CN220822086U - Rotary assembling and disassembling structure of split device - Google Patents

Abstract

The utility model discloses a rotary assembly and disassembly structure of a split device, which belongs to the assembly and disassembly structure of the split device, and the existing assembly and disassembly structure is not easy to assemble and disassemble each component part according to the requirement.

Description

Rotary assembling and disassembling structure of split device

Technical Field

The utility model belongs to an assembly and disassembly structure of a split device, and particularly relates to a rotary assembly and disassembly structure of a split device, which is used for assembling different components into different forms according to requirements.

Background

The hand-held electric appliance with the split structure, such as split ironing equipment, can enable the ironing device to work together with or separate from the cable according to requirements, can place the ironing device on the base to charge or supplement water, and can also take the ironing device off the base to work independently. The use requirement is dependent on an assembly and disassembly structure, and the existing assembly and disassembly structure is not easy to assemble and disassemble each component part according to the requirement.

Disclosure of utility model

The utility model aims to solve the technical problems and provide a rotary assembling and disassembling structure of a split device, which is used for a user to assemble the split device into different structural forms for use according to the needs, thereby providing convenience for the user and relieving the holding burden.

In order to achieve the above object, the rotational assembly and disassembly structure of the split device of the present utility model includes:

a first assembly including a first assembly portion, a rotation portion, and an actuation member, the first assembly portion being provided with a first locking structure, the actuation member being moved by the rotation portion;

A second assembly adapted to be assembled and disassembled with the first assembly portion, provided with a first locking member configured to be transposed between a locking position and an unlocking position by the elastic action of the elastic element and the thrust action from the actuating member against the elastic force of the elastic element;

When the second assembly body and the first assembly part are in an assembled state, the movement of the actuating member promotes the first locking piece to be in any one of the following states:

Splitting state: the first locking piece is positioned at the unlocking position and is not locked with the first locking structure,

Double connection state: the first locking piece is located at the locking position and is locked with the first locking structure.

Accordingly, the first assembly body and the second assembly body are detached or connected to meet the requirement by rotating the rotating part on the first assembly body, and the operation is easy.

In order to simplify the structure, the first locking piece is a transverse bolt, and the first locking structure is a first pin hole; when in a split state: the first locking piece is positioned at the unlocking position and is separated from the first pin hole; in the doubly-linked state: the first locking piece is located at the locking position and inserted into the first pin hole. In particular, the actuating member is a vertical rod member, and a transversely protruding actuating protrusion is arranged on the rod member; the actuating member is configured to move vertically, and the actuating projection exerts a lateral thrust force on the first lock when the actuating member moves vertically. Moreover, in order to smoothly fit, the actuating protrusion is fitted with the end of the first locking member by a slope.

In order to avoid the first locking piece from rotating and being out of position, the first locking piece is guaranteed to be matched with the actuating component, and the first locking piece is arranged on the second assembly body through the rotation stopping structure.

In order to reduce the volume of the assembly, the first assembly part and the second assembly body are both cylindrical, and the first assembly part is sleeved outside the second assembly body when the second assembly body and the first assembly part are in an assembled state.

In order to facilitate the use, the first assembly is configured on the handheld moving part, and the second assembly is configured on the base. The first assembly can thus be placed on or removed from the second assembly.

In order to guide the first assembly to be assembled with the second assembly accurately, the first assembly is assembled with the second assembly through the guide structure.

In one embodiment, the rotational assembly disassembly structure further comprises a third assembly comprising a third assembly portion adapted to be assembled and disassembled with the first assembly or/and the second assembly. Accordingly, the combination of the first assembly and the second assembly can be assembled with the third assembly or disassembled from the third assembly.

One structure of assembling or disassembling the combination of the first assembly and the second assembly with the third assembly is as follows:

the third assembling part is provided with a third locking structure;

The second assembly is provided with a third locking piece, and the third locking piece is used for shifting between a locking position and an unlocking position by virtue of the elastic action of the elastic element and the thrust action from the actuating component, which overcomes the elastic force of the elastic element;

when the second assembly is in an assembled state with the first assembly portion and the third assembly portion, movement of the actuating member urges the first locking member and the third locking member to be in any one of:

Splitting state: the first locking piece is positioned at the unlocking position and is not locked with the first locking structure, the third locking piece is positioned at the unlocking position and is not locked with the third locking structure,

Double connection state: the first locking piece is positioned at the locking position and is locked with the first locking structure, the third locking piece is positioned at the unlocking position and is not locked with the third locking structure,

Three states: the first locking piece is located at the locking position and is locked with the first locking structure, and the third locking piece is located at the locking position and is locked with the third locking structure.

