KR20230090456A - Apparatus for opening and closing a flow path - Google Patents

Abstract

The present invention relates to a flow path opening and closing device provided at the middle of a flow path or at an end of the flow path, which can block and unblock the flow of a fluid by opening and closing the corresponding flow path. Opening and It is closed, characterized in that it comprises a passage opening and closing portion that rotates in the direction of opening and closing the intermediate conduit member by receiving the rotational force of the intermediate connection portion.
In addition, the passage opening and closing device, when the intermediate connection portion is rotated in the direction of opening the intermediate pipe member and at the same time receives the rotational force of the intermediate connection portion to accumulate elastic force, and an elastic restoring force corresponding to the elastic force is generated, the It characterized in that it further comprises a passage automatic closing drive for transferring the elastic restoring force to the intermediate connection portion so that the intermediate connection portion rotates in a direction to close the intermediate pipe member.
In addition, the passage automatic closing drive unit is characterized in that it can maintain the unwinding progress speed of the spring member within a predetermined cycle range.

Description

Euro switchgear {Apparatus for opening and closing a flow path}

The present invention relates to a flow path opening and closing device, and more particularly, to a flow path opening and closing device provided at the middle or end of a flow path to open and close the flow path to block and unblock the flow of fluid.

Various channel structures are being utilized to transport fluids such as various liquids and various gases from a supply or storage place to a place of use.

In addition, the above-mentioned liquid may include water, oil, and other various liquid components not mentioned above, and similarly, the above-mentioned gas may include various gas components other than those mentioned above.

And, in order to save resources, these fluids need to be supplied to the place of use only when necessary, and for this purpose, various passage opening and closing means are being utilized.

As an example of such flow path opening/closing means, a preceding Korean Patent Registration No. 10-2317266 discloses a three-way shut-off valve for easy opening and closing of flow paths.

In addition, according to the prior literature, the plug rotation operation for changing the flow path and the plug pressing and releasing operation for airtightness can operate independently, so that the plug can be pressed and released with less force, In the shut-off valve, various effects such as minimizing abrasion of the plug seat can be expected.

In this case, after the user manipulates the passage opening/closing means to open the passage to be used, there are frequent cases where the user does not close the passage to be used by manipulating the passage opening/closing means due to negligence.

However, the prior art document does not disclose any means for automatically implementing the closure of the passage without a user's separate manipulation. In this case, if the passage is not closed due to the user's negligence, not only waste of various resources but also gas Various problems such as safety accidents such as explosions may occur.

Korean Registered Patent Publication No. 10-2317266

As part of solving the above problems, an object of the present invention is to provide a passage opening and closing device capable of automatically closing a corresponding passage even if a passage locking operation is not performed due to a user's negligence.

A flow path opening and closing device according to the present invention includes a flow path portion including an intermediate conduit member through which fluid passes, a manipulation unit including a lever member provided on either side of the flow passage portion, an intermediate connection portion that rotates by receiving rotational force of the lever member, and It is characterized in that it includes a passage opening and closing portion that opens and closes the intermediate conduit member through a rotary valve drive, and rotates in a direction to open and close the intermediate conduit member by receiving rotational force of the intermediate connection portion.

In addition, the passage opening and closing device, when the intermediate connection portion is rotated in the direction of opening the intermediate pipe member and at the same time receives the rotational force of the intermediate connection portion to accumulate elastic force, and an elastic restoring force corresponding to the elastic force is generated, the It characterized in that it further comprises a passage automatic closing drive for transferring the elastic restoring force to the intermediate connection portion so that the intermediate connection portion rotates in a direction to close the intermediate pipe member.

In addition, the flow path automatic closing drive unit is provided inside the spring housing while having a spring housing rotatable integrally with the intermediate connection unit and a predetermined spiral structure, and the intermediate connection unit rotates in a direction in which the intermediate pipe member is opened. In this case, the elastic force is accumulated by being compressed by rotating together with the spring housing, and the shape is restored as the elastic restoring force acts, so that a rotational force corresponding to the elastic restoring force is transmitted to the spring housing so that the spring housing is the intermediate channel member. It is characterized in that it includes a mainspring member that rotates in the direction of closing.

In addition, the passage automatic closing drive unit is characterized in that it can maintain the unwinding progress speed of the spring member within a predetermined cycle range.

