JP6920721B2 - Faucet with lock mechanism - Google Patents

Description

The present invention relates to a faucet with a locking mechanism.

Water faucets may be installed outside the building. Such water services are at risk of stealing water. Therefore, a device for preventing water theft is attached to the faucet of the water supply.

Patent Document 1 discloses a water stopcock lock for preventing water theft, which includes a dial-type lock. In the water stopcock lock for preventing water theft, the handle cannot be attached to the valve shaft of the stopcock unless the dial type lock is removed. Therefore, when the dial-type lock is attached, both the water discharge operation and the water stop operation cannot be performed.

Japanese Unexamined Patent Publication No. 2001-065213

In the water stopcock lock for preventing water theft of Patent Document 1, if water leaks from the discharge port with the dial type lock attached, the dial type lock must be removed once in order to stop the water. , There is a problem that it takes time and effort.

An object of the present invention is to provide a faucet capable of performing a water stop operation even when the water discharge operation is regulated.

The faucet of the present invention includes a valve that opens and closes a water passage, a handle that moves the valve to open and close the water passage, a locked state in which the valve can be moved only in the water stop direction, and water stop. It is characterized by comprising a lock mechanism for switching between an unlocked state in which the valve can be moved in both a direction and a water discharge direction.

In the faucet of the present invention, the locking mechanism urges the ratchet teeth that can rotate with the valve and the handle, the ratchet claws that can engage with the ratchet teeth, and the ratchet claws toward the ratchet teeth. When the ratchet teeth and the ratchet claws are in an engaged state, the elastic member and a moving means for moving the ratchet claws to engage and disengage the ratchet teeth and the ratchet claws are provided. When the ratchet teeth and the ratchet claws are in the locked state and the ratchet claws are in the disengaged state, the unlocked state is preferable.

In the faucet of the present invention, the lock mechanism further includes a driving means for driving the moving means, and the faucet is a power source electrically connected to the driving means and a control means for controlling the driving means. It is preferable that the control means further includes a communication unit that transmits and receives a signal to and from the information terminal, and the control means drives the drive means by a signal transmitted from the information terminal.

In the faucet of the present invention, the lock mechanism can switch between a locked state in which the water discharge operation is restricted and an unlocked state in which the water discharge operation is permitted. In the locked state, the valve cannot be moved in the water discharge direction (the direction in which the water passage is opened). Therefore, water theft can be prevented. On the other hand, even in the locked state, the valve can be moved in the water stop direction (the direction in which the water passage is closed). Therefore, when water is leaking, the water can be stopped simply by moving the valve (handle) in the water stopping direction.

It is a perspective view of a faucet. It is an exploded perspective view of a faucet. It is a perspective schematic plan view which shows the locked state, (a) shows the state which the handle was rotated in the water discharge direction, and (b) shows the state that the handle was rotated in the water stop direction. It is a perspective schematic plan view which shows the unlocked state. It is a block diagram which shows the structure of the control means of a faucet.

The present invention will be described with reference to the drawings. In addition, all of the embodiments described below show a preferable specific example of the present invention. The present invention is not limited to the following embodiments, and can be appropriately modified without departing from the spirit of the present invention.

<Structure of faucet>
FIG. 1 is a perspective view of the faucet 10 of the present invention, and FIG. 2 is an exploded perspective view of the faucet 10. The faucet 10 of the present invention includes a faucet main body 20, a valve 30, a handle 40, a lock mechanism 50, and a power supply 60.

The faucet main body 20 includes an inflow port 21 into which water flows in, a discharge port 22 from which water is discharged, a power supply accommodating portion 23 accommodating a power source 60, and a power supply cover 24 covering the power accommodating portion 23. ..

An opening 25 is formed in the upper part of the faucet main body 20, and a female screw 26 is formed on the inner peripheral surface of the opening 25. A motor accommodating portion 27 for accommodating the motor 55, which will be described later, is formed around the opening 25.

A water passage (not shown) is provided in the faucet main body 20, and the water passage includes a first water passage on the inflow port 21 side and a second water passage on the discharge port 22 side. A valve seat (not shown) having an opening for communicating the first passage and the second passage is formed between the first passage and the second passage. The water flowing in from the inflow port 21 flows in the order of the first water passage, the opening of the valve seat, and the second water passage, and is discharged from the discharge port 22.

