut (5), the spindle (4) being equipped with a bearing (8). A substantially tubular adjustment element (6) is connected to the spindle unit. In order to keep the adjustment element (6) in a given position when the supply of current to the motor (2) is interrupted, a brake (11) is provided, which comprises a spring (15) and a cylindrical element (12). The cylindrical element (12) has a threaded pin (12a) on which the nut (13) is arranged, a spring (15) being positioned around the cylindrical element (12) between one side of the nut (12) and a stop (14) on the cylindrical element (12), so that the spring (15) presses the other side of the nut (13) against the contact surface (16). Thus, a braking force is generated by the frictional contact surface on the nut side. Thus, this is an alternative brake structure, with a simple structure and the spring only applying a compressive force. The braking force can be adjusted based on the spring force, the friction between the nut and the contact surface and finally the pitch on the nut.)

1. A linear actuator, comprising: a motor (2) having a motor shaft; the transmission device (3) is connected with the motor shaft; a spindle unit connected to the transmission, wherein the spindle unit comprises at least one spindle (4) with a spindle nut (5), wherein the spindle (4) is equipped with a bearing (8); an adjusting element (6) connected to the spindle unit; brake (11) comprising a spring (15) and a cylindrical element (12) for holding the adjustment element (6) in a given position when the supply of power to the motor (2) is interrupted, characterized in that the cylindrical element (12) has a threaded pin (12a) on which a nut (13) is arranged; a spring (15) is positioned around the cylindrical element (12) between one side of the nut (12) and a stop (14) on the cylindrical element (12), so that the spring (15) presses the other side of the nut (13) against the contact surface (16).

2. Linear actuator according to claim 1, characterized in that the spring (15) is a helical spring.

3. Linear actuator according to claim 1, characterized in that the spring (15) is a torsion spring.

4. Linear actuator according to claim 1, characterized in that the brake (11) is arranged on the rear end, i.e. the shaft of the spindle (4).

5. Linear actuator according to claim 1, characterized in that the brake (11) is arranged on the motor shaft.

6. Linear actuator according to claim 1, characterized in that the cylindrical element (12) is constructed as a separate element.

7. Linear actuator according to claim 1, characterized in that the linear actuator comprises a housing (1) and the contact surface (16) is constituted by a side surface of the housing (1).

Technical Field

The invention relates to a linear actuator comprising: a motor having a motor shaft; the transmission device is connected with the motor shaft; a spindle unit connected with the transmission, the spindle unit comprising at least one spindle with a spindle nut, the spindle being equipped with a bearing; an adjustment element connected with the spindle unit; and a stopper including a spring and a cylindrical member for holding the regulating member at a given position when the power supply to the motor is interrupted.

Background

In general, the linear actuator should be self-locking to ensure that the actuating element, which is still under maximum load, remains in the desired position also when the supply of the motor is interrupted. In this regard, linear actuators can be generally classified into linear actuators equipped with a self-locking spindle and linear actuators equipped with a non-self-locking spindle. Whether the mandrel is self-locking or non self-locking depends primarily on the thread pitch. If the pitch is below the friction coefficient, the spindle is self-locking; if the pitch is large, the spindle is not self-locking. However, friction is ambiguous and depends on various conditions such as material, processing of the material, lubrication, temperature, and dynamic effects (e.g., vibration). Furthermore, static friction and dynamic friction are distinguished from each other, static friction being greater than dynamic friction.

There are a number of reasons why non-self-locking mandrels have advantages over self-locking mandrels. One reason is that non-self-locking mandrels have a higher efficiency than self-locking mandrels, which means that the non-self-locking mandrels operate with lower energy consumption than self-locking mandrels. Another reason is that the non-self-locking spindles are adjusted faster than self-locking spindles due to the larger pitch. On the other hand, it should be considered that the linear actuator should generally be self-locking, so that the actuating element remains in the position that has been reached when the supply of the motor is interrupted. This results in a mandrel with a pitch that is generally chosen to be close to self-locking.