In addition, the flow path automatic closing drive unit is characterized in that it comprises an escapement wheel part interlocked with the rotation drive of the mainspring housing and an anchor member interfering with the rotation of the escapement wheel part within a predetermined cycle according to the principle of the escapement and anchor. .

According to the flow passage opening and closing device according to the present invention, a spring member to which a kind of spring spring principle is applied may be applied to an intermediate connection portion that performs an opening and closing operation of an intermediate conduit member, which is a flow passage, through a rotational action. When the intermediate connecting part rotates, the mainspring member may also be rotated and wound along with it.

Thereafter, as the spring member is unwound by an elastic restoring force applied to the spring member, the intermediate connecting portion interlocking with the spring member also rotates in the same direction as the spring member. Since the wind-up member is in the opposite direction to the direction in which the wind-up member was previously wound to open the passage, the direction of rotation of the intermediate connection portion accompanying the unwinding action of the wind-up member may correspond to the direction of closing the flow passage.

Accordingly, even if a separate user operation is not performed to close the passage due to negligence in use, the passage is automatically closed by the elastic restoring action of the spring member after a predetermined time has elapsed according to the principle of the spring spring described above. Therefore, through this, an effect of saving resources such as various liquids and gases occurs.

In addition, since the above-described automatic water locking principle works only based on the elastic force of the material, an advantage arises in that a separate power supply for automatic water locking operation is not required.

1 is a perspective view showing a passage opening and closing device according to the present invention.
FIG. 2 is a view based on a state in which the case portion shown in FIG. 1 is removed.
FIG. 3 is a plan view illustrating the passage opening and closing device shown in FIG. 1 .
4 is an exploded perspective view illustrating the passage opening and closing device shown in FIG. 2;
FIG. 5 is a cross-sectional view based on a state viewed from section AA′ shown in FIG. 3 .
FIG. 6 is a cross-sectional view based on a state viewed from the section BB′ shown in FIG. 5 .
7A and 7B are diagrams illustrating a process in which the driven-side intermediate gear unit shown in FIG. 2 rotates.
8 is a view showing a state in which the opening and closing member shown in FIG. 5 is rotated.
FIG. 9 is a view showing a state in which elastic force is applied to the mainspring member shown in FIG. 6 .
10A and 10B are diagrams illustrating a process in which an anchor member is driven based on a state viewed from a section CC′ shown in FIG. 5 .

Prior to the detailed description of the present invention, specific details for carrying out the present invention are included in the following embodiments and drawings, and the same reference numerals described throughout the specification denote the same components.

In addition, singular expressions in this specification will also include plural unless specifically stated in the phrase.

Hereinafter, a flow passage opening and closing device according to the present invention will be described with reference to the drawings.

1 is a perspective view showing a passage opening and closing device according to the present invention, and FIG. 2 is a view based on a state in which the case portion shown in FIG. 1 is removed.

And, Figure 3 is a plan view showing the passage opening and closing device shown in Figure 1.

And, Figure 4 is an exploded perspective view showing the passage opening and closing device shown in Figure 2.

1 to 4, the flow path opening and closing device 1000 according to the present invention includes a case part 100, a flow path part 200, a control unit 300, an intermediate connection part 400, a flow path opening and closing part 500, and a flow path. An automatic closing drive unit 600 may be included.

Also, the case part 100 may include a case body 110 , an inflow opening 120 , and an outflow opening 130 .

The case body 110 may be formed in a kind of cylindrical structure with a hollow inside, and the previously mentioned components of the passage opening and closing device 1000 may be installed thereto.

In addition, the case body 110 may be provided in the middle or at the end of a flow path (not shown) where it is used.

Also, the inlet opening 120 is formed at one end of the case body 110 and can communicate the inside and outside of the case body 110 .

Also, the outflow opening 130 is formed at the other end of the case body 110 and can communicate the inside and outside of the case body 110 .

That is, the case unit 100 may have a kind of hollow tube structure in which both ends are open.

Subsequently, FIG. 5 is a cross-sectional view based on a state viewed from section A-A′ shown in FIG. 3 .

And, FIG. 6 is a cross-sectional view based on a state viewed from the section BB′ shown in FIG. 5 .

Further referring to FIGS. 5 and 6 , the passage part 200 may include a cover member 210 , an intermediate passage member 220 , an outlet housing 230 , and an outlet portion 240 .

