JP6846159B2 - Decoupling device - Google Patents

Description

The present invention relates to a decoupling device capable of connecting a plurality of objects and holding them in a separable manner.

Structures that connect a plurality of objects and hold them in a separable manner are used in various fields, and various structures have been proposed.

As an example, as a connecting structure for connecting a rocket and an artificial satellite, Cited Document 1 proposes a technique for separating by utilizing a shape change of a thermoplastic resin without using a pyrotechnic that has been widely used in the past. There is.

Japanese Unexamined Patent Publication No. 2012-136131

However, when the connected objects are connected under a load, when the connected state is gradually released, an unexpected load is generated on the engaging portion, and the driving portion directly connected to the engaging portion is affected. However, unexpected load may occur and the operation reliability may be lowered, or the transmission of the load for separating the connected objects may be interrupted, which is an unfavorable state in the operation of the separation operation. It happened to be.

The present invention has been made in view of this point.
A decoupling device used to separate navigating objects.
A pair of separation mechanisms that are separably coupled by an engaging member,
A drive unit that generates a driving force for releasing the coupling of the pair of separation mechanisms and transmits the driving force to the engaging member via a drive shaft is provided.
The drive unit is fixed to one of the pair of separation mechanisms .
As is rotated toward the drive shaft at an angle in the released state of the pair of separation mechanism, the locking engagement by the engagement member is characterized that you change toward the released state.

According to the present invention, it is possible to more reliably release the connection in the connection release device.

An exploded perspective view of the disconnection device according to the embodiment of the present invention. An exploded perspective view of a main part of the disconnection device according to the embodiment of the present invention. The separation operation explanatory drawing of the disconnection apparatus in one Embodiment of this invention. Detailed separation operation explanatory view of the disconnection apparatus in one Embodiment of this invention. FIG. 5 is an explanatory diagram of the operating principle of the disconnection device according to the embodiment of the present invention. FIG. 5 is an explanatory diagram of the operating principle of the disconnection device according to the embodiment of the present invention. FIG. 5 is an explanatory diagram of the operating principle of the disconnection device according to the embodiment of the present invention. Another separation operation explanatory view of the disconnection apparatus in one Embodiment of this invention. FIG. 5 is a comparison diagram of the operation of the disconnection device according to the embodiment of the present invention. The whole view of the example which mounted the disconnection device in one Embodiment of this invention. The whole view of the example in which the disconnection device in one Embodiment of this invention was activated. The enlarged view of the main part of the example which mounted the disconnection device in one Embodiment of this invention. The enlarged view of the main part of the example in which the disconnection device in one embodiment of the present invention is operated. Enlarged view of a main part of another example in which the disconnection device according to another embodiment of the present invention is mounted. Enlarged view of a main part of another example in which the disconnection device in another embodiment of the present invention is activated. FIG. 3 is an enlarged view of a main part of another example in which the disconnection device according to another embodiment of the present invention is mounted. Enlarged view of a main part of another example in which the disconnection device in another embodiment of the present invention is activated. Enlarged view of a main part of another example in which the disconnection device according to another embodiment of the present invention is mounted. Enlarged view of a main part of another example in which the disconnection device in another embodiment of the present invention is activated. FIG. 3 is an enlarged view of a main part of another example in which the disconnection device according to another embodiment of the present invention is mounted. Enlarged view of a main part of another example in which the disconnection device in another embodiment of the present invention is activated. The whole view of the navigation body to which the disconnection device in one Embodiment of this invention is applied.

(First Embodiment)
The disconnection device according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 5. As shown in the exploded perspective view of FIG. 1, the connection release device 100 according to the embodiment of the present invention includes a first end member (first intermediate member) 101, a second end member (second intermediate member) 201, and a separation mechanism. It is composed of 301, an unlocking motor M, and a separation assisting mechanism 401.

The first end member 101 and the second end member 201 connect the separation object and the separation mechanism 301, etc., so that the first attachment portion 102 and the second attachment portion 202 for connecting the separation object to one end are connected. Have.

The other end of the first end member 101 is connected to the separation mechanism 301 via the first adjusting member 104 inserted into the guide hole 103, and also via the unlocking motor M and the motor fixing member 106 inserted into the motor hole 105. Link.

The other end of the second end member 201 is connected to the separation mechanism 301 via the second adjusting member 204 inserted into the guide hole 203, and the separation assisting mechanism 401 is connected to the second end member 201 via the support portion fixing member 404. And the second adjusting member 204.

The separation mechanism 301 and the unlocking motor M are fixed by the shaft fixing member 302, and the rotational power generated by the unlocking motor M is transmitted to the separation mechanism 301.

As shown in FIG. 2, the separation mechanism 301 includes a first connecting member 310, a second connecting member 320, a first semicircular fixing member (first semicircular member) 311 serving as a first fixed shaft, and a second fixed shaft. It is composed of a second semicircular fixing member (second semicircular member) 321.

The first connecting member 310 and the second connecting member 320 are each formed in an L shape, and the first connecting member 310 and the second connecting member 320 are configured so that their outer shapes are substantially the same. By doing so, as shown in FIG. 2, when the two are arranged point-symmetrically and brought into contact with each other, no gap is generated. In the following description, the first connecting member 310 and the second connecting member 320 are collectively referred to as a connecting member 1.

The first connecting member 310 and the second connecting member 320 are provided with a first guide pin 312 and a second guide pin 322, respectively. The first guide pin 312 is fixed to the first guide pin hole 312a, and the first guide pin hole 312a is fixed. The 2 guide pin 322 is fixed to the 2nd guide pin hole 322a. In the following description, the first guide pin 312 and the second guide pin 322 are collectively referred to as a guide pin 3.

In a state where the first connecting member 310 and the second connecting member 320 are in contact with each other (hereinafter, connected state), the guide pin 312 is inserted into a guide hole 524 (not shown) provided in the second connecting member. The guide pin 322 is inserted through the guide hole 514 provided in the first connecting member. As a result, the moving direction of the first connecting member 310 and the second connecting member 320 is restricted, and the guide pin 3 can move only in the extending direction. In the following description, the guide hole 514 and the guide hole 524 are collectively referred to as the guide hole 5.

The first connecting member 310 has a first recess 315 on a surface parallel to the guide pin 3 (contact surface F1) among the three surfaces that abut the second connecting member 320 in the connected state. Similarly, the second connecting member 320 has a second recess 325 on a surface parallel to the guide pin 3 (contact surface F1) among the three surfaces that come into contact with the first connecting member 310 in the connected state.

The first recess 315 and the second recess 325 are semicircular, more specifically, a cylindrical shape having a perfect circle as the upper surface and the lower surface, and a surface (dividing surface F2) passing through the center of the perfect circle forming the upper surface and the bottom surface. It is recessed along the split shape (hereinafter referred to as a semi-cylinder for the sake of explanation). That is, in the connected state, the first recess 315 and the second recess 325 face each other in front of each other to form a through hole (circular holding portion) 6. The through hole 6 is a columnar shape having a perfect circular shape. Here, it has been described that the cross-sectional shape of the through hole 6 is a perfect circle in the explanation, but it is difficult to make it an accurate perfect circle in actual processing, and it goes without saying that a hole close to a perfect circle is included. Further, as will be described later, even if a gap is formed between the first recess 315 and the second recess 325, it can be regarded as having a perfect circular shape when both are opposed to each other. .. Of course, if it can be formed as a perfect circle, the degree of adhesion of the connection in the connection principle described below can be increased, which is preferable.