In actuators with a positive self-locking spindle, such as a ball screw, a "parking brake" is used, which prevents the spindle from rotating when the supply of current to the motor is interrupted, so that the actuating element is held in the position that has been reached when the supply of current to the motor is interrupted. For example, the "parking brake" may be a solenoid brake or a coil spring, wherein both ends of the spring are actuated. The solenoid brake includes a brake disk that is operated by an electromagnet. For a "parking brake" with a helical spring, the outside thereof is tightened against the surrounding wall, and there is a dog clutch in the hollow of the spring, the two bent ends of the spring engaging with respective portions of the dog clutch. When the motor is started, the dog clutch pulls one or the other end of the spring and tightens it to reduce the diameter of the spring, thereby disengaging the spring from engagement with the surrounding wall. Here, the spring functions as a clutch spring, and does not play an actual braking function by itself. Such a "parking brake" is disclosed in WO 2005/079134A 2, for example, LINAK A/S. This brake is particularly effective, but is relatively expensive and takes up relatively large space, resulting in an increased installed length of the actuator. Another brake, not only a parking brake, but also generally used when the spindle is near self-locking, comprises two cylindrical elements coupled by a helical spring. A needle bearing is located between the two cylindrical elements, and a friction disc is located between a free end portion of one of the two cylindrical elements and the fixed portion. In one direction of rotation of the spindle, the two cylindrical elements are released from each other and the spindle can rotate freely. In the other direction of rotation, the two cylindrical elements are coupled together, actuating the friction discs to brake the spindle. Here, the spring also functions as a clutch spring because it couples and decouples the two cylindrical members, respectively. Such a brake is disclosed, for example, in US 5,910,692B 1 by Tsubakimoto Chain. It should be noted that such brakes were originally developed and introduced by the Washington electric company, USA. This construction of the brake is good in itself, but consists of relatively many components, is relatively expensive and takes up a lot of space. A different and simple brake is known which simply comprises a helical spring located around the end cylindrical element of the spindle or the gear in the transmission. In one direction of rotation of the spindle, the spring will be released from the cylindrical element and the spindle may rotate freely. This is due to: the angular orientation of the spring is such that it is affected to try to unwind from the cylindrical element, whereby the diameter of the spring is enlarged. In the other direction of rotation of the spindle, the spring will tighten itself around the cylindrical element and exert a braking force, keeping the spindle still in the event of interruption of the power supply to the motor. The braking force is adapted such that it can be overcome by the motor when the actuating element is reversed towards the initial position. Thus, the brake actively helps to stop the spindle when the power supply of the motor is interrupted, just as the brake is active when the actuating element reverses towards the initial position, i.e. the brake damps the return speed of the actuating element. In contrast to the brake mentioned above, the spring here acts as an actual brake, i.e. the spring itself exerts a braking force. Such a brake was developed and introduced by LINAK A/S and is disclosed in EP 0662573B 1 of LINAK A/S. Such a brake is widely used because it is effective and very inexpensive. However, it is difficult to determine the braking force, since the friction is ambiguous and depends on e.g. lubrication and temperature. Germany OKIN discloses a brake wherein the spring brake has a circular cross-section, whereby the hollow between two adjacent windings serves as a lubricant reservoir. On the other side, the contact surface of the spring is linear, as opposed to a spring with a square cross-section, which is flat. Furthermore, conventionally, the spring is placed on the cylindrical projecting edge of the worm wheel made of plastic, and the spring tends to cut into the plastic, which also makes it difficult to determine the braking force. When the actuator is operated, heat is generated in the worm wheel, and further frictional heat is generated between the spring and the worm wheel-side cylindrical member during the period from braking to complete stop and during the return movement. This heat generation has a negative effect on the dimensional stability of the worm wheel, so that the spring will cut into the cylindrical element more easily over time. For example, it has been sought to solve this problem by placing a metal bushing around a cylindrical element on the worm gear so that the spring engages the metal bushing and does not come into direct contact with the worm gear. However, this does not solve the problem of heat generation of the worm wheel, and in addition, noise is generated when the bush rubs against the spring during rotation.

Disclosure of Invention

Starting from the latter brake configuration described above, it is an object of the present invention to provide an alternative brake configuration which is equally simple, but which avoids at least some of the problems described above.