The cover member 210 is formed to cover the side of the inlet opening 120, and concave holes 211 may be formed through the concentric side.

At this time, the concave hole 211 may be in communication with a middle or end of a flow path (not shown) where it is used.

Further, the intermediate conduit member 220 extends from the cover member 210 and is provided inside the case part 100 with its longitudinal axis being provided coaxially with the length concentric axis of the case part 100. can

In addition, the intermediate conduit member 220 may be formed as a kind of double pipe structure including an inner pipe member 221 and an outer pipe member 222.

More specifically, the inner tube member 221 may be formed in a structure in which both ends are open while communicating with the inlet hole 211, through which the fluid flows through the inlet opening 120 and the inlet hole 211. ) to enter the inner tube member 221.

In addition, the outer tube member 222 may be formed to surround the inner tube member 221 with an inner circumferential surface spaced apart from the outer circumferential surface of the inner tube member 221 by a predetermined distance.

In addition, the outer tube member 222 has a spring installation groove 223 that communicates the space between the outer tube member 222 and the inner tube member 221 to the outside of the outer tube member 222 along the longitudinal direction. can be formed

In addition, a plurality of spring installation grooves 223 may be formed along the circumferential direction of the outer tube member 222 .

In addition, the outflow housing 230 is provided on the inside of the case unit 100 and is formed of a hollow tube structure with both ends open, and one end of the inner tube structure provided inside the case unit 100 and It can communicate, and through this, the fluid passing through the inner tube member 221 can be introduced into the outlet housing 230.

In addition, the outlet 240 may be installed in a manner passing through the outlet opening 130 and may be formed as a hollow tube structure having both ends communicating with the end of the outlet housing 230 open.

Accordingly, the fluid introduced into the inlet opening 120 can be supplied to the place of use by passing through the concave hole 211, the inner tube member 221 and the outlet housing 230, and finally passing through the outlet 240. there will be

Also, the control unit 300 may include a lever member 310, a lever shaft 320, and a driving gear member 330.

The lever member 310 may be provided outside the case part 100 .

In addition, the lever shaft 320 may be penetrated into the case body 110 in a direction orthogonal to the longitudinal axis of the case body 110, and one end thereof exposed to the outside of the case body 110 may be the lever. Member 310 may be coupled.

And, the driving gear member 330 is coupled to the end of the lever shaft 320 provided inside the case body 110, and has a gear structure in which gear teeth are formed along the rim direction of the lever shaft 320. can be formed

Accordingly, when the lever member 310 rotates, the rotational force at this time is transmitted to the driving gear member 330 via the lever shaft 320, so that the driving gear member 330 is also the same as the lever member 310. It will be able to rotate in either direction.

Also, the intermediate connection unit 400 may include a driving side intermediate gear unit 410 and a driven side intermediate gear unit 420 .

The drive-side intermediate gear unit 410 is provided on the upper side of the drive gear member 330 on the side of the inlet opening 120 from the inside of the case unit 100, and is geared with the drive gear member 330 in a bevel gear manner. A predetermined gear tooth structure may be formed along the rim so as to be combined.

In addition, the axis of rotation of the motor-side intermediate gear unit 410 may be provided coaxially with the longitudinal axis of the case unit 100 .

In addition, the aforementioned intermediate conduit member 220 may pass through the central axis of rotation of the motor-side intermediate gear unit 410, and thus the intermediate conduit member 220 and the motor-side intermediate gear unit 410 are mutually coaxial. can be provided.

And the driven-side intermediate gear unit 420 is provided on the outer surface of the motor-side intermediate gear unit 410 facing the outflow opening 130 side, and a plurality of gears along the rim of the motor-side intermediate gear unit 410. The tooth may be formed in a protruding structure.

In addition, the gear teeth of the driven-side intermediate gear unit 420 may be arranged in parallel with the gear teeth of the driving-side intermediate gear unit 410 .

In addition, each gear tooth of the driven-side intermediate gear unit 420 may be formed in the inner section of the rim of the motor-side intermediate gear unit 410, and through this, the gear teeth of the driven-side intermediate gear unit 410 may be formed in the driven-side intermediate gear unit 410. It can be provided to surround the gear teeth of the gear unit 420 .

That is, it can be understood that the driven-side intermediate gear unit 420 is provided inside the pitch circle of the driven-side intermediate gear unit 410 .