A semi-cylindrical first fixed shaft (first semi-circular fixing member) 311 and a semi-cylindrical second fixed shaft (second semi-circular fixing member) 321 are inserted into the through hole 6. The first fixed shaft 311 and the second fixed shaft 321 have the same shape at the portions facing each other in the through hole 6, and form a cylindrical fixed shaft (cylindrical member) 2. In the present embodiment, the end portion of the first fixed shaft 311 opposite to the side inserted into the first connecting member 310 has an insertion hole 306 (not shown) for fitting with the unlocking motor M. By connecting with the drive shaft Ma of the unlocking motor M, the structure is such that the desired rotational power required for unlocking can be obtained.

The unlocking motor M is connected not only to the first fixed shaft 311 but also to the first end member 101. Therefore, the first connecting member 310 and the first fixed shaft 311 are connected to the unlocking motor M via the first end member 101 and are integrally formed. With this structure, even if the connecting member 1 is displaced with respect to the object to be separated at the time of unlocking, the unlocking motor M is also displaced in the same manner, so that an unexpected load is not generated on the drive shaft Ma and the power transmission is interrupted. There is no such thing.

Further, the cable for supplying electric power to the unlocking motor M has a structure sufficiently long with respect to the displacement, so that an unexpected load is not generated on the cable and the connecting member 1 is connected to the object to be separated. Is displaced, the driving force to the unlocking motor M is transmitted, and the displacement is not constrained.

In the through hole 6, the fixed shaft 2 formed by the first fixed shaft 311 and the second fixed shaft 321 is in sliding contact with each other. That is, the inner surface of the through hole 6 forms a circular inner surface portion, so that the fixed shaft 2 as a cylindrical member slides smoothly.

The driving force from the unlocking motor M is transmitted via the drive shaft Ma, and the fixed shaft 2 is rotationally driven. That is, the drive shaft Ma and the drive shaft Mb are rotated by the rotational driving force generated by the unlocking motor M, and then the through hole 306 connected so as to be rotatable in conjunction with the drive shaft Mb is rotated and penetrated. The first fixed shaft 311 in which the hole 306 is formed and the second fixed shaft 321 loaded from the first fixed shaft 311 can rotate integrally in the through hole 6 along the circumferential direction of the through hole 6. Is supported by.

The first fixed shaft 311 and the second fixed shaft 321 have a cylindrical shape (semi-cylindrical shape) in order to provide a structure for restricting the movement of the fixed shaft 2 in the extending direction when the fixed shaft 2 is rotationally driven in the through hole 6. ), Each has a first regulation hole 316 and a second regulation hole 326.

The first connecting member 310 is provided with a first elongated hole 316a extending in a direction in which the guide pin 3 extends so as to face the first regulating hole 316 of the first fixed shaft 311. By fitting the first regulating member 313 into the first regulating hole 316 through the 316a, the movement of the second fixed shaft 321 in the direction in which the fixed shaft 2 extends is restricted to a predetermined range (regulation). are doing. In the present embodiment, the width of the first slot 316a (the length in the direction in which the fixed shaft 2 extends) and the diameter of the first regulating member 313 are substantially the same, and the first fixed shaft 311 is the fixed shaft. 2 does not move in the extending direction.

Further, the first regulating member 313 regulates that the first fixed shaft 311 is separated from the first connecting member 310 when a separation operation described later acts on the connecting member 1. As an example, the first regulation hole 316 is composed of a screw and the first regulation member 313 is composed of a screw hole. If the diameter of the head shape of the screw is larger than the width of the first slot 316a, the first connection is made. It is possible to regulate the separation of the first regulating member 313 from the member 310.

Further, the first regulating member 313 regulates the rotation angle of the first fixed shaft 311 by contacting the end surface of the guide pin 3 of the first elongated hole 316a in the extending direction.

Similarly, the second connecting member 320 is provided with a second elongated hole 326a extending in the extending direction of the guide pin 3 so as to face the second regulation hole 326 of the second fixed shaft 321. By fitting the second regulating member 323 into the second regulating hole 326 through the two elongated holes 326a, the movement of the second fixed shaft 321 in the direction in which the fixed shaft 2 extends is restricted to a predetermined range. (Regulated). In the present embodiment, the width of the second slot 326a (the length in the direction in which the fixed shaft 2 extends) and the diameter of the second regulating member 323 are substantially the same, and the first fixed shaft 321 is the fixed shaft. 2 does not move in the extending direction.

Further, the second regulating member 323 regulates that the second fixed shaft 321 is separated from the second connecting member 320 when the separating operation described later acts on the connecting member 1. As an example, the second regulation hole 326 is composed of a screw and the second regulation member 323 is composed of a screw hole. If the diameter of the head shape of the screw is larger than the width of the second elongated hole 326a, the second connection is made. It is possible to regulate the separation of the second regulating member 323 from the member 320.

Further, the second regulating member 323 regulates the rotation angle of the second fixed shaft 321 by contacting the end surface of the guide pin 3 of the second elongated hole 326a in the extending direction.

The object to which the separation mechanism 301 configured in this way is connected is the outer surface of the first connecting member 310 where the guide hole 312a is provided, and is provided adjacent to the position where the first guide pin 312 is inserted. The first connecting portion 318 (shown) and the second connecting portion 328 provided on the outer surface of the second connecting member 320 where the guide hole 322a is provided and adjacent to the position where the second guide pin 322 is inserted. By being fixed, the connection is made via the disconnection device 100. In addition, the connection can be released by performing the separation operation described later.

SUS630-H900, which is a high-strength material, is a high-strength material because stress due to an external force in the separation direction, which will be described later, is concentrated at the contact points between the connecting member 1 and the fixed shaft 2 and the connecting member 1 and the other guide pin 3.
Is preferable. It is also preferable to divide each component into a plurality of parts and apply a high-strength material only to the contact points.

Further, from the viewpoint of preventing the strength from being lowered due to corrosion due to aging, SUS630-H900, which is a kind of stainless steel which is a corrosion resistant material, is preferable.

In the surface state of each member, sliding occurs between the members when the separation operation described later acts, so it is necessary to form a surface state or the like having a desired friction coefficient. In particular, by reducing the friction coefficient of the sliding portion, the output of the unlocking motor M for obtaining the desired separation operation can be reduced, so that the surface roughness can be reduced and the molybdenum disulfide coating (MIL) can be reduced. -L-23398) or DLC (Diamond-Like Carbon) coating is preferably applied.

FIG. 3 shows an explanatory diagram of a separation operation (separation by counterclockwise rotation) of the disconnection device according to the embodiment of the present invention. The front view of the disconnection device 100 is shown on the left side of the figure, and the cross-sectional view of the disconnection device 100 is shown on the right side of the drawing.

t1 to t4 indicate each step in connection or separation, and each step will be described step by step below.

Step t1 shows the connection state of the connection release device 100 according to the present embodiment. In step t1, both the first fixed shaft 311 and the second fixed shaft 321 on the fixed shaft 2 are the first connecting member 310 and the second fixed shaft 321. It is located across the second connecting member 320. More specifically, as shown in step t1, the fixed shaft is released from the released state in which the divided surface F2 of the fixed shaft 2 is flush with the contact surface F1 of the connecting member 1 as shown in step t2. 2 is rotated clockwise (CW) by the first predetermined angle (initial angle) θ1.

When the fixed shaft 2 is rotated in the counterclockwise (CCW) direction in FIG. 3 by the unlocking motor M, the first fixed shaft 311 and the second fixed shaft 321 gradually escape from the other connecting member 1. Will go. When the rotation is continued, the state of step t2 is reached. In the present embodiment, an example in which the fixed shaft 2 is rotated by using the unlocking motor M is shown, but the present invention is not limited to this, and for example, the fixed shaft 2 is twisted while being held by an electromagnetic clutch. It also includes a type in which the fixed shaft 2 is rotated by the restoring force of the torsion spring by urging with a spring and releasing the electromagnetic clutch.

