阅读说明：本技术 旋转接头 (Rotary joint ) 是由 高井智久 竹内嘉彦 于 2020-11-19 设计创作，主要内容包括：本发明提供一种旋转接头。在以往的旋转接头中,在能够无限旋转的旋转接头中存在难以进行高速的通信的问题。本发明所涉及的旋转接头的一个方式具有：第1微带线(13)；第2微带线(23)；与第1微带线(13)的一端连接,输出通信信号的发送电路(14)；与第1微带线(13)的另一端连接的发送侧终端电阻(15)；与第2微带线(23)的一端连接的接收侧终端电阻(25)；以及与第2微带线(23)的另一端连接,接收通信信号的接收电路(24),第1微带线(13)以及第2微带线(23)被设定于通信信号在微带线传播的行波的波长的整数倍的圆周长度的圆环的至少一部分。(The invention provides a rotary joint. In a conventional rotary joint, it is difficult to perform high-speed communication in a rotary joint that can be rotated infinitely. One embodiment of a rotary joint according to the present invention includes: a 1 st microstrip line (13); a 2 nd microstrip line (23); a transmission circuit (14) connected to one end of the 1 st microstrip line (13) and outputting a communication signal; a transmission-side terminating resistor (15) connected to the other end of the 1 st microstrip line (13); a reception-side terminating resistor (25) connected to one end of the 2 nd microstrip line (23); and a receiving circuit (24) connected to the other end of the 2 nd microstrip line (23) and receiving the communication signal, wherein the 1 st microstrip line (13) and the 2 nd microstrip line (23) are set to at least a part of a circular ring having a circumferential length that is an integral multiple of the wavelength of the traveling wave of the communication signal propagating through the microstrip lines.)

1. A rotary joint, comprising:

a 1 st microstrip line provided along an arc set on the stationary body of the rotary joint;

a 2 nd microstrip line that is fitted to a rotating body of a stationary body of the rotary joint in an infinitely rotatable state and is provided along a predetermined arc so as to face the 1 st microstrip line;

the transmitting circuit is connected with one end of the 1 st microstrip line and outputs a communication signal;

the transmitting side terminal resistor is connected with the other end of the 1 st microstrip line;

a receiving side terminal resistor connected with one end of the 2 nd microstrip line; and

a receiving circuit connected with the other end of the 2 nd microstrip line for receiving the communication signal,

the 1 st microstrip line and the 2 nd microstrip line are provided on at least a part of a ring having a circumferential length of an integral multiple of a wavelength of a traveling wave of the communication signal propagating on the microstrip line, the 1 st microstrip line and the 2 nd microstrip line are disposed in proximity so that the traveling waves propagating on each of them are loosely coupled by an electromagnetic field,

when a direction from the transmission circuit toward the transmission-side terminating resistor is a 1 st direction, the reception circuit is disposed on a leading end side in the 1 st direction of the 2 nd microstrip line, and the reception-side terminating resistor is disposed on a root side in the 1 st direction of the 2 nd microstrip line.

2. The swivel joint of claim 1,

the 1 st microstrip line and the 2 nd microstrip line are arranged on opposite planes.

3. The rotary joint according to claim 1 or 2,

and the shielding part surrounds the 1 st microstrip line and the 2 nd microstrip line and shields the communication signals.

4. The swivel joint of claim 1,

the 1 st microstrip line and the 2 nd microstrip line are arranged on opposite cylindrical surfaces.

5. A swivelling joint as claimed in any one of claims 1 to 4, wherein,

the power transmission device further includes a transformer that is provided in an inner peripheral portion of the annular portion where the 1 st microstrip line and the 2 nd microstrip line are arranged, and that transmits and receives electric power between the stationary body and the rotating body.

6. A swivelling joint as claimed in any one of claims 1 to 5, wherein,

the stationary body and the rotating body are detachably coupled.

Technical Field

The present invention relates to a rotary joint, and more particularly to a rotary joint for performing communication between a stationary body and a rotating body in a joint portion that rotates endlessly.

Background

In order to use an arm for multiple purposes, a robot arm has been proposed in which an arm is used for multiple purposes by replacing a hand attached to the tip of the arm. In such applications, the hand may be freely rotated with respect to the arm as a stationary body. When the hand is rotatably attached in this manner, a rotary joint that supports the rotating body so as to be able to rotate endlessly is used as the joint portion. In the rotary joint, communication is performed between the stationary body and the rotating body. Accordingly, an example of a method of arranging antennas at a rotary joint is disclosed in japanese patent laid-open No. 2002-33607.