Accordingly, when the motor-side intermediate gear unit 410 engaged with the motor-side intermediate gear unit 410 in a bevel gear manner rotates in response to the rotation of the motor-side intermediate gear unit 410 described above, the driven side installed in the motor-side intermediate gear unit 410 The intermediate gear unit 420 can also rotate in the same direction as the motor-side intermediate gear unit 410 .

At this time, the gear teeth of the driven-side intermediate gear unit 420 may be provided along only a part of the inner circumference of the driven-side intermediate gear unit 410 so that the arranged shape forms an arc rather than a circle.

Subsequently, FIGS. 7A and 7B are diagrams illustrating a rotation process of the driven-side intermediate gear unit illustrated in FIG. 2 , and FIG. 8 is a diagram illustrating a rotated state of the opening/closing member illustrated in FIG. 5 .

Further referring to FIGS. 7A, 7B, and 8 , the passage opening/closing part 500 may include an opening/closing member 510, an opening/closing shaft 520, and a driven gear member 530.

The opening and closing member 510 is provided inside the outflow housing 230 and is formed in a kind of ball structure, and a ball passage 511 opening both ends and hollowing the inside may be formed through.

In addition, the opening and closing member 510 may be provided coaxially with the intermediate conduit member 220, and the ball passage 511 corresponds to the rotation of the opening and closing member 510, the inner tube member 221 and the outlet portion (240) can be interconnected or closed.

In addition, the opening and closing shaft 520 is provided such that its longitudinal axis is orthogonal to the longitudinal axis of the intermediate conduit member 220, and may be coupled through the outlet housing 230.

At this time, one end of the opening/closing shaft 520 provided inside the outlet housing 230 may be coupled to the opening/closing member 510 .

Also, the driven gear member 530 may be coupled to an end of the opening/closing shaft 520 exposed to the outside of the outflow housing 230 .

In this case, the opening/closing member 510, the opening/closing shaft 520, and the driven gear member 530 may be provided to be closer to the outflow opening 130 than the driven-side intermediate gear unit 420.

In addition, the driven gear member 530 may be formed in a gear structure in which gear teeth are formed along the edge direction of the opening/closing shaft 520 .

In addition, the driven gear member 530 may be meshed with the aforementioned driven-side intermediate gear unit 420 in a bevel gear manner.

More specifically, as shown in FIG. 2 to FIG. 7A in order, when the rotation principle of the aforementioned driving side intermediate gear unit 410 is implemented by operating the lever member 310, the driven side intermediate gear unit 420 is also rotated together with it to move toward the driven gear member 530, and eventually the driven-side intermediate gear unit 420 can be engaged with the driven gear member 530 in a bevel gear manner.

Next, as shown in the order of FIGS. 7A to 7B , as the motor side intermediate gear unit 410 continues to rotate in response to the operation of the lever member 310, the driven side engaged with the driven gear member 530 The intermediate gear unit 420 also continuously rotates in the direction of rotation of the motor-side intermediate gear unit 410 and passes the driven gear member 530.

In addition, according to the above-described rotational movement of the driven-side intermediate gear unit 420, the driven gear member 530 rotates through meshing with the driven-side intermediate gear unit 420, and is connected to the driven gear member 530. The opening and closing shaft 520 also rotates together.

Next, as shown in the order of FIG. 5 to FIG. 8, the opening and closing member 510 coupled thereto also rotates in response to the rotation of the above-described opening and closing shaft 520, through which the ball passage 511 moves to the inside. By connecting the pipe member 221 and the outlet 240, the fluid can flow across the case body 110 and be supplied to a place of use.

At this time, the above-described opening and closing member 510 can be interpreted as performing a kind of ball valve drive, but various means for opening and closing the flow path in a rotational manner, such as other disk valves, correspond to the selection of the opening and closing member 510. It can be.

In addition, the number of gear teeth of the driven-side intermediate gear unit 420 may be provided only as necessary to open or close the intermediate pipe member 220 only by meshing with the driven gear member 530 for one cycle.

Next, FIG. 9 is a view showing a state in which elastic force is applied to the mainspring member shown in FIG. 6 .

Further, FIGS. 10A and 10B are diagrams illustrating a process of driving an anchor member based on a state viewed from a section C-C′ shown in FIG. 5 .