When the step t2 is reached, the first fixed shaft 311 exists only in the first connecting member 310, and the second fixed shaft 321 exists only in the second connecting member 320.

At this time, as shown in FIG. 1, in the second connecting member 320, the first connecting member 310 and the second connecting member 320 pass through the second adjusting member 204, the first spring supporting member 402a, and the second spring supporting member 402b. It is connected to a tension spring 403 urged in the separating direction. Further, since the restoring force of the object to be separated is also generated in the same direction, the first connecting member 310 and the second connecting member 320 slide while being guided by the guide pin 3, and their relative positions are opened. ..

In step t3, the first connecting member 310 and the second connecting member 320 slide while being guided by the guide pin 3 to open their relative positions. At the time of step t3, the guide pin 3 comes out of the guide hole 5, and the connection of the separation object via the connection release device 100 is completely separated.

When the connecting member 1 is urged to be separated only by the restoring force of the separation target, the separation target is opened by opening the relative positions of the first connecting member 310 and the second connecting member 320. There is a possibility that the restoring force of the present invention is reduced, the guide pin 3 disappears before it comes out of the guide hole 5, the separation is not completed, and the separation operation of the present invention cannot be properly operated.

On the other hand, in the uncoupling device according to the present embodiment, the restoring force of the tension spring 403 is reduced by opening the relative positions of the first connecting member 310 and the second connecting member 320, but the guide pin 3 is a guide hole. By arranging the tension spring 403 having a displacement amount equal to or greater than the distance from 5 to release, the urging force in the direction in which the first connecting member 310 and the second connecting member 320 are separated from each other is applied regardless of the restoring force of the object to be separated. It can exert and properly operate the separation operation.

The tension spring 403 is provided apart from the second end member 201 by the support portion fixing member 404 so that the restoring force of the tension spring 403 acts in the extending direction of the guide pin 3. More specifically, the tension spring 403 is arranged on the extension of the second adjusting member 204, and as shown in FIG. 2, the second connecting portion 328 to which the second adjusting member 204 is connected is the second guide pin hole 322a. It is installed as close as possible to. The second connecting portion 328 and the second guide pin hole 322a may be made to coincide with each other, and in that case, the second guide pin 322 and the second adjusting member 204 may be integrally formed.

In step t4, the engagement is released, and the first connecting member 310 and the second connecting member 320 are separated from each other.

In the separation operation, the direction in which the first connecting member 310 and the second connecting member 320 separate and move is regulated by the first guide pin 312 and the second guide pin 322, and the guide pin 3 has at least up to step t3. Move in the extending direction. By restricting the moving direction of the connecting member 1 by the guide pin 3, the movement of the connecting member 1 in the direction orthogonal to the extending direction of the guide pin can be regulated, and the separation operation of the present invention can be appropriately operated.

In the connection release device according to the present embodiment, by rotating the fixed shaft 2 in the CCW direction to release the engagement, the first connection state is changed from the connection state in step t1 to the release state in step t2. The state of close contact between the connecting member 310 and the second connecting member 320 can be slightly loosened. The principle will be explained below.

For the sake of explanation, it is assumed that an external force in the direction of separation is applied to the connecting member 1 by the object to be separated. That is, the first connecting member 310 is pulled to the left side in FIG. 3 by the external force of the object connected to the first connecting portion 318, and the second connecting member 320 is pulled to the left side in FIG. 3 by the external force of the object connected to the second connecting portion 328. It is in a state of being pulled to the right.

In that case, in the state of step t1, the first fixed shaft 311 receives a force in the left direction in FIG. 3 from the first connecting member 310. At that time, the first connecting member 310 is connected to the first fixed shaft 311 by the adjusting gap S formed between the first guide pin 312 and the second guide hole 524 in the radial direction of the first guide pin 312. It receives a force in the direction of being pulled upward while sliding on the surface, and moves slightly to the left while moving upward by the amount of the adjustment gap S.

As a result, the first connecting member 310 can move slightly to the left with respect to the second connecting member 320 before transitioning to step t2, as the fixed shaft 2 advances in the CCW direction (counterclockwise). This becomes remarkable because the deviation between the first recess 315 and the second recess 325 becomes large. Therefore, the connected state of the first connecting member 310 and the second connecting member 320 can be gradually loosened with the rotation of the fixed shaft 2 before moving to the state of step t2, and the impact when the connection is released can be reduced. Can be reduced.

In the above description, it is assumed that an external force is applied, but the same applies even when no external force is applied, and the connected state of the first connecting member 310 and the second connecting member 320 is changed before the transition to step t2. It can be loosened.

In order to make the above explanation easier to understand, FIG. 4 shows a diagram in which the adjustment gap S is largely represented. The separation operation proceeds in the order of steps T1 to T5, and specific description thereof will be described with reference to FIGS. 5 to 9 below. Note that steps T1 and T5 correspond to steps t1 and t2 (or t3) in FIG. 3, respectively.

FIG. 5 shows the state of step T1 of FIG. In this state, when tension due to an external force does not act on the connecting member 1, an adjustment gap S is provided between the guide pin 3 and the guide hole 5. In the state of FIG. 4, the sum of the gap s1 and the gap s2 formed on the side of the guide pin is the adjustment gap S.

FIG. 6 shows a state in which tension due to an external force acts on the connecting member 1 in the same state as in FIG. 5, which corresponds to step T2 in FIG. In this state, the fixed shaft 2 slides on the split surface F2 due to tension.

When the first connecting member 310 moves upward by S in FIG. 6, the guide pin 312 and the guide hole 524 come into contact with each other and the slide stops. The amount of movement L in the reference plane X direction at this time is L = S / tan θ, where θ is the angle formed by the reference plane X and the contact surface Y.

As can be seen from the above equation for obtaining the movement amount L, the relationship between the first predetermined angle θ1 and the movement amount L is arbitrarily determined by setting the dimension of S to an appropriate value when designing the guide pin 3 and the guide hole 5. be able to. When the movement amount L is increased to some extent, the centers of the first connecting portion 318 and the second connecting portion 328 are deviated from each other. Therefore, the separation target to be connected to the first connecting portion 318 and the second connecting portion 328. When an external force acts due to the above, the state shown in FIG. 6, that is, the state in which the first connecting member 310 and the second connecting member 320 move up and down, respectively, and the guide pin 3 comes into contact with the outer surface of the guide hole 5. The mounting position of the first connecting portion 318 and the second connecting portion 328 in the direction perpendicular to the reference surface X may be set so that the centers of the first connecting portion 318 and the second connecting portion are aligned with each other.

When the rotation of the fixed shaft 2 is advanced by the unlocking motor M or the like, the movement amount L gradually increases as the angle θ decreases. The state is shown in step T3 in FIG. Here, even if the rotation speed is constant, the movement amount L does not increase linearly. That is, as can be seen from the above equation for obtaining the movement amount L, when the angle θ is 90 degrees or less and relatively large, the change in the movement amount L is small with respect to the change in the angle θ, and the impact on the disconnection device 100 is applied. Will also be small. Further, it can be seen from the equation for obtaining L that the movement amount L suddenly diverges to infinity as the angle θ decreases and the angle θ approaches 0.