Accordingly, the first assembly, the second assembly and the third assembly can be in a required separated state or combined state by rotating the rotating part on the first assembly, and the operation is easy.

In order to facilitate operation, when the rotating part rotates in one direction, the first locking piece and the third locking piece change from the split state to the triple state through the double-connection state, and when the rotating part rotates in the other direction, the first locking piece and the third locking piece change from the triple state to the split state through the double-connection state.

In order to simplify the structure, the first locking piece and the third locking piece are both transverse bolts, the first locking structure is a first pin hole, and the third locking structure is a third pin hole;

When in a split state: the first locking piece is positioned at the unlocking position and is separated from the first pin hole, and the third locking piece is separated from the third pin hole;

In the doubly-linked state: the first locking piece is positioned at the locking position and inserted into the first pin hole, and the third locking piece is separated from the third pin hole;

In the three-connection state: the first locking piece is located at the locking position and is inserted into the first pin hole, and the third locking piece is inserted into the third pin hole.

In particular, the actuating member is a vertical rod member, and a transversely protruding actuating protrusion is arranged on the rod member; the actuating member is configured to move vertically, and the actuating protrusion exerts a lateral thrust on the first locking piece or simultaneously on the first locking piece and the third locking piece when the actuating member moves vertically. Moreover, for smooth engagement, the actuating projections are engaged with the end portions of the first locking member and the third locking member by inclined surfaces.

In order to avoid the first locking piece from rotating and being out of position, the first locking piece and the third locking piece are arranged on the second assembly body through a rotation stopping structure, and the first locking piece and the third locking piece are kept to be matched with the actuating component.

In order to reduce the volume of being assembled together, first equipment portion, second equipment body and third equipment portion all are the tube-shape, and first equipment portion and third equipment portion cover are outside the second equipment body when second equipment body and first equipment portion and third equipment portion are in the assembled state. In particular, the second assembly abuts the first assembly portion and the third assembly portion when the second assembly body is in an assembled state with the first assembly portion and the third assembly portion and shields the second assembly body within the first assembly portion and the third assembly portion.

Another structure in which the combination of the first assembly and the second assembly is assembled with or disassembled from the third assembly is as follows: the first assembly body or/and the second assembly body are/is locked and assembled with the third assembly body through an interlocking structure. This interlocking structure is another locking structure that is independent of the assembly and disassembly achieved by operating the rotating portion.

In order to facilitate the use, the first assembly is configured on the handheld moving part, the second assembly is configured on the coupling part, and the third assembly is configured on the base. It is thus possible to place the combination of the first assembly and the second assembly on the third assembly or to remove it from the third assembly or to place the second assembly on the third assembly and then to place the first assembly on the second assembly from the second assembly.

In order to guide the second assembly to be assembled with the third assembly accurately, the first assembly or/and the second assembly are assembled with the third assembly through the guide structure.

For compact structure, the rotating part is a rotating sleeve.

In order to accurately control the movement of the brake member, the first assembly includes a guide, the actuating member is in lifting engagement with the guide, and the rotating portion is in threaded engagement with the actuating member.

According to the utility model, at least two assemblies are arranged, the rotating part and the actuating member are arranged on the first assembly, the actuating member is driven to move by rotating the rotating part on the first assembly, the locking piece on the assembly is driven to be locked or unlocked with the locking structure on the first assembly by the actuating member, or the locking piece on the second assembly is driven to be locked or unlocked with the locking structure on the first assembly and the third assembly by the actuating member, so that the required combination or disassembly state is achieved, and the operation is easy.