9, 10A, and 10B, the flow path automatic closing drive unit 600 includes a spring housing 610, a spring member 620, a spring-side gear unit 630, and an escape-side gear unit ( 640), an escapement wheel 650, and an anchor member 660.

The mainspring housing 610 may be coupled to an upper surface of the motor side intermediate gear unit 410 facing the inflow opening 120 side.

In addition, the mainspring housing 610 may rotate integrally with the motor-side intermediate gear unit 410, and the mainspring housing 610 and the motor-side intermediate gear unit 410 may be coaxially provided with each other.

In addition, the above-described intermediate conduit member 220 may pass through the central axis of the longitudinal axis of the mainspring housing 610, through which the intermediate conduit member 220 such as the outer tube member 222 and the spring installation groove 223 The outer portion of ) may be provided inside the mainspring housing 610.

In addition, a spring fixing part 611 having an arc shape may protrude from the inside of the mainspring housing 610 in a circumferential direction, and the spring fixing part 611 may be formed to protrude from the inner wall surface of the mainspring housing 610 at a predetermined distance. may be separated by more than a distance.

In addition, the mainspring member 620 may have a spiral wound shape as a whole and be made of a material having a predetermined elastic force, like a kind of mainspring spring.

In addition, the rotational axis of the spiral structure of the spring member 620 may be provided coaxially with the rotational axis of the spring housing 610 .

In addition, the mainspring member 620 may be firmly installed inside the mainspring housing 610 by the intermediate conduit member 220 and the spring fixing part 611 .

More specifically, one end of the mainspring member 620, which is the central side of the spring spring structure, is bent between the outer tube member 222 and the inner tube member 221 through any one of the spring installation grooves 223 described above. After passing through, at least a part of the end side portion may be exposed to the outside of the outer tube member 222 through the other spring installation groove 223.

Thus, the length of one end side of the spring member 620 can be bent while forming an arc corresponding to the difference in radius between the outer tube member 222 and the inner tube member 221, and also such a spring member ( 620) spatially interferes between the outer tube member 222 and the inner tube member 221, and through this spatial interference action, one end of the spring member 620 is firmly attached to the intermediate tube member 220. It can be combined and fixed in position.

In addition, the end portion of one end side of the outer tube member 620 exposed from the inside to the outside of the outer tube member 222 is bent along the outer circumferential surface of the outer tube member 222 to serve as a kind of hook, Through this hooking structure, one end of the spring member 620 can be prevented from sliding along the space between the outer tube member 222 and the inner tube member 221 .

Also, the distal end of the spring member 620 may be bent and cover the above-described spring fixing part 611, and through this, a kind of hooking structure may be provided on the distal side of the spring member 620 as well.

In addition, referring to FIGS. 6 and 9, when the mainspring housing 610 rotates in response to the rotation of the motor-side gear member, the helical length of the mainspring member 620 is compressed as if the mainspring is wound. It is deformed, and through this, the spring member 620 can accumulate elastic force due to compression.

At this time, as shown in the order of FIGS. 6 to 9, the process of rotating by compressing the spiral structure of the mainspring member 620 is the same as the process shown in the order of FIGS. 5 to 8 described above, the intermediate conduit member 220 can proceed simultaneously with the process of opening.

That is, when the intermediate connector 400 rotates in the direction of opening the intermediate conduit member 220, the spring housing 610 also rotates in the same direction at the same time, and is provided coaxially with the spring housing 610 and spring The spiral structure of the spring member 620, both ends of which are constrained by the installation groove 223 and the spring fixing part 611, can also be rotated and compressed in a manner that is wound in the same direction.

Conversely, when no external force acts on the lever member 310, etc., as shown in the order of FIGS. 9 to 6, an elastic restoring force corresponding to the action of the above-described elastic force is generated in the spring member 620. do.

In this way, when the spring member 620 is restored to its original shape by the elastic restoring force acting on the spring member 620, the shape restoring force generated in the spiral structure of the spring member 620 is physically coupled to the spring housing. It can also be delivered to 610.

At this time, the elastic force acting on the mainspring member 620 acts in the direction in which the spiral structure of the mainspring member 620 is wound, that is, in the direction in which the intermediate conduit member 220 is opened, as described above. The elastic restoring force of ) acts in the direction in which the mainspring member 620 is unwound, in the direction in which the intermediate channel member 220 is closed.