Actually, when L reaches a predetermined size, the guide pin 3 is separated from the guide hole 5, so that the regulation of the first connecting member 310 and the second connecting member 320 is released and separated. However, depending on how the parameters such as the rotational momentum of the unlocking motor M are swung, the guide pin 3 becomes the guide hole 5 after the tip of the fixed shaft 2 in the rotational direction comes into contact with the surface forming the contact surface F1 of the connecting member 1. The connecting member 1 may be separated from the connecting member 1. In the present embodiment, the time change amount of L can be controlled by controlling the rotation speed of the unlocking motor M.

That is, in the state shown in FIG. 7 (step T4 in FIG. 4), the guide pin 3 is separated from the guide hole 5 so that the connection between the first connecting member 310 and the second connecting member 320 is released. The length of the guide pin 3 may be set, or the connection may be released at a position where the reference surface X and the contact surface Y coincide with each other (step T5 in FIG. 4).

That is, to summarize the explanations so far, step T1 in FIG. 4 is a connected state corresponding to t1 in FIG. 3, and when the rotation of the fixed shaft 2 is advanced, after the start of the separation operation shown in steps T2 and T3 in FIG. After the transition state, the state of step T5 in FIG. 4, which is the state of disconnection, is reached. Step T5 in FIG. 4 corresponds to t2 or t3 in FIG. Note that steps t3 and t4 in FIG. 3 show a separated state when a force in the direction of pulling the first connecting member 310 and the second connecting member 320 apart is applied by an external force after the release state is reached.

Here, a case where the first predetermined angle θ1 is changed will be described. When the first predetermined angle θ1 is reduced, the torque required to rotate the fixed shaft 2 by the driving force of the unlocking motor M can be reduced when the separation operation is started from the connected state. That is, a small unlocking motor M can be used, and the disconnection device 100 or the entire device can be miniaturized.

In the above embodiment, the first predetermined angle θ1 is set to about 30 degrees so that the device can be driven with a relatively small drive torque while maintaining a certain tension in the connected state. We are trying to reduce the size of the.

FIG. 8 shows an explanatory diagram of another separation operation (clockwise separation) of the disconnection device according to the embodiment of the present invention. The front view of the disconnection device 100 is shown on the left side of the figure, and the cross-sectional view of the disconnection device 100 is shown on the right side of the drawing. Since the basic separation operation method is the same as the separation operation described above, details are omitted and only different parts will be described.

Step t'1 shows the connection state of the connection release device according to the present embodiment, and in step t'1, both the first fixed shaft 311 and the second fixed shaft 321 on the fixed shaft 2 are first connected. It is located across the member 310 and the second connecting member 320. More specifically, from the state where the divided surface F2 of the fixed shaft 2 is flush with the contact surface F1 of the connecting member 1 as in step t'2, the fixed shaft 2 is counterclockwise as shown in step t'1. It is in a state of being rotated by a second predetermined angle (initial angle) θ'1 in the clockwise (CCW) direction.

When the fixed shaft 2 is rotated in the clockwise (CW) direction in FIG. 8 by the unlocking motor M, the first fixed shaft 311 and the second fixed shaft 321 gradually escape from the other connecting member 1. Will go. When the rotation is continued, the state of step t'2 is reached. The rotation of the fixed shaft 2 does not necessarily have to be performed by the unlocking motor M. For example, the restoring force of the torsion spring by urging the fixed shaft 2 with the torsion spring while holding it by the electromagnetic clutch and releasing the electromagnetic clutch. May be done by.

When step t'2 is reached, the first fixed shaft 311 exists only in the first connecting member 310, the second fixed shaft 321 exists only in the second connecting member 320, and the connecting member 1 is separated. It will be possible.

By rotating the fixed shaft 2 in the CW direction to disengage the engagement, the first connecting member 310 and the second connecting member 320 are connected to each other during the transition from step t'1 to step t'2. The first connecting member 310 and the second connecting member 320 can be kept in close contact with each other, and when the step t'3 is reached, the first connecting member 310 and the second connecting member 320 are separated more rapidly than the above-mentioned counterclockwise separation operation. Can be done. The principle will be explained below.

For the sake of explanation, it is assumed that an external force in the direction of separation is applied to the connecting member 1 by the object to be separated. That is, the first connecting member 310 is pulled to the left side in FIG. 8 by the external force of the object connected to the first connecting portion 318, and the second connecting member 320 is pulled to the left side in FIG. 8 by the external force of the object connected to the second connecting portion 328. It is in a state of being pulled to the right.

In that case, in the state of step t'1, the first fixed shaft 311 receives the leftward force in FIG. 8 from the first connecting member 310. At that time, the first fixed shaft 311 is in direct contact with the second connecting member 320 and receives the rightward force in FIG. 8 from the second connecting member 320. Even if the adjustment gap S is formed between the guide pin 3 and the guide hole 5, the relative position with respect to the second connecting member 320 changes only by the amount equal to or less than the adjustment gap S.

As a result, the first connecting member 310 does not move to the left side with respect to the second connecting member 320 until the transition to step t'2, and the first connecting member 310 does not move to the left side with respect to the second connecting member 320 until the transition to the state of step t'2. And the second connecting member 320 can be maintained in a connected state, and the connection can be released relatively rapidly by reaching step t'2.

That is, the connection release device of the present embodiment is used in the state immediately before reaching step t'2, and the connection is released immediately after the connection release operation is started by slightly rotating in the CW direction. (The rise time of the disconnection operation can be shortened). Therefore, unlike the first predetermined angle θ1 which has a certain size to ensure reliable connection, the second predetermined angle θ'1 in the connected state is set to an angle at which the connection can be released by rotating the device a little. By using it, it is possible to instantly release the connection when it is required to release the connection suddenly. Naturally, the second predetermined angle θ'2 may be equal to the first predetermined angle θ1, and it does not prevent the setting from being larger than the first predetermined angle θ1.

Here, when the disconnection release operation is started, it is released to the electromagnetic clutch at the time when the drive command for the release operation for the unlocking motor M is output or in order to release the restoring force of the torsion spring in order to rotate the fixed shaft 2. It means the time when the command is output.

FIG. 9 shows a comparison of the tension applied to the connecting member 1 in the case of performing the above-mentioned counterclockwise separation (separation in the CCW direction) and the case of performing the clockwise separation (separation in the CW direction). It is a conceptual diagram. As with the change in the amount of movement L with respect to the angle θ described above, the tension does not actually decrease linearly, but in FIG. 9, it is expressed linearly for the sake of explanation.

As described above, the tension in the case of performing the separation by counterclockwise, which is shown by the solid line in FIG. 9, is the angle θ of the dividing surface (contact surface) F2 between the first fixed shaft 311 and the second fixed shaft 321. It decreases as it gets smaller. On the other hand, the tension in the case of performing the separation in the clockwise direction, which is shown by the broken line in FIG. 9, is the angle of the dividing surface (contact surface) F2 between the first fixed shaft 311 and the second fixed shaft 321 as described above. When θ'approaches 0, it momentarily becomes 0.

On the other hand, the impact applied to the connecting member 1 and the like when the connection is released can be made smaller in the case of performing the separation by counterclockwise rotation.

In this way, by realizing a structure in which one disconnection device has a plurality of disconnection methods, it is possible to select a disconnection method according to the intended use and purpose of the device, and the versatility of the disconnection device. Can be enhanced.