According to the invention this is achieved by constructing the linear actuator as claimed in claim 1, wherein the cylindrical element has a threaded pin, the nut is arranged on the threaded pin, and the spring is positioned around the cylindrical element between one side of the nut and a stop on the cylindrical element, such that the spring presses the other side of the nut against the contact surface. Thus, a braking force is generated by the frictional contact surface on the nut side. The braking force applied is therefore dependent on the spring force. The greater the spring force, the greater the braking force. The braking force also depends on the friction between the nut and the contact surface. I.e. the greater the friction, the greater the braking force. Finally, the pitch is also important for the braking force. A lower pitch results in a greater braking force. When the cylindrical element rotates with the pitch of the thread, the nut tends to unscrew itself from the contact surface due to friction between the nut and the contact surface. On the other hand, when the cylindrical element rotates with the pitch, the nut tends to tighten against the contact surface, increasing the braking force.

In an embodiment, the spring is cylindrical, so that it can simply push against the thread of the cylindrical element. The decisive factor here is the spring force of the spring, but the accuracy of the spring wire is not as particularly required as is the case with the spring brake according to EP 0662573B 1, the spring tension and the contact surface around the cylindrical element being very important in EP 0662573B 1.

In an alternative embodiment, the spring is a torsion spring, one end being held in the nut and the other end being held in the cylindrical element. In the nut, the end of the spring may preferably be held in the slit; in the cylindrical element, the end of the spring may be held in the groove.

As mentioned above, the brake may be arranged on a cylindrical element in the actuator and in an embodiment it is arranged on the rear end, i.e. the shaft of the spindle, i.e. the spindle unit may be constructed as an integrated unit with the brake ready to be mounted in the actuator.

In another embodiment, the brake is arranged on the motor shaft, with the advantage that the torque to which the brake is subjected is not very large.

The cylindrical element for the brake can be constituted by the rotary element around which the brake is constructed. In one embodiment, the cylindrical element is configured as a separate element mounted on the rotating element. Thus, the threaded cylindrical element can be manufactured in a more precise manner, or can be cast as an integral unit from a suitable plastic material.

The contact surface with which the nut of the brake cooperates may be constituted by a separate element, however it is preferred to use an existing surface of the actuator, for example a side surface of the housing.

Drawings

A linear actuator according to the present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which:

fig. 1 shows a linear actuator comprising a two-part housing, but with one part removed,

figure 2 shows a detail of the brake of the linear actuator,

FIG. 3 shows a longitudinal section through the detail of FIG. 2, an

Fig. 4 shows a perspective view of a detail of fig. 2.

Detailed Description

Fig. 1 shows an actuator comprising a two-part housing 1 made of plastic and a reversible electric motor 2 which drives a spindle 4 with a spindle nut 5 via a worm wheel 3, to which an actuating rod 6 (also referred to as inner tube) surrounded by an outer tube 7 is fixed, the outer tube serving as a guide for the actuating rod 6. One end of the spindle 4 is embedded in the housing 1 together with the bearing 8. The actuator is mounted in the structure to be received by a rear mounting 9 mounted at the rear end of the housing 1 and a front mounting 10 mounted at the free end of the actuator rod 6.

The rear end (the shaft 4a of the spindle 4) is equipped with a braking mechanism 11, described more fully with reference to figures 2, 3 and 4 of the drawings. Mounted on the shaft 4a of the spindle 4 is a cylindrical element 12 in the form of a bush, fixed non-rotatably, having an externally threaded portion 12 a. The nut 13 is disposed on the threaded pin 12 a. An annular stopper 14 is fixed to the end, i.e., the front end of the cylindrical member 12. Between the stop 14 and the front side of the nut 13, a coil or helical spring 15 is arranged, which exerts a compressive force on the nut 13. Since the threads on the cylindrical element 12 and the nut 13 are non self-locking, the nut 13 will be pushed back against the contact surface 16, which here is constituted by the side of the seat 17 on which the bearing 8 for the spindle 4 is seated. At the rearmost end of the spindle 4, a clutch portion 18 is mounted for interconnection with the output stage of the actuator's transmission. As can be seen, the bearings are embedded in the annular portion 19 of the cylindrical member 12 and the clutch portion 18.