Thus, the mainspring housing 610 and the motor-side intermediate gear unit 410 reversely rotate in response to the above-described elastic restoration of the mainspring member 620, so that the driven-side intermediate gear unit 420 also rotates in FIGS. 7B, 7A and 7A. By reverse rotation in the order of FIG. 2 , the driven intermediate gear unit 420 and the driven gear member 530 are engaged with each other so that the opening and closing member 510 closes the intermediate pipe member 220 .

Thus, in the order of FIG. 8 to FIG. 5 , the opening/closing member 510 also rotates in the direction of closing the intermediate conduit member 220 in response to the rotation of the driven gear member 530 .

When the above-mentioned intermediate conduit member 220 is comprehensively described, first, according to the operation of the lever member 310, the intermediate connection portion 400 rotates in the order of FIGS. 2, 7A and 7B, FIG. As in the order of 5 and FIG. 8 , the passage opening/closing part 500 can be rotated to open the intermediate passage member 220 .

In addition, as the spring housing 610 rotates together with the intermediate conduit member 220 simultaneously with the above-described process of opening the intermediate conduit member 220, the spring member 620 is also wound in the order shown in FIGS. 6 and 9. can be compressed.

Thereafter, when the spring member 620 is unwound by an elastic restoring force acting on the spring member 620 as shown in the order of FIGS. The rotational force is also transmitted to the mainspring housing 610, so that the mainspring housing 610 also rotates in the same direction as the unwinding direction of the mainspring member 620.

At this time, if it is assumed that the direction in which the mainspring member 620 is wound to open the intermediate conduit member 220 is clockwise, the direction in which the mainspring member 620 is unwound can be understood as a counterclockwise direction, which is the opposite direction.

In addition, in response to the rotation of the mainspring housing 610 according to the unwinding of the mainspring member 620, the intermediate connecting portion 400 rotates in the order of FIGS. 7B, 7A and 2, and thus FIGS. 8 and 5 As in the order of, the passage opening and closing portion 500 can be rotated to close the intermediate conduit member 220.

Through the application of the above-described mainspring spring principle, even if the user does not operate the lever member 310 in the capital-locking direction due to carelessness after operating the lever member 310 in the capital-open direction, the aforementioned spring-up member 620 Through the elastic restoring action, the corresponding waterway can be automatically locked, thereby resulting in an effect of saving resources such as various liquids and gases.

In addition, since the above-described automatic water locking principle works only based on the elastic force of the material, an advantage arises in that a separate power supply for automatic water locking operation is not required.

In addition, the above-described matters based on the accompanying drawings are that the intermediate connection portion 400 rotates clockwise in response to the counterclockwise rotation of the lever member 310, and accordingly, the driven gear member 530 rotates counterclockwise. It can be interpreted that the opening/closing member 510 rotates in the direction of opening the intermediate conduit member 220, and the mainspring housing 610 and the mainspring member 620 rotate clockwise at the same time as the passage is opened.

However, even if the components described above are rotated in the opposite direction according to various factors such as a change in the operation method and a change in structural design, the above-described principle of opening and closing the passage can be similarly implemented.

Also, the mainspring-side gear unit 630 may be provided on an upper surface of the mainspring housing 610 facing the inlet opening 120 and may rotate integrally with the mainspring housing 610 .

In addition, the intermediate channel member 220 may pass through the mainspring-side gear unit 630, and its rotational axis may be provided coaxially with the rotational axis of the mainspring housing 610, and the gear teeth may be along the edge direction of the rotational axis. structure can be formed.

In addition, the escape-side gear unit 640 is formed in a kind of double gear structure, and the one-end gear of the corresponding double gear structure provided toward the outflow opening 130 is geared with the mainspring-side gear unit 630 in a parallel shaft gear type. can be combined

Also, the escape wheel unit 650 may include an intermediate escape gear 651 and an escape wheel 652 .

The intermediate escape gear 651 may be provided on an upper surface of the escape side gear unit 640 toward the inlet opening 120.

In addition, the intermediate escapement gear 651 may mesh with the other end gear of the escapement side gear unit 640 provided toward the inlet opening 120 in a parallel shaft gear method.

In addition, the intermediate pipeline member 220 may pass through the intermediate escapement gear 651, and its rotational axis may be provided coaxially with the rotational axis of the spring housing 610, and the gear teeth structure along the edge direction of the rotational axis. can be formed.