Here, as an example of a device to which the disconnection device according to the present embodiment is applied, an example provided in a separation device for a space navigation body such as a rocket or a satellite will be shown. FIG. 18 shows an example in which the disconnection device according to the present embodiment is applied as a separation device between a fairing on which a satellite or the like is mounted and a rocket. According to this configuration, the impact generated when disconnecting the fairing and the rocket can be suppressed as compared with the one separated by using pyrotechnics, and at the same time, the separation operation can be performed more reliably. be able to. Further, the same effect can be obtained when the connection release device according to the present embodiment is applied between the upper stage member and the lower stage member of the rocket, which is preferable. The specific structure will be described in detail below. 10 and 11 are overall views showing the separation device according to the present embodiment. By performing the separation operation of the disconnection device 1100, the Maruman band 1600 is separated to separate the satellite and the upper stage member of the rocket, and the upper stage member of the rocket and the lower stage member of the rocket. In the following description, of the two members held by the separation mechanism 1301, the upper side is collectively referred to as the upper member 1701, and the lower side is collectively referred to as the lower member 1702.

FIG. 10 shows the interstage joint 1700 of the rocket, in which the satellite and the upper member of the rocket and the upper member of the rocket and the lower member of the rocket are brought into contact with each other and fixed by the Maruman band 1600.

The Maruman band 1600 is formed by connecting a plurality of clamps 1602 to the band 1601, and the disconnection device 1100 or the end clamp 1800 of the present embodiment is connected to the end portion. A plurality of disconnection devices 1100 can be arranged for the purpose of redundancy, and a plurality of end clamps 1800 can be arranged in consideration of the behavior of the Maruman band 1600 at the time of adjusting the band tension and separating, which will be described later.

When the Maruman band 1600 is fixed, the disconnection device 1100 and the end clamp 1800 pull the band 1601 in the circumferential direction of the interstage joint 1700 of the rocket so that the band 1601 closes. And the clamp 1602 is urged toward the center of the interstage joint 1700 of the rocket, and the upper member 1701 and the lower member 1702 are connected.

The band 1601 is fixed in a state of being urged in the circumferential direction, and as shown in FIG. 11, the restoring force acts in the direction in which the disconnection device 1100 separates when the connection release device 1100 is activated. .. That is, the restoring force acts in the direction in which the diameter of the band 1601 expands.

12 and 13 show enlarged views of the disconnection device 1100 according to the present embodiment. The first connecting member 1310 is fixed to the first end member 1101 by the first adjusting member 1104 connected to the first connecting portion 1102. Similarly, the second connecting member 1320 is fixed to the second end member 1201 by the second adjusting member 1204 connected to the second connecting portion 1202. The first end member 1101 and the second end member 1201 are each connected to the Maruman band 1600.

As shown in FIG. 12, the unlocking motor 1M is connected to the first end member 1101, and the drive shaft 1Ma of the unlocking motor is connected to the first fixed shaft 1311 and is in contact with the second fixed shaft. It can be rotated together with 1321, and as described above, separation by rotating in the CW direction and separation by rotating in the CCW direction are possible.

As described above, by integrally connecting the first end member 1101, the unlocking motor 1M, and the first fixed shaft 1311, an unexpected displacement occurs in the Maruman band 1600 due to the restoring force of the band 1601 at the time of unlocking. However, since the member is also displaced in the same manner, the power is not interrupted during unlocking, and the unlocking can be performed more reliably.

As shown in FIG. 13, when the unlocking motor 1M is operated, the first fixed shaft 1311 and the second fixed shaft 1321 rotate, and the separation surface of the first fixed shaft 1311 and the second fixed shaft 1321 and the first connecting member When the separation surfaces of the 1310 and the second connecting member 1320 coincide with each other, the restoring force of the band 1601 and the restoring force of the tension spring 1403 act on the second connecting member 1320 via the second adjusting member 1204, and the second connecting member 1320 And the first connecting member 1310 are separated.

At this time, the separation mechanism 1301 of the disconnection device 1100 is restricted by the restoring force of the band 1601 and is restricted by the interstage joint 1700 of the rocket. There is a possibility that the restoring force disappears before the connecting member 1320 is detached, and the connecting member 1320 cannot be separated.

On the other hand, since the tension spring 1403 is not restricted by the interstage joint 1700 of the rocket, the restoring force can be adjusted so that the first connecting member 1310 can be displaced until the second connecting member 1320 is disengaged, so that the tension spring 1403 can be separated more reliably. can do.

When the separation operation is performed, the impact is determined by the force for tightening the band 1601 and the time required for releasing the tightened force by the disconnection device 1100. In the past, when the joint was cut with a pyrotechnic, the impact was large because the time to release the tightened force was momentary, but in this embodiment, the connected state can be gradually released. , It is possible to reduce the impact.

(Second Embodiment)
As another example of the device to which the disconnection device according to the embodiment of the present invention is applied, an example in which the unlocking motor is arranged in the direction orthogonal to the axis of the step joint is shown. This embodiment is effective when there is no space in the axial direction and there is a space in the axial direction orthogonal to the space for arranging the unlocking motor. In particular, in a space navigation body, application to a stage between a rocket and an artificial satellite arranged inside a fairing is preferable.

14 and 15 are enlarged views of the disconnection device of the present embodiment. Along with the arrangement of the unlocking motor 2M in the axial direction, the uncoupling device 2100 is arranged so that the first fixed shaft 2311 (not shown) connected to the unlocking motor 2M is also arranged in the axial direction. (The arrangement is rotated by 90 ° from the first embodiment.)

As shown in FIG. 14, in the first end member 2101, the motor holes 2105 (not shown) are arranged in the axial orthogonal direction as the connection release device 2100 is arranged in the axial orthogonal direction, and the unlocking motor 2M is arranged. Arranged in the direction orthogonal to the axis. According to this arrangement, the separation mechanism 1301, that is, the first adjusting member 2104 and the second adjusting member 2204 can be brought close to the outer peripheral surface of the Maruman band 2600. Since the fastening force from the Maruman band 2600 acts in the axial direction of the first adjusting member 2104 and the second adjusting member 2204, the first end member 2101 and the second end member 2201 attached to the Maruman band 2600 are separated. The load applied to the object can be made uniform (stress concentration can be reduced), and damage to each part can be prevented.

The separation operation is the same as that of the first embodiment. As shown in FIG. 15, when the unlocking motor 2M operates, the first fixed shaft 2311 (not shown) connected to the unlocking motor 2M rotates and is in contact with the first fixed shaft 2311. 2 The fixed shaft 2321 also rotates together.

When the separation surface of the first fixed shaft 2311 and the second fixed shaft 2321 reaches the separation surface of the first connecting member 2310 and the second connecting member 2320, the restoring force of the band 2601 and the restoring force of the tension spring 2403 cause the second connecting member. The 2320 is separated from the first connecting member 2310, and the disconnecting device 2100 is separated.

As described above, by integrally connecting the first end member 2101, the motor 2M, and the first fixed shaft 2311, even if an unexpected displacement occurs in the Maruman band 2600 due to the restoring force of the band 2601 at the time of unlocking. Since the member is also displaced in the same manner, the power is not interrupted during unlocking, and the unlocking can be performed more reliably.

According to the present embodiment, particularly in a space navigation body, a disconnection device for connecting rocket stages and the like by arranging an unlocking motor 2M behind the space navigation body such as a rocket or a satellite in the traveling direction. It is possible to reduce the protrusions in the direction orthogonal to the axis of the rocket and reduce the air resistance during flight.

(Third Embodiment)
As another example of the device to which the disconnection device according to the embodiment of the present invention is applied, an example in which the unlocking motor M is arranged in the tangential direction on the outside of the step joint is shown. This embodiment is effective when there is no space for arranging the unlocking motor in the axial direction and the axial orthogonal direction. In particular, in a space navigation body, if a disconnection device is installed to connect rocket stages or the like, it becomes a protrusion in the direction orthogonal to the axis, air resistance during flight increases, and rocket performance deteriorates. Therefore, the present embodiment capable of reducing the protrusion in the direction orthogonal to the axis is suitable.