The rotary joint described in jp 2002-33607 a has a structure for fixing an antenna element substrate, which is a structure for fixing an antenna element substrate in a non-contact signal transmission device as follows: a pair of antenna element substrates holding an antenna element comprising inner and outer double rings around a rotation axis are attached to a rotating body fixed to the rotation axis and a stationary body stationary to the rotating body via support members, respectively, and each antenna element substrate is fixed to a plurality of positions between the inner and outer double rings at a predetermined angular interval with respect to the support members.

In the robot arm, it is not sufficient to perform only communication of status information in order to control the hand portion, and high-speed communication for executing real-time control is required. However, the antenna element substrate disclosed in japanese patent application laid-open No. 2002-33607 has a problem that it is difficult to perform high-speed communication.

Disclosure of Invention

The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a rotary joint capable of rotating infinitely, which performs high-speed communication by utilizing loose coupling between microstrip lines.

One embodiment of a rotary joint according to the present invention includes: a 1 st microstrip line provided along a circular ring set on the stationary body of the rotary joint; a 2 nd microstrip line that is fitted to a rotating body of the stationary body of the rotary joint in an infinitely rotatable state and is provided along a predetermined circular ring so as to face the 1 st microstrip line; a transmission circuit connected to one end of the 1 st microstrip line and configured to transmit a communication signal; a transmission-side terminating resistor connected to the other end of the 1 st microstrip line; a reception-side terminating resistor connected to one end of the 2 nd microstrip line; and a receiving circuit connected to the other end of the 2 nd microstrip line and configured to receive the communication signal, wherein the 1 st microstrip line and the 2 nd microstrip line are set to at least a part of a circular ring having a circumferential length that is an integral multiple of a wavelength at which the communication signal propagates through the microstrip line, and when a direction from the transmitting circuit toward the transmitting-side terminating resistor is a 1 st direction, the receiving circuit is disposed on a tip side in the 1 st direction of the 2 nd microstrip line, and the receiving-side terminating resistor is disposed on a root side in the 1 st direction of the 2 nd microstrip line.

According to the rotary joint of the present invention, it is possible to perform non-contact high-speed communication between the stationary body and the rotating body using a broadband communication signal at a high carrier (RF) frequency, by means of the microstrip line set to at least a part of the circular ring having the circumferential length of an integral multiple of the wavelength at which the communication signal propagates through the microstrip line.

According to the present invention, in a rotary joint having a rotating body that can endlessly rotate relative to a stationary body, non-contact high-speed communication can be performed between the stationary body and the rotating body.

The above and other objects, features and advantages of the present disclosure will become more fully understood from the detailed description given herein below and the accompanying drawings, which are given by way of illustration only, and thus should not be taken as limiting the present disclosure.

Drawings

Fig. 1 is a schematic view of a rotary joint according to embodiment 1.

Fig. 2 is a block diagram of a communication interface circuit according to embodiment 1.

Fig. 3 is a schematic view of a rotary joint according to embodiment 2.

Fig. 4 is a schematic view of a rotary joint according to embodiment 3.

Fig. 5 is a schematic view of a rotary joint according to embodiment 4.

Detailed Description

Embodiment mode 1

First, fig. 1 shows a schematic view of a rotary joint 1 according to embodiment 1. As shown in fig. 1, a rotary joint 1 according to embodiment 1 includes a stationary body 10 and a rotating body 20. The stationary body 10 is, for example, a joint portion attached to the tip of an arm portion of a robot arm. The rotating body 20 is a joint portion of a hand portion of the robot arm. The rotating body 20 has a structure that can be attached to and detached from the stationary body 10. In fig. 1, the details of the detachable structure are omitted. The rotating body 20 is attached to be capable of infinitely rotating along a plane orthogonal to the attaching and detaching direction to the stationary body 10.

The stationary body 10 has a housing 11. The housing 11 is provided with a joint recess 12. The joint recess 12 is a hole into which the joint protrusion 22 is fitted. Further, the housing 11 has a flat surface facing the rotating body 20. Further, a 1 st microstrip line 13 is provided on the plane.