In addition, the escape wheel 652 may be provided in a kind of double gear structure with the intermediate escape gear 651 while being provided on the upper surface of the intermediate escape gear 651 facing the inlet opening 120.

In addition, the intermediate conduit member 220 may pass through the escapement wheel 652, and its rotational axis may be provided coaxially with the rotational axis of the spring housing 610, and a gear tooth structure may be formed along the rim direction of the rotational axis. can be formed

Accordingly, in response to the above-described rotational drive of the mainspring housing 610, the rotational force is transmitted to the escapement wheel 652 through the mainspring side gear unit 630, the escapement side gear unit 640, and the intermediate escapement gear 651. can be conveyed.

That is, it can be understood that the mainspring-side gear unit 630 and the escape wheel unit 650 are mutually interlocked by a double gear structure like the escape-side gear unit 640.

At this time, in the drawings mentioned, the escapement side gear unit 640 having a double gear structure is provided with a total of three, so that the mainspring side gear unit 630 and the intermediate escapement gear 651 are Although shown as interlocking, the number of these double gears may be selected and designed within a variety of ranges, and the above-described double gear structure may also be provided in a singular number.

In addition, by providing the above-described double gear structure, when the opening drive of the intermediate conduit member 220 inducing rotation of the mainspring housing 610 in one direction is performed, the escapement wheel 652 also moves in the corresponding direction. be able to rotate.

Conversely, when the closing drive of the intermediate channel member 220 is performed according to the aforementioned elastic restoring action of the mainspring member 620, the escapement wheel 652 can also rotate in a direction corresponding to this.

That is, it can be understood that the rotational action of the escapement wheel 652 and the rotational action of the spring housing 610 are interlocked together.

Also, the anchor member 660 may include an anchor shaft portion 661 , an anchor body 662 , and a contact pin 663 .

The anchor shaft portion 661 may be provided such that a longitudinal axis, which is a rotational axis, is parallel to the rotational axis of the escapement wheel 652.

In addition, the anchor bodies 662 may extend from the anchor shaft portion 661 as a pair to surround the escapement wheel 652, and accordingly, a predetermined angle between each anchor body 662 may be formed. can

In addition, the contact pins 663 may protrude one by one at both ends of each anchor body 662 so as to contact the gear teeth of the escapement wheel 652 .

In addition, the structure of the anchor body 662 and the contact pin 663 provided as a pair may be provided to be symmetrical to each other with respect to the virtual extension line of the shortest distance between the axis of rotation of the anchor shaft portion 661 and the escapement wheel 652.

In addition, in the structure of the anchor body 662 and the contact pin 663 provided as a pair, when one contact pin 663 contacts the gear tooth of the escapement wheel 652, the other contact pin 663 It may be provided so as not to contact the escapement wheel 652.

In addition, the above-described anchor member 660 may perform a kind of seesaw motion with the anchor shaft portion 661 as an axis in response to the rotation of the escapement wheel 652 .

More specifically, referring to FIG. 10A , when one of the contact pins 663 contacts the gear teeth of the escape wheel 652 in response to the rotation of the escape wheel 652, the other contact pins 663 and The anchor body 662 connected thereto can be spaced apart from the gear teeth of the escapement wheel 652 with the anchor shaft portion 661 as an axis.

That is, as the anchor shaft portion 661 serves as a kind of axis in a seesaw motion, when any one contact pin 663 comes into contact with the escapement wheel 652, the remaining contact pins 663 are anchor shaft portions. It is separated from the escapement wheel 652 with 661 as an axis in the seesaw motion.

Next, as shown in the order of FIGS. 10A to 10B, the contact pin 663, which has previously been in contact with the gear teeth of the escapement wheel 652, moves along the corresponding gear as the rotation of the escapement wheel 652 proceeds. It is separated from the teeth, and at the same time, the above-described seesaw motion occurs, so that the remaining contact pins 663, which have been previously spaced apart from the gear teeth of the escape wheel 652, come into contact with the gear teeth of the escape wheel 652.

In addition, the items described above in the order of FIGS. 10A and 10B or the items corresponding to the reverse order may be repeatedly performed according to the rotation of the escapement wheel 652.