16 and 17 are enlarged views of the disconnection device of the present embodiment. The unlocking motor 3M is arranged below the first end member 3101 in the tangential direction on the outside of the step joint, that is, in the same direction as the axis of the first adjusting member 3104 (parallel), and the first end member 3101. It is connected to the.

As shown in FIG. 16, since the axes of the unlocking motor 3M and the first fixing member 3311 are orthogonal to each other, they cannot be directly connected as in the above embodiment, and the first gear 3116 and the second gear 3117 are connected. Through, the unlocking motor 3M is indirectly connected to the first fixing member 3311. The second gear 3117 is connected to and fixed to the first fixing member 3311.

Here, the torque of the unlocking motor 3M can be amplified by interposing the first gear 3116 and the second gear 3117 with different numbers of teeth, so that the unlocking motor 3M can be miniaturized. is there.

Further, since the type and angle change amount of the first gear 3116 and the second gear 3117 are arbitrary, the position of the motor can be arbitrarily changed.

The separation operation is the same as that of the above embodiment. As shown in FIG. 17, when the unlocking motor 3M operates, the first gear 3116, the second gear 3117, and the first fixed shaft 3311 connected to the unlocking motor 3M rotate in this order and are first fixed. The second fixed shaft 3321 that is in contact with the shaft 3311 also rotates together.

When the separation surface of the first fixed shaft 3311 and the second fixed shaft 3321 reaches the separation surface of the first connecting member 3310 and the second connecting member 3320, the restoring force of the band 3601 and the restoring force of the tension spring 3403 cause the second connecting member. The 3320 is separated from the first connecting member 3311, and the disconnecting device 3100 is separated.

As described above, by integrally connecting the first end member 3101, the motor 3M, and the first fixed shaft 3311, even if an unexpected displacement occurs in the Maruman band 3600 due to the restoring force of the band 3601 at the time of unlocking. Since the member is also displaced in the same manner, the power is not interrupted during unlocking, and the unlocking can be performed more reliably.

According to the present embodiment, particularly in a space navigation body, a disconnection device for connecting rocket stages and the like by arranging an unlocking motor 2M behind the space navigation body such as a rocket or a satellite in the traveling direction. It is possible to reduce the protrusions in the direction orthogonal to the axis of the rocket and reduce the air resistance during flight. Further, since the separation mechanism 3301 in the present embodiment performs the separation operation by sliding, a certain amount of space is provided in the separation direction (movement direction of the first guide pin 3312 and the second guide pin 3322). On the other hand, by arranging the longitudinal direction of the unlocking motor 3M along the separation direction, the unlocking motor 3M is provided as far behind the separation mechanism 3301 as possible with respect to the traveling direction of the space navigation body, thereby increasing air resistance. In addition, the amount of protrusion of the unlocking motor 3M toward the lower member can be suppressed, and it is possible to prevent contact with the object to be separated when the object to be separated is separated.

(Fourth Embodiment)
As another example of the device to which the disconnection device according to the embodiment of the present invention is applied, an example in which a compression spring for separation is provided on the second end member will be shown. This embodiment is effective when the space for arranging the spring for urging in the separation direction is limited. In particular, in a space navigation body, if a disconnection device is mounted to connect rocket stages and the like, it becomes a protrusion in the direction orthogonal to the axis, air resistance during flight increases, and rocket performance deteriorates. Therefore, the present embodiment capable of reducing the protrusion in the direction orthogonal to the axis is suitable.

18 and 19 are enlarged views of the disconnection device of the present embodiment. In the present embodiment, by compressing the spring for urging in the separation direction, the tension spring 1403 and the like used in the first embodiment can be abolished, and the protrusion in the direction orthogonal to the axis of the rocket is eliminated. Can be done.

As shown in FIG. 18, the compression spring 4130 is arranged between the second end member 4201 and the second adjusting member 4204, and is held in an axially urged state of the second adjusting member 4204 before separation. ing. Specifically, one end of the compression spring 4130 is in contact with the head shape of the screw used as the second adjusting member 4204 or a washer provided adjacent to the head shape, and the other end is not shown. The two-ended member 4201 is held in a compressed state by abutting on the abutting portion provided in the guide hole 4203.

The separation operation is the same as that of the first embodiment. As shown in FIG. 19, when the unlocking motor 4M is operated, the first fixed shaft 4311 connected to the unlocking motor 4M is rotated, and the second fixed shaft 4311 is in contact with the first fixed shaft 4311. 4321 also rotates together.

When the separation surface of the first fixed shaft 4311 and the second fixed shaft 4321 reaches the separation surface of the first connecting member 4310 and the second connecting member 4320, the restoring force of the band 4601 and the restoring force of the compression spring 4130 cause the second connecting member. The 4320 is separated from the first connecting member 4310, and the disconnecting device 4100 is separated.

As described above, the initial setting such as the restoring force of the compression spring 4130 can be arbitrarily set because it is not restricted by the external parts, and the second connecting member 4320 is surely separated from the first connecting member 4310. By setting the restoring force and the amount of movement that can be performed, the separation operation is not interrupted during the separation operation, and the lock can be reliably unlocked.

According to the present embodiment, particularly in a space navigation body, a disconnection device for connecting rocket stages and the like by arranging an unlocking motor 4M behind the space navigation body such as a rocket or a satellite in the traveling direction. It is possible to reduce the protrusions in the direction orthogonal to the axis of the rocket and reduce the air resistance during flight.

(Fifth Embodiment)
As another example of the device to which the disconnection device according to the embodiment of the present invention is applied, an example in which the first compression spring 5130 and the second compression spring 5131 for urging in the separation direction are arranged inside the separation mechanism. Shown.

When a plurality of decoupling devices are arranged with respect to an object to be separated, it is difficult to separate each decoupling device at exactly the same time, and when one decoupling device is separated, the other decoupling devices are connected. It may be in a state. Therefore, when a urged spring is arranged between the second end member 5201 and the second adjusting member 5204 as in the first embodiment and the second embodiment, it is necessary to separate the separation mechanism 5301 by the spring. When the load required to pull the second end member 5204 toward the separation mechanism 5301 is smaller than the load, the second end member 5204 does not move in the separation direction, and the second end member 5204 moves. It is conceivable that the separation mechanism may move in the direction of 5301 and the separation may not be completed.

Therefore, in the present embodiment, by arranging the spring for urging the separation mechanism 5301 in the separation direction, the separation mechanism 5301 is more reliably attached in the separation direction even when the separation of the disconnection devices is not simultaneous. It was supposed to be urged.

Therefore, in particular, the application of the present embodiment to a space navigation body in which a plurality of disconnection devices are arranged for redundancy is suitable. However, it does not prevent only one disconnection device 5100 of the present embodiment from being attached to the object to be separated, and even in that case, the same effect as that of the other embodiments can be obtained.

20 and 21 are enlarged views of the disconnection device of the present embodiment. As shown in FIG. 20, the first compression spring 5130 and the second compression spring 5131 are arranged between the first connecting member 5310 and the second connecting member 5320, and before the separation, the first adjusting member 5104 and the second adjusting member 5104 and the second adjusting member are arranged. The member 5204 is held in a state of being urged in the axial direction.

The separation operation is the same as that of the first embodiment. As shown in FIG. 21, when the unlocking motor 5M is operated, the first fixed shaft 5311 connected to the unlocking motor 5M is rotated, and the second fixed shaft 5311 is in contact with the first fixed shaft 5311. 5321 also rotates together.