Drawings

FIG. 1 is a schematic view of the split device of embodiment 1 of the present utility model assembled together;

FIG. 2 is a schematic view of the split device of FIG. 1 from another perspective;

FIG. 3 is a schematic illustration of the split device of FIGS. 1-2 shown in a split view;

FIG. 4 is a schematic view of the split device of FIG. 3 from another perspective;

FIG. 5 is an exploded view of the first assembly of FIGS. 3-4;

FIG. 6 is a schematic diagram of another view of the structure of FIG. 5;

FIG. 7 is an exploded view of the second assembly of FIGS. 3-4;

FIG. 8 is a schematic diagram of another view of the structure of FIG. 7;

FIG. 9 is a schematic front view of the split device of FIGS. 1-2 in a triple-connected state;

FIG. 10 is a cross-sectional view taken along A-A of FIG. 9;

FIG. 11 is a B-B cross-sectional view of FIG. 10;

FIG. 12 is a schematic diagram of the structure of FIG. 11 transitioning to a doubly-linked state;

FIG. 13 is a schematic diagram of the structure of FIG. 11 being transformed to a disassembled state;

Fig. 14 is a schematic view of the third locking member of embodiment 1 configured on the second assembly body through the rotation stopping structure;

Fig. 15 is a schematic diagram showing a split device in which a first assembly and a second assembly are assembled and disassembled with a third assembly according to embodiment 2;

The reference numerals in the figures illustrate:

100 first assembly: 101 first assembly part, 102 rotation part, 103 actuation member, 104 guide, 105 first locking structure, 106 actuation protrusion, 107 guide hole;

200 second assembly: 201 first locking piece, 202 third locking piece, 203 elastic element, 204 inclined plane, 205 rib, 206 groove;

300 third assembly: 301 third assembling portion, 302 third locking structure

410 Hand-held mobile part, 420 coupling part, 430 base, 431 toggle.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present utility model more apparent, the technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The terms "comprises" and "comprising" and any variations thereof, in the description and claims, are intended to cover a non-exclusive inclusion, such as a method or article, that comprises a list of features does not necessarily limit the features to those expressly listed, but may include other features not expressly listed that may be included in such method or article.

In the description of the present utility model, it should be understood that the technical features defined by the terms "first", "second", "third", etc. having sequential concepts are merely for the purpose of clearly describing the defined technical features, so that the defined technical features can be clearly distinguished from other technical features, and do not represent such naming when actually implemented, and thus should not be construed as limiting the present utility model.

The present utility model will be described in detail with reference to specific embodiments and drawings.

Example 1

As shown in fig. 1 to 4 and fig. 9 to 13, the rotary assembling and disassembling structure of the split device comprises: the first assembly 100, the second assembly 200, and the third assembly 300.

The first assembly 100 is shown in fig. 5-6, and includes a first assembly portion 101, a rotation portion 102, an actuating member 103, and a guide 104. The first assembly portion 101 is cylindrical and is provided with a first locking structure 105, and the first locking structure 105 is a first pin hole provided in an inner wall of the first assembly portion. The rotating portion 102 is a rotating sleeve. The guide 104 is fixed and provided with a vertical guide hole 107. The actuating member 103 is a vertical rod and is inserted into a guide hole 107 of the guide 104 to be in lifting fit with the guide. The turning part 102 is screw-fitted with the actuating member 103, so that the actuating member can be moved by the turning part, i.e. the turning of the turning part can be converted into a vertical movement (up-down movement) of the actuating member. The lever is provided with a laterally protruding actuating projection 106.

As shown in fig. 7 to 8, the second assembly 200 has a cylindrical shape, and an outer diameter corresponding to an inner diameter of the first assembly portion 101. The second assembly 200 is adapted to be assembled and disassembled with the first assembly portion 101, and is configured with a first locking member 201 and a third locking member 202, which are both configured to be transposed between a locking position and an unlocking position by the elastic force of the elastic element 203 and the thrust force from the actuating member 103 against the elastic force of the elastic element. The first locking member 201 and the third locking member 202 are both transverse pins. The ends of the first and third latches mate with the actuation protrusion 106 via the ramp 204. The first lock member 201 and the third lock member 202 are arranged in the second assembly by a rotation stopping structure. The rotation stopping structure, as shown in fig. 14, includes a rib 205 and a groove 206 separately provided on the second assembly 200 and the third locking member 202, and in the assembled state, the rib 205 is located in the groove 206 to stop the rotation of the third locking member. The first locking member 201 is disposed in the second assembly by the same rotation-stopping structure.