Accordingly, the escapement wheel 652 comes into contact with each of the contact pins 663 alternately, so that a braking or interference action occurs in the rotational motion of the escapement wheel 652 corresponding to the cycle of the seesaw motion described above.

At this time, the seesaw motion period of the anchor member 660 having a certain range within a predetermined range may be set within a variety of ranges corresponding to various design matters such as the distance between both contact pins 663 .

That is, the escapement wheel 652 and the anchor member 660 can be understood as a relationship in which a kind of escapement and anchor principle is applied to each other.

In this way, as the anchor member 660 brakes the rotation of the escapement wheel 652 at regular intervals, the rotation of the spring housing 610 interlocked with the escapement wheel 652 is also braked or interfered with as described above. action will occur.

And, as described above, since the rotational action of the mainspring housing 610 is interlocked with the unwinding process of the mainspring member 620, the anchor member 660 is exhausted despite the unwinding and elastic restoring action of the mainspring member 620. A braking or interference action caused by the wheel 652 can be applied.

Thus, the unwinding and elastic restoring action of the mainspring member 620 can be performed with a predetermined period corresponding to the braking or interfering action of the anchor member 660 on the escape wheel 652, so that the intermediate connection portion ( 400) and the like can also be performed regularly as long as the corresponding period, so that performance and operation stability of the device can be improved.

As described above, the main technical idea of the present invention is to provide a passage opening and closing device, and the embodiment described above with reference to the drawings is only one embodiment, and the scope of the present invention is not limited to the claims. , It will also extend to equivalent embodiments that can exist in various ways.

1000: flow path opening and closing device according to the present invention
100: case part
110: case body
120: inflow opening
130: outflow opening
200: Euro part
210: cover member
211: concave hole
220: intermediate pipe member
221: inner tube member
222: outer tube member
223: spring installation groove
230: outflow housing
240: outlet
300: control panel
310: lever member
320: lever axis
330: driving gear member
400: intermediate connection
410: motor side intermediate gear
420: driven intermediate gear unit
500: Euro opening and closing part
510: opening and closing member
511: ball euro
520: opening and closing shaft
530: driven gear member
600: flow path automatic closing drive unit
610: mainspring housing
611: spring fixing part
620: absence of mainspring
630: mainspring gear part
640: escape side gear unit
650: escape wheel part
651: middle escape gear
652: escape wheel
660: anchor member
661: anchor shaft
662: anchor body
663: contact pin

Claims (5)

a flow path portion including an intermediate conduit member through which fluid passes;
a control unit including a lever member provided on either side of the flow path unit;
an intermediate connecting portion that rotates by receiving the rotational force of the lever member; and
A flow path opening and closing device comprising a flow opening and closing portion that opens and closes the intermediate conduit member through a rotational valve drive, and rotates in a direction of opening and closing the intermediate conduit member by receiving rotational force of the intermediate connection portion.
According to claim 1,
The flow path opening and closing device,
When the intermediate connection portion is rotated in the direction of opening the intermediate pipe member and at the same time receives the rotational force of the intermediate connection portion and accumulates elastic force, and an elastic restoring force corresponding to the elastic force is generated, the intermediate connector connects the intermediate pipe member. Passage opening and closing device characterized in that it further comprises a flow passage automatic closing drive for transmitting the elastic restoring force to the intermediate connection portion to rotate in the closing direction.
According to claim 2,
The flow path automatic closing drive unit,
a mainspring housing rotatable integrally with the intermediate connecting portion; and
It is provided inside the mainspring housing while having a predetermined spiral structure, and when the intermediate connection part rotates in a direction to open the intermediate conduit member, it is compressed by rotating together with the mainspring housing to accumulate the elastic force, and the elastic restoring force The passage opening and closing device comprises a mainspring member that restores its shape according to the action of the mainspring and transmits a rotational force to the mainspring housing corresponding to the elastic restoring force so that the mainspring housing rotates in a direction to close the intermediate conduit member. . According to claim 3,
The flow path automatic closing drive unit,
A passage opening and closing device characterized in that the unwinding speed of the mainspring member can be maintained within a predetermined cycle range. According to claim 4,
The flow path automatic closing drive unit,
an escapement wheel part interlocked with the rotation drive of the mainspring housing; and
An escapement opening and closing device comprising an anchor member interfering with the rotation of the escapement wheel within a predetermined period according to the principle of an escapement and an anchor.

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