When the separation surface of the first fixed shaft 5311 and the second fixed shaft 5321 reaches the separation surface of the first connecting member 5311 and the second connecting member 5321, the restoring force of the band 5601 and the first compression spring 5130 and the second compression spring 5131 The second connecting member 5320 is separated from the first connecting member 5310 by the restoring force of the above, and the connection releasing device 5100 is separated.

As described above, the initial setting such as the restoring force of the compression spring can be arbitrarily set because it is not restricted by the external parts, and the second connecting member 5320 is surely separated from the first connecting member 5310. By setting the restoring force and the amount of movement that can be performed, the separation operation is not interrupted during the separation operation, and the lock can be reliably unlocked.

In the present embodiment, the first adjusting member 5104 is arranged at the center of the first connecting member 5310 with respect to the extending direction of the fixed shaft 2, and the first adjusting member 5104 in the extending direction of the fixed shaft 2 Guide pins 5312 and compression springs 5130 are provided on both sides so as to be symmetrically arranged. Similarly, the second component 5204 is centrally located in the second connecting member 5320 with respect to the extending direction of the fixed shaft 2. The guide pin 5322 and the compression spring 5131 are symmetrically arranged on both sides of the second adjusting member 5204 in the extending direction of the fixed shaft 2.

With this configuration, when the connecting member 1 is urged by the compression springs 5130 and 5131, the sliding loss in the separation operation by the guide pin 3 and the compression springs 5130 and 5131 can be reduced, and the separation operation can be efficiently assisted. it can. Further, at the contact position of the compression springs 5130 and 5131 on the other side connecting member with which the compression springs 5130 and 5131 are in contact, the urging direction by the compression spring is set to the axial direction of the guide pin 3 after the start of the separation operation. It is preferable to provide a tangential structure. The contact structure is formed by a concave groove or the like into which the compression springs 5130 and 5131 are inserted.

Further, when a plurality of disconnection devices 5100 according to the present embodiment are arranged on the object to be separated, the Maruman band 5600 may be unexpectedly displaced when one disconnection device is separated, but one disconnection is performed. The first compression spring 5130 and the second compression spring 5131 do not receive the urging force from the band 5600 with respect to the other disengagement devices 5100 in the connected state due to the separation of the device 5100. Is always arranged between the first connecting member 5310 and the second connecting member 5320 to exert an urging force, so that the separation operation of the first connecting member 5310 and the second connecting member 5320 can be promoted.

As described above, in order to separate the second connecting members 1320 and 4320 from the first connecting members 1310 and 4310 by the urging force of the tension spring 1403 and the compression spring 4130 as the urging means, the Maruman bands 1600 and 4600 are rocketed. When attaching to a separation object such as an interstage joint, the urging means is extended or compressed as much as possible, and the head shape of the second connecting member 1320, 4320 is the guide hole 1203 of the second end member 1201, 4201. It is preferable to fasten the Maruman bands 1600 and 4600 in a state where they are in contact with the 4203. By doing so, the urging force (elastic force) of the urging means can be effectively applied between the connecting members, which is preferable. The same applies to the case where the compression springs 5130 and 5131 are used, and it is preferable that the compression springs 5130 and 5131 are arranged in the connecting member in a compressed state as much as possible.

Here, the outer surface of the first mounting portion of the first end member will be described in detail. The outer surface of the first mounting portion is a flat surface, and the Maruman band is mounted so that the inner peripheral surface abuts on the flat surface. The first mounting portion is formed so as to include an end portion of the first end member opposite to the side on which the separation mechanism is provided, and the outer surface of the first mounting portion is the end portion and the center of the Maruman band. It is perpendicular to the straight line passing through. That is, when the objects to be separated are connected to the end of the first mounting portion on the inner peripheral surface (inner peripheral circle) of the Maruman band formed so as to form a perfect circle except at the position where it abuts on the first mounting portion. The outer surface of the first connecting portion is formed so as to coincide with the tangent line at the intersection of.

According to this configuration, the direction of the load exerted on the Maruman band by the first end member or the like can be made tangential by the restoring force of the Maruman band, and the load exerted on the separated object or the like can be made uniform (stress concentration is reduced). It is possible to prevent damage to each part. Similarly, the load is made uniform in the second end member and the second connecting portion.

FIG. 22 shows an example in which the disconnection device according to the present invention is applied as a separation device between a fairing on which a satellite or the like is mounted and a rocket. FIG. 22A shows a rocket body configured in three stages and a rocket on which a load such as a satellite SAT is mounted inside a fairing PLF provided above the rocket body. A separation device 6100 using the disconnection device according to the present invention is provided between each stage of the rocket and the fairing PLF. Further, a separation device 6100 using the disconnection device according to the present invention is also provided between the satellite joint PAF and the satellite SAT. For the separation device 6100, any form of the disconnection device in each of the embodiments described so far may be used.

As shown in FIGS. 22B to 22E, the disconnection device according to the present invention is used in the separation of the rocket stages B1, B2, B3 and the fairing PLF and the separation of the satellite SAT and the satellite joint PAF. As a result, the separation operation can be reliably performed while reducing the impact on the disconnection device. In particular, in the separation of the satellite SAT and the satellite joint PAF, it is desired to suppress the impact as much as possible, and the application of the disconnection device according to the present invention is very suitable.

Although the disconnection device of the present invention has been described in detail above, the present invention is not limited to the above-described embodiment, and various improvements and changes can be made without departing from the gist of the present invention.

In the above embodiment, an example in which one disconnection device is arranged with respect to the Maruman band has been described. For example, two disconnection devices may be arranged at opposite positions in the circumferential shape of the Maruman band. In that case, the effect of the present invention can be enhanced. That is, even if two disconnection devices are instructed to release at the same time, it is difficult to drive them exactly at the same time, and when one of the disconnection devices is disconnected, the restoring force of the Maruman band to the other suddenly increases. It may be reduced and the connection may not be released as it is, but if the present invention is applied, the connection of the connection release device can be released even after the restoring force of the Maruman band is reduced, which is preferable. The present invention can be more preferably applied even when three or more disconnection devices are provided.

For example, in the above embodiment, the guide pin 3 has a circular cross section, that is, a substantially cylindrical shape. However, in reality, the guide pin 3 has a rectangular parallelepiped shape and the guide hole 5 has an elliptical shape. May be given.

(Appendix 1)
The present invention includes an engaging portion that engages the first member and the second member.
A drive unit for disengaging the engagement portion is provided.
The engaging portion includes a cylindrical member composed of a pair of divided semicircular members and a cylindrical member.
It is provided with a pair of connecting members that abut along the outer peripheral surface of the cylindrical member to form a circular holding portion that holds the cylindrical member.
The circular holding portion is formed by making the semicircular portion of one connecting member and the semicircular portion of the other connecting member face each other and making the inner peripheral surfaces of the semicircular portions continuous. Has a circular inner surface that is in sliding contact with the outer peripheral surface of the
The cylindrical member is fixed to a first semicircle that forms a semicircle along the circular inner surface portion with reference to a release position where the contact surface of the pair of connecting members and the divided surface of the cylindrical member are flush with each other. It has a shaft and a second semicircular fixed shaft that forms the other semicircle and forms a hole for connecting to the drive unit.
The drive unit includes an unlocking drive unit and a separation drive unit.
The unlocking drive unit has a drive shaft for connecting to one of the cylindrical members and a housing for connecting to the first member.
The separation drive unit has a spring support member that connects to the second member and a tension spring for separating one of the pair of connecting members after release.
When the first member and the second member are engaged, the cylindrical member is attached to the pair of connecting members in a state where the contact surface of the pair of connecting members and the divided surface of the cylindrical member are not flush with each other. Is maintained in the inserted state,
When the engagement between the first member and the second member is disengaged, the drive shaft and the second semicircular fixed shaft connected to the drive shaft rotate to contact the contact surface of the pair of connecting members. When the split surface of the cylindrical member is flush with each other, the first member and the second member are not constrained with respect to the tangential direction of the split surface, and the tension spring contracts to cause one of the pair of connecting members. Moves in the tangential direction of the dividing surface, and the engagement between the first member and the second member is released.