The third assembly 300 includes a third assembly portion 301 adapted to be assembled and disassembled with the second assembly 200, the third assembly portion 301 having a cylindrical shape, an inner diameter of the third assembly portion 301 being equivalent to an outer diameter of the second assembly portion 200. The third assembling portion 301 is provided with a third locking structure 302, and the third locking structure 302 is a third pin hole provided on an inner wall of the third assembling portion.

When the second assembly 200 is in an assembled state with the first and third assemblies 101 and 301, movement of the actuating member 103 urges the first and third latches 201 and 202 to be in either of:

the split state shown in fig. 13: the first locking piece 201 is located at the unlocking position and is separated from the first pin hole, and the first locking piece 201 is located at the unlocking position and is not locked with the first locking structure 105; the third locking member 202 is disengaged from the third pin aperture, and the third locking member 202 is in the unlocked position and is not locked with the third locking structure 302. At this time, the first assembly, the second assembly and the third assembly are separated from each other, and the first assembly can be taken out separately.

The double connection state shown in fig. 12: the first locking piece 201 is located at the locking position and inserted into the first pin hole, and the first locking piece 201 is located at the locking position and locked with the first locking structure 105; the third locking member 202 is disengaged from the third pin aperture, and the third locking member 202 is in the unlocked position and is not locked with the third locking structure 302. At this time, the first assembly and the second assembly are combined into a combined body, and the combined body is detached from the third assembly, so that the combined body formed by combining the first assembly and the second assembly can be taken from the base.

The tri-connection state shown in fig. 11: the first locking piece 201 is located at the locking position and inserted into the first pin hole, and the first locking piece 201 is located at the locking position and locked with the first locking structure 105; the third locking member 202 is inserted into the third pin hole, and the third locking member 202 is located at the locking position and locked with the third locking structure 302. At this time, the first assembly body, the second assembly body and the third assembly body are assembled into a whole, so that the assembled whole can be moved together by holding the first assembly body or the third assembly body.

When the actuating member 103 moves vertically, the actuating protrusion 106 applies a lateral thrust to the first locking piece 201 as shown in fig. 12 or simultaneously to the first locking piece 201 and the third locking piece 202 as shown in fig. 11, and does not apply a lateral thrust to the first locking piece and the third locking piece as shown in fig. 13.

Since the first assembly 101, the second assembly 200 and the third assembly 301 are all cylindrical, the first assembly 101 and the third assembly 301 are outside the second assembly 200 when the second assembly is assembled with the first assembly and the third assembly. The second assembly is adjacent to the first assembly portion and the third assembly portion when the second assembly is in an assembled state with the first assembly portion and the third assembly portion, and the second assembly is shielded in the first assembly portion and the third assembly portion. In order to maintain the engagement of the actuating member with the first and third locking members, the first assembly and/or the second assembly is/are assembled with the third assembly via a guiding structure, which may be provided like a rotation stopping structure.

Wherein, when the rotation part 102 rotates to one direction, the first locking piece and the third locking piece change from the split state to the triple state through the double-connection state, and when the rotation part rotates to the other direction, the first locking piece and the third locking piece change from the triple state to the split state through the double-connection state.

When actually carried out on a product, the first assembly 100 is disposed on the hand-held moving part, the second assembly 200 is disposed on the coupling part, and the third assembly 300 is disposed on the base. Taking an ironing device as an example, the hand-held moving part is a hand-held ironing device and is used for ironing clothes; the coupling part is an external power supply and is used for being connected to power supply positions such as a wall socket and the like to supply power for the ironing device; the base is used for bearing the handheld ironing device and can be provided with a water tank for supplying water for the handheld ironing device. Thus, when the first assembly, the second assembly, and the third assembly are stacked together, the hand-held ironing appliance, the base, and the base may be powered by the coupling portion.

Example 2

As shown in fig. 15, the split device includes a first assembly 100, a second assembly 200, and a third assembly 300, wherein the first assembly 100 is disposed on a hand-held moving portion 410, the second assembly 200 is disposed on a coupling portion 420, and the third assembly 300 is disposed on a base 430.