The rotating body 20 has a housing 21. Further, the housing 21 is provided with a joint projection 22. The joint projection 22 is a projection member projecting from the housing 21. The housing 21 has a flat surface facing the stationary body 10. Further, a 2 nd microstrip line 23 is provided on the plane.

Here, the 1 st microstrip line 13 and the 2 nd microstrip line 23 are arranged so that the lines face each other on mutually facing planes. The 1 st microstrip line 13 is provided along an arc set on the stationary body 10, and the 2 nd microstrip line 23 is provided along an arc set on the rotating body 20. The 1 st microstrip line 13 and the 2 nd microstrip line 23 are preferably formed in shapes in which propagation constants of traveling waves propagating respectively are equal to each other. Here, the 1 st microstrip line 13 and the 2 nd microstrip line 23 are arranged so that the lines face each other on mutually facing planes. Thus, a part of the signal (traveling wave) propagating through the 1 st microstrip line is converted into a traveling wave having the same propagation constant through the loose coupling of the electromagnetic field generated by the electromagnetic wave propagating through the microstrip line, and the traveling wave propagates through the 2 nd microstrip line. In addition, a part of the signal (traveling wave) that similarly propagates through the 2 nd microstrip line is converted into a traveling wave having the same propagation constant through the 1 st microstrip line. In the example shown in fig. 1, the 1 st microstrip line 13 and the 2 nd microstrip line 23 are shown as circular shapes having no notch, but actually have arc shapes having a notch in part in order to connect a transmission circuit, a reception circuit termination resistor, and the like.

The details of the communication interface circuit using the microstrip line in the rotary joint 1 will be described in detail. Fig. 2 shows a block diagram of a communication interface circuit according to embodiment 1.

As shown in fig. 2, in the communication interface circuit according to embodiment 1, the 1 st microstrip line 13 and the 2 nd microstrip line 23 are provided in an arc shape with end portions thereof being separated from each other. In fig. 2, for the sake of easy understanding, the ends of the microstrip line are separated to a large extent. However, the separation width may be extremely small in practice. The following microstrip line length condition is satisfied for the separation width. The microstrip line length condition is as follows: the circumferential lengths (circular rings) of the 1 st microstrip line 13 and the 2 nd microstrip line 23 having no separation width are integral multiples of the wavelength of the RF signal propagating, and the microstrip lines are provided in a part or all of the circumferential lengths. That is, the microstrip line length condition means: the length of the ring in which the 1 st microstrip line 13 and the 2 nd microstrip line 23 are provided is an integral multiple of the wavelength of the communication signal propagating on the microstrip lines, and the microstrip lines 13 and 23 actually radiating the communication signal are provided in at least a part of the ring. By determining such a microstrip line length condition, it is possible to accurately transmit and receive an RF signal between the transmission circuit 14 and the reception circuit 24 regardless of the relative rotational position of the 1 st microstrip line 13 and the 2 nd microstrip line 23 (details will be described later).

A transmission circuit 14 is provided at one end of the 1 st microstrip line 13, and a transmission-side terminator (for example, a termination resistor 15) is provided at the other end of the 1 st microstrip line 13. The transmission circuit 14 outputs an RF signal as a communication signal to the 1 st microstrip line 13. The RF signal is a traveling wave traveling on a microstrip line. The RF signal travels in the 1 st direction from the transmission circuit 14 toward the termination resistor 15. Further, the RF signal is transmitted from the 1 st microstrip line 13 to the 2 nd microstrip line 23 by electromagnetic field coupling between the 1 st microstrip line 13 and the 2 nd microstrip line 23. In fig. 2, RF signals are labeled for the purpose of illustration.

A reception-side terminator (for example, a terminating resistor 25) is provided at one end of the 2 nd microstrip line 23, and a reception circuit 24 is provided at the other end of the 2 nd microstrip line 23. More specifically, the receiving circuit 24 is connected to an end portion of the 2 nd microstrip line 23 that is located on the leading end side as viewed in the 1 st direction. The terminating resistor 25 is connected to an end portion located on the root side as viewed in the 1 st direction, among the end portions of the 2 nd microstrip line 23.

In the rotary joint 1 according to embodiment 1, the 1 st microstrip line 13 and the 2 nd microstrip line 23 are in a state of being close to each other in a state where the rotating body 20 is attached to the stationary body 10. Then, in a state where the 1 st microstrip line 13 and the 2 nd microstrip line 23 are close to each other, the RF signal is transmitted to the 1 st microstrip line 13 by the transmission circuit 14, and the RF signal is excited in the 2 nd microstrip line 23 electromagnetically coupled to the 1 st microstrip line 13. Further, the RF signal transferred to the 2 nd microstrip line 23 is received by the receiving circuit 24.