A cylindrical member composed of a pair of divided semicircular members,
It is provided with a pair of connecting members that abut along the outer peripheral surface of the cylindrical member to form a circular holding portion that holds the cylindrical member.
The circular holding portion is formed by making the semicircular portion of one connecting member and the semicircular portion of the other connecting member face each other and making the inner peripheral surfaces of the semicircular portions continuous. Has a circular inner surface that is in sliding contact with the outer peripheral surface of the
The cylindrical member is formed in either a clockwise direction or a counterclockwise direction along the circular inner surface portion with reference to a position where the contact surface of the pair of connecting members and the divided surface of the cylindrical member are flush with each other. A disconnection device characterized by being rotatably configured.

It has a regulating part that limits the rotation angle of the cylindrical member.
The circular holding portion is a connection release device characterized in that the cylindrical member can be held in any direction in which the cylindrical member is in contact with the circular inner surface portion.

The regulating portion is provided on a normal line passing through the cylindrical member of the contact surface of the connecting member in the connecting member.

The pair of connecting members are connected by stopping the cylindrical member at a position rotated counterclockwise with respect to a position where the contact surface of the pair of connecting members and the divided surface of the cylindrical member are flush with each other. Hold the state,
A disconnection device characterized in that the connection state is released by rotating the cylindrical member clockwise.

The connected state of the pair of connecting members is obtained by stopping the cylindrical member at a position rotated clockwise with respect to a position where the contact surface of the pair of connecting members and the divided surface of the cylindrical member are flush with each other. Is held,
A connection release device characterized in that the connection state is released by rotating the cylindrical member counterclockwise.

Even when the cylindrical member is rotated clockwise or counterclockwise with respect to a position where the contact surface of the pair of connecting members and the divided surface of the cylindrical member are flush with each other, the cylinder member is stopped. A disconnection device characterized in that the connected state of a pair of connecting members can be maintained.

A connection release device, characterized in that the connection state of the pair of connection members is released by rotating the cylindrical member in a direction in which the pair of connection members move when they are separated.

(Appendix 2)
If the force for separating the disconnection device depends on the restoring force of the separation object, the separation operation may not be completed if the restoration force of the separation object is lost in the middle of the separation operation.

On the other hand, the disconnection device according to the present invention is
A decoupling device used to separate navigating objects.
A pair of separable separation mechanisms and
A drive unit that generates a driving force to release the coupling of the separation mechanism is provided.
A disconnection device comprising an urging means for exerting an urging force on the separation mechanism in a direction in which the separation mechanism is separated.

According to this configuration, even if the restoring force of the object to be separated disappears or decreases at the time of separation, the connection can be released by the urging force of the urging means.

The separation mechanism
A pair of connecting members that are separably connected,
One side is attached to the connecting member, and the other side is composed of an intermediate member attached to the object to be separated.
The drive unit is attached to the first intermediate member among the intermediate members.
The urging means is a disconnection device, which is attached to a second intermediate member among the intermediate members.

The connecting member
Slidingly engages with the intermediate member by the engaging member,
The urging means is a disconnection device provided on the engaging member.

The urging means is a disconnection device provided inside the intermediate member.

The pair of separation mechanisms have a first connecting member and a second connecting member arranged so as to straddle the separating surfaces facing each other in the direction in which the separation mechanism is separated.
The urging means is an elastic member that is provided so as to straddle the first connecting member and the second connecting member on the separating surface and exerts an urging force in the direction in which the separating mechanism is separated. Decoupling device.

The urging means
A disconnection device, characterized in that the separation mechanism is provided at both ends in a direction orthogonal to the direction of separation.

The urging means is arranged on one of the pair of separation mechanisms.
A disconnection device capable of performing a separation operation depending on the urging force of the urging means, regardless of the external force acting on the separation mechanism.

1 Connecting member 310, 1310, 2310, 3310 First connecting member 320, 1320, 2320, 3320 Second connecting member 2 Fixed shaft 311, 1311, 2311, 3311 First fixed shaft 321, 1321, 2321, 3321 Second fixed shaft 3 Guide pin 5 Guide hole 401 Separation assist mechanism M, 1M, 2M, 3M Unlocking motor

Claims (10)

A decoupling device used to separate navigating objects.
A pair of separation mechanisms that are separably coupled by an engaging member,
A drive unit that generates a driving force for releasing the coupling of the pair of separation mechanisms and transmits the driving force to the engaging member via a drive shaft is provided.
The drive unit is fixed to one of the pair of separation mechanisms .
As is rotated toward the drive shaft at an angle in the released state of the pair of separation mechanisms, uncoupling device the locking engagement by the engagement member is characterized that you change toward the released state. The pair of separation mechanisms
A pair of connecting members that are separably connected,
One side is attached to the pair of connecting members, and the other side is composed of an intermediate member attached to the object to be separated.
The disconnection device according to claim 1, wherein the drive unit is attached to the intermediate member. The disconnection device according to claim 2, wherein the drive unit is attached to a fixing member provided integrally with the intermediate member. Wherein the pair of separation mechanisms, uncoupling device according to claim 1, characterized in that it comprises a biasing means in any one of 3 to exert urging force in the direction of isolated minute. A decoupling device attached to a spacecraft
The disconnection device according to any one of claims 1 to 4, wherein the drive unit is arranged behind the pair of separation mechanisms in the traveling direction of the space navigation body. The drive unit is a motor
The disconnection device according to claim 5, wherein the longitudinal direction of the motor is arranged along the disconnection release direction in the pair of separation mechanisms. The pair of connecting members include, as the engaging member, a cylindrical member composed of a pair of divided semicircular members.
It has a circular holding portion that abuts along the outer peripheral surface of the cylindrical member and holds the cylindrical member.
The circular holding portion is formed by making the semicircular portion of one of the pair of connecting members and the semicircular portion of the other so as to face each other and making the inner peripheral surfaces of the semicircular portions continuous. uncoupling device according to claim 2 or 3 outer circumference is characterized Rukoto that having a circular inner surface in sliding contact with the. The pair is stopped by stopping the cylindrical member at a position rotated in one of the circumferential directions of the cylindrical member with reference to a position where the contact surface of the pair of connecting members and the divided surface of the cylindrical member are flush with each other. connected state of the coupling member is held in,
The disconnection device according to claim 7, wherein the connected state is released by rotating the cylindrical member in a direction opposite to one of the above. 7. Or 8 according to claim 7, further comprising a regulating member provided on the outer peripheral surface of the cylindrical member, which regulates the rotation angle of the cylindrical member with respect to the circular holding portion and prevents the cylindrical member from being separated from the circular holding portion. The decoupling device described. The drive unit is a motor
One of the motor and the pair of connecting members is directly or indirectly connected and integrated.
Even if the separation mechanism is displaced due to an external force or the like during the release of the coupling due to the rotation of the motor, the release operation without displacement of the relative position between the motor and one of the pair of connecting members connected to the motor. The disconnection device according to claim 2 or 3, wherein the device can be continued.

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