The assembly or disassembly of the first assembly 100 and the second assembly 200 with the third assembly 300 is the locking assembly of the first assembly or/and the second assembly with the third assembly via the interlocking structure. This interlocking structure is another locking structure that is independent of assembly and disassembly by operation of the rotating portion, and is illustrated as a snap-in structure and operated by toggle button 431, and in other embodiments may be a pin-in structure operated by a knob. Accordingly, the strength of the interlocking structure may be configured according to the requirements of the specific structure to carry the third assembly by holding the first assembly.

Example 3

In other embodiments, the third assembly 300 and the third lock 202 of embodiment 1 may be omitted. The rotational assembly and disassembly structure of the split device only comprises the first assembly 100 and the second assembly 200. When the second assembly is in an assembled state with the first assembly, movement of the actuating member urges the first latch to be in any of: splitting state: the first locking piece is located the unblock position and with first locking structure not locking, the double-link state: the first locking piece is located at the locking position and is locked with the first locking structure. When the portable electronic device is applied to a specific product, the first assembly body is configured on the handheld moving part, and the second assembly body is configured on the base.

Claims (22)

1. The rotation assembly split structure of components of a whole that can function independently device, characterized by includes:

A first assembly (100) comprising a first assembly part (101), a rotation part (102), an actuating member (103),

The first assembly part is provided with a first locking structure (105), and the actuating member (103) is carried by the rotating part (102) to move;

A second assembly (200) adapted to be assembled and disassembled with the first assembly portion, provided with a first locking piece (201), the first locking piece (201) being configured to be shifted between a locking position and an unlocking position by means of the elastic action of the elastic element (203) and the thrust action from the actuating member (103) against the elastic force of the elastic element;

When the second assembly body and the first assembly part are in an assembled state, the movement of the actuating member promotes the first locking piece to be in any one of the following states:

splitting state: the first locking piece (201) is positioned at the unlocking position and is not locked with the first locking structure,

Double connection state: the first locking piece (201) is located at the locking position and is locked with the first locking structure.

2. The rotational assembly disassembly structure of the split device according to claim 1, characterized in that: the first locking piece (201) is a transverse bolt, and the first locking structure (105) is a first pin hole;

When in a split state: the first locking piece (201) is positioned at the unlocking position and is separated from the first pin hole;

in the doubly-linked state: the first locking piece (201) is located at the locking position and inserted into the first pin hole.

3. The rotational assembly disassembly structure of the split device according to claim 2, characterized in that: the actuating component (103) is a vertical rod piece, and a transversely protruding actuating protrusion (106) is arranged on the rod piece; the actuating member (103) is configured to move vertically, when the actuating member moves vertically, the actuating protrusion (106) exerts a lateral thrust action on the first lock (201).

4. A rotary assembling and disassembling structure of a split device according to claim 3, characterized in that: the actuating projection (106) cooperates with the end of the first locking member (201) via a ramp (204).

5. The rotational assembly disassembly structure of the split device according to claim 2, characterized in that: the first locking member (201) is disposed on the second assembly body by a rotation-stopping structure.

6. The rotational assembly split structure of a split device according to claim 1 or 2, characterized in that: the first assembly part (101) and the second assembly body (200) are both cylindrical, and the first assembly part (101) is sleeved outside the second assembly body (200) when the second assembly body and the first assembly part are in an assembled state.

7. The rotational assembly split structure of a split device according to claim 1 or 2, characterized in that: the first assembly is configured on the handheld moving part, and the second assembly is configured on the base.

8. The rotational assembly split structure of a split device according to claim 1 or 2, characterized in that: the first assembly (100) is assembled with the second assembly (200) via a guide structure.

9. The rotational assembly disassembly structure of the split device according to claim 1, characterized in that: the rotational assembly and disassembly structure further comprises a third assembly (300) comprising a third assembly portion (301) adapted to be assembled and disassembled with the first assembly or/and the second assembly.