The microstrip line has a structure in which a linear conductor foil is formed on the surface of a plate-shaped dielectric substrate having a conductor foil formed on the back surface thereof, and is a transmission path for transmitting electromagnetic waves. The microstrip line transmits an electromagnetic wave (traveling wave) by an electric field in a direction from the front surface conductor toward the rear surface conductor and a magnetic field in a direction surrounding the periphery of the front surface conductor. Since propagation constants (propagation velocity and characteristic impedance) of the traveling wave propagating through the microstrip line are mainly determined by the line width of the microstrip line, the dielectric constant of the dielectric substrate, and the substrate thickness, it is preferable to match the shape and the dielectric constant of the 1 st and 2 nd microstrip lines in order to match the propagation constants. The carrier (RF) frequency of the signal transmitted through the microstrip line is a frequency of a GHz band or more having a relatively small bandwidth, which is small in phase and amplitude fluctuation per unit wavelength of the electromagnetic wave traveling on the line even when the communication frequency bandwidth to be transmitted is wide, and high-speed data communication can be performed by a broadband signal.

As described above, in the rotary joint 1 according to embodiment 1, the 1 st microstrip line 13 and the 2 nd microstrip line 23 are provided so as to face each other on the facing surfaces in the state where the joint projection 22 of the rotating body 20 is fitted in the housing 11 of the stationary body 10. The 1 st microstrip line 13 and the 2 nd microstrip line 23 are provided on at least a part of a circular ring having a length that is an integral multiple of the wavelength of the RF signal propagating through these microstrip lines. The traveling wave propagating through the 1 st microstrip line 13 becomes a part of a virtual traveling wave traveling endlessly on the ring, and a part of the virtual traveling wave also traveling endlessly on the ring is excited by the electromagnetic field generated along with the traveling wave in the 2 nd microstrip line 23. Since the traveling wave excited by the 2 nd microstrip line 23 forms a part of a virtual traveling wave traveling endlessly on the ring, even if the 1 st and 2 nd microstrip lines are not the entire ring but a part thereof, and the position thereof corresponds to any part of the virtual traveling wave, the operation excited by the 2 nd microstrip line 23 does not change. The propagation velocity of the pseudo traveling wave is a value obtained by multiplying the light velocity by a wavelength shortening factor (about 50%) determined by the shape of the microstrip line, and can be said to approximate the light velocity. Therefore, considering the rotating body 20 as a quasi-stationary state, the influence of the rotation speed of the rotating body is extremely low. As a result, in the rotary joint 1 according to embodiment 1, high-speed communication using a wide-band RF signal at a high frequency can be performed between the stationary body 10 and the rotary body 20 while the rotary body 20 is infinitely rotated.

In addition, in the rotary joint 1 according to embodiment 1, near field wireless communication of, for example, several mm or less is performed, and high-speed communication is possible even if the signal intensity of the RF signal is weak. By performing communication using an RF signal having a weak signal strength in this manner, leakage of a signal to other components is suppressed, and the rotary joint 1 can be used in a communication path for each of a plurality of joints provided in the robot arm, for example.

Embodiment mode 2

In embodiment 2, a rotary joint 2 having a power supply function to a rotary body in addition to a communication function will be described. Note that the same reference numerals as those in embodiment 1 are given to the constituent elements described in embodiment 1, and the description thereof is omitted.

Fig. 3 shows a schematic view of a rotary joint according to embodiment 2. As shown in fig. 3, the rotary joint 2 according to embodiment 2 includes a stationary body 10a and a rotating body 20a instead of the stationary body 10 and the rotating body 20. The stationary body 10a is a member in which a primary coil 16 is added to the stationary body 10. The rotor 20a is a component in which the secondary coil 26 is added to the rotor 20. The primary coil 16 and the secondary coil 26 are arranged to overlap concentrically with each other in a joined state where the joint protrusion 22 is fitted in the joint recess 12, and constitute a transformer for wirelessly transmitting power from the stationary body 10 to the rotating body 20.