10. The rotational assembly disassembly structure of the split device according to claim 9, characterized in that:

The third assembly part is provided with a third locking structure (302);

The second assembly is provided with a third locking piece (202), and the third locking piece (202) is used for shifting between a locking position and an unlocking position by the action of the elastic force of the elastic element (203) and the thrust action from the actuating component, which overcomes the elastic force of the elastic element;

when the second assembly is in an assembled state with the first assembly portion and the third assembly portion, movement of the actuating member urges the first locking member and the third locking member to be in any one of:

Splitting state: the first locking piece (201) is positioned at the unlocking position and is not locked with the first locking structure (105), the third locking piece (202) is positioned at the unlocking position and is not locked with the third locking structure (302),

Double connection state: the first locking piece (201) is positioned at the locking position and locked with the first locking structure (105), the third locking piece (202) is positioned at the unlocking position and unlocked with the third locking structure (302),

Three states: the first locking piece (201) is located at the locking position and is locked with the first locking structure (105), and the third locking piece (202) is located at the locking position and is locked with the third locking structure (302).

11. The rotational assembly disassembly structure of the split device according to claim 10, characterized in that: when the rotating part (102) rotates in one direction, the first locking piece and the third locking piece change from the split state to the triple state through the double-connection state, and when the rotating part (102) rotates in the other direction, the first locking piece and the third locking piece change from the triple state to the split state through the double-connection state.

12. The rotational assembly split structure of a split device according to claim 10 or 11, characterized in that: the first locking piece (201) and the third locking piece (202) are both transverse bolts, the first locking structure (105) is a first pin hole, and the third locking structure (302) is a third pin hole;

When in a split state: the first locking piece (201) is positioned at the unlocking position and is separated from the first pin hole, and the third locking piece (202) is separated from the third pin hole;

In the doubly-linked state: the first locking piece (201) is positioned at the locking position and inserted into the first pin hole, and the third locking piece (202) is separated from the third pin hole;

In the three-connection state: the first locking piece (201) is located at the locking position and is inserted into the first pin hole, and the third locking piece (202) is inserted into the third pin hole.

13. The rotational assembly disassembly structure of the split device according to claim 12, wherein: the actuating component (103) is a vertical rod piece, and a transversely protruding actuating protrusion (106) is arranged on the rod piece; the actuating member (103) is configured to move vertically, when the actuating member moves vertically, the actuating protrusion (106) exerts a lateral thrust action on the first locking piece (201) or simultaneously on the first locking piece (201) and the third locking piece (202).

14. The rotational assembly disassembly structure of the split device according to claim 13, wherein: the actuating projection (106) cooperates with the ends of the first locking member (201) and the third locking member (202) by means of a ramp (204).

15. The rotational assembly disassembly structure of the split device according to claim 12, wherein: the first locking member (201) and the third locking member (202) are arranged on the second assembly (200) by a rotation stopping structure.

16. The rotational assembly split structure of a split device according to claim 10 or 11, characterized in that: the first assembly part (101), the second assembly body (200) and the third assembly part (301) are all cylindrical, and the first assembly part (101) and the third assembly part (301) are sleeved outside the second assembly body (200) when the second assembly body is in an assembled state with the first assembly part and the third assembly part.

17. The rotational assembly disassembly structure of the split device according to claim 16, wherein: the second assembly (200) is adjacent to the first assembly (101) and the third assembly (301) when the second assembly (200) is in an assembled state with the first assembly (101) and the third assembly (301), and the second assembly (200) is shielded within the first assembly and the third assembly.

18. The rotational assembly disassembly structure of the split device according to claim 9, characterized in that: the first assembly (100) or/and the second assembly (200) is/are assembled with the third assembly (300) in a locking way through an interlocking structure.

19. The rotational assembly split structure of a split device according to any one of claims 9-11, 18, characterized in that: the first assembly (100) is disposed on the hand-held moving part, the second assembly (200) is disposed on the coupling part, and the third assembly (300) is disposed on the base.

20. The rotational assembly split structure of a split device according to any one of claims 9-11, 18, characterized in that: the first assembly (100) or/and the second assembly (200) is/are assembled with the third assembly (300) via a guiding structure.

21. The rotational assembly split structure of a split device according to any one of claims 1 to 5, 9 to 11, 18, characterized in that: the rotating part (102) is a rotating sleeve.

22. The rotational assembly split structure of a split device according to any one of claims 1 to 5, 9 to 11, 18, characterized in that: the first assembly (100) comprises a guide (104), an actuating member (103) is in lifting fit with the guide (104), and a rotating part (102) is in threaded fit with the actuating member (103).