Specifically, the primary coil 16 is disposed along the outer periphery of the cylinder constituting the joint recess 12. The secondary coil 26 is disposed along the inner circumference of the cylinder constituting the joint protrusion 22. In a state where the joint convex portion 22 is fitted in the joint concave portion 12, the secondary coil 26 is fitted concentrically inside the primary coil 16, that is, the transformer is configured by the primary coil 16 and the secondary coil 26 in a state where the rotating body 20a is joined to the stationary body 10 a.

In this way, by providing a coil to the stationary body 10a and the rotating body 20a to form a transformer, electric power can be supplied from the stationary body 10a to the rotating body 20a by wireless connection. When the rotating body 20a is caused to rotate relative to the stationary body 10a without limitation, electric power is supplied by wireless connection, and the operation of the rotating body 20a is not hindered, so that the effect is great.

Embodiment 3

In embodiment 3, another mode of a method of disposing the 1 st microstrip line 13 and the 2 nd microstrip line 23 will be described. Note that the same reference numerals as those in embodiment 1 are assigned to the constituent elements described in embodiment 1, and the description thereof is omitted.

Fig. 4 shows a schematic view of a rotary joint 3 according to embodiment 3. As shown in fig. 4, the rotary joint 3 according to embodiment 3 includes a stationary body 10b and a rotating body 20b in place of the stationary body 10 and the rotating body 20. In the stationary body 10b, the 1 st microstrip line 13 is provided along the inner periphery of the joint recess 12. In addition, in the rotator 20b, the 2 nd microstrip line 23 is wound along the outer periphery of the tab projection 22. In addition, the 1 st microstrip line 13 and the 2 nd microstrip line 23 are provided at positions facing each other in a state where the contact convex portion 22 is fitted in the contact concave portion 12.

Even in this manner, the transmission and reception of signals between the 1 st microstrip line 13 and the 2 nd microstrip line 23 can be performed in a state where the contact convex portion 22 is fitted in the contact concave portion 12. That is, the place of installation of the microstrip line is not limited to the plane of the case 11 and the case 21, and the communication path can be configured even if the microstrip line is installed on the cylindrical surface facing each other in the joined state.

Embodiment 4

In embodiment 4, a rotary joint 4 as another embodiment of the rotary joint 1 according to embodiment 1 will be described. Note that the same reference numerals as those in embodiment 1 are given to the constituent elements described in embodiment 1, and the description thereof is omitted.

Fig. 5 shows a schematic view of a rotary joint according to embodiment 4. As shown in fig. 5, the rotary joint 4 according to embodiment 4 includes a rotary body 20c instead of the rotary body 20. The rotor 20c is a member in which a shield wall 27 is added to the rotor 20. The shielding wall 27 is provided to shield a gap formed between the stationary body 10 and the rotating body 20c in a state where the stationary body 10 is joined to the rotating body 20 c. In the rotary joint 4 according to embodiment 4, the 1 st microstrip line 13 and the 2 nd microstrip line 23 are provided on planes facing each other in a state where the rotating body 20c is joined to the stationary body 10. Therefore, there is a case where an RF signal leaks from a gap formed between the opposing planes in the joined state. Therefore, the 1 st microstrip line 13 and the 2 nd microstrip line 23 are surrounded so as to close the gap by the shield wall 27, and the leaked RF signal is shielded (interference is given). On the other hand, the shield is configured to shield interference from RF signals leaking from rotary joints of other joints provided in the robot arm.

As described above, in the rotary joint 4 according to embodiment 4, the shield wall 27 is provided so as to surround the 1 st microstrip line 13 and the 2 nd microstrip line 23 and so as to close the gap formed between the opposing planes in the joined state. As a result, the rotary joint 4 according to embodiment 4 can shield leakage (giving interference) of the RF signal transmitted and received between the 1 st microstrip line 13 and the 2 nd microstrip line 23 and can efficiently shield interference (interfered) of the RF signal from other components, as compared with the rotary joint 1 according to embodiment 1.

In industrial equipment such as a robot arm, it is required to suppress radio wave leakage as much as possible in order to suppress malfunction of other equipment, and in accordance with such a situation, it is significant to suppress leakage (giving disturbance or being disturbed) of radio waves from a rotary joint.

From the disclosure thus described, it will be obvious that the embodiments of the disclosure may be varied in a plurality of ways. Such variations are not to be regarded as a departure from the spirit and scope of the disclosure, and all such modifications as would be obvious to one skilled in the art are intended to be included within the scope of the following claims.