The valve 30 includes a shaft member 31, a valve body 32 provided on one side of the shaft member 31 and seated on and off the valve seat of the water passage, and a connecting member 33 provided on the other side of the shaft member 31. I have. A male screw 311 screwed with the female screw 26 of the faucet body 20 is formed at substantially the center of the shaft member 31 in the axial direction. The connecting member 33 is composed of a tubular member, and is attached to the shaft member 31 so as not to rotate relative to each other. A female screw 331 is formed on the inner peripheral surface of the connecting member 33. A plurality of concavo-convex (serration) 332s extending in the axial direction are formed on the outer peripheral surface of the connecting member 33 in the circumferential direction. The connecting member 33 is inserted into the tubular portion of the ratchet tooth member 51, which will be described later.

The valve 30 is attached to the faucet body 20 by screwing the male screw 311 of the shaft member 31 into the female screw 26 of the faucet body 20. As a result, the valve 30 can move in the axial direction while rotating with respect to the faucet main body 20. Then, by moving the valve 30 in the axial direction, the valve body 32 can be taken off and seated on the valve seat. When the valve body 32 is seated on the valve seat, the opening of the valve seat is closed, and the water flowing in from the inflow port 21 is stopped by the valve body 32. As a result, water is not discharged from the discharge port 22. On the other hand, the opening of the valve seat is opened by separating the valve body 32 from the valve seat. As a result, the first water passage and the second water passage communicate with each other, and the water flowing in from the inflow port 21 is discharged from the discharge port 22.

The handle 40 is composed of a ridged tubular member, and an opening 42 is formed at substantially the center of the top portion 41. A bolt 70 is inserted into the opening 42, and the bolt 70 is screwed with the female screw 331 of the connecting member 33. As a result, the handle 40 and the valve 30 are connected, and the valve 30 also rotates as the handle 40 is rotated.

The lock mechanism 50 has a ratchet mechanism. The lock mechanism 50 includes a ratchet tooth member 51, a ratchet pawl 52, a wire spring 53, a cam 54, and a motor 55.

The motor 55 is housed in the motor housing section 27. The motor box 57 is covered with the motor 55 via the packing 56. The motor box 57 is fixed to the faucet body 20 with bolts or the like. The motor box 57 is formed with an opening 571 for attaching the ratchet pawl 52, an opening 572 for attaching the wire spring 53, an opening 573 for inserting the shaft portion of the motor 55, and a cam stopper 574. .. The cam stop 574 is a stepped portion protruding from the upper surface of the motor box 57.

The motor 55 is electrically connected to the power supply 60 housed in the power supply accommodating portion 23 of the faucet main body 20. In this embodiment, the power source 60 is a portable power source such as a rechargeable or non-rechargeable dry cell battery. The power supply 60 is not limited to the portable power supply.

The shaft portion of the motor 55 passes through the opening 573 and projects from the upper surface of the motor box 57. A cam 54 is arranged on the upper surface of the motor box 57, and the cam 54 is attached to a shaft portion of the motor 55. As a result, the cam 54 rotates as the motor 55 is driven to rotate. The cam 54 comes into contact with the cam stopper 574 so that it does not rotate any further.

The ratchet tooth member 51 is composed of a tubular member having ratchet teeth 511 formed on the entire outer peripheral surface. The connecting member 33 is inserted into the tubular portion of the ratchet tooth member 51. In this way, the handle 40 and the ratchet tooth member 51 are indirectly connected via the bolt 70 and the connecting member 33. Since a plurality of irregularities 332 are formed on the outer peripheral surface of the connecting member 33, the frictional force between the outer peripheral surface of the connecting member 33 and the inner peripheral surface of the ratchet tooth member 51 causes the connecting member 33 and the ratchet tooth member 51. It is not possible to rotate relative to. Therefore, when the valve 30 is rotated by the handle 40, the valve 30 (handle 40) and the ratchet tooth member 51 both rotate. The connecting member 33 and the ratchet tooth member 51 may be composed of one member instead of being composed of separate members.

The ratchet pawl 52 has a shaft member 521, a ratchet claw 522 that can engage with the ratchet tooth 511, and an arm portion 523. The shaft member 521 is inserted into the opening 571 formed in the motor box 57. Then, the ratchet pawl 52 is rotatably held with respect to the motor box 57. The ratchet claw 522 and the arm portion 523 are formed on the upper portion of the shaft member 521, and the ratchet claw 522 and the arm portion 523 form a substantially right angle.

The wire spring 53 is composed of a linear spring whose center is bent. One end of the wire spring 53 is inserted into the opening 572 of the motor box 57, and the other end is in contact with the recessed portion 524 formed on the outer surface of the arm portion 523. The wire spring 53 urges the ratchet claw 522 toward the ratchet tooth 511.

3 (a) and 3 (b) are perspective plan views showing a locked state. FIG. 4 is a perspective plan view showing the unlocked state.

The lock mechanism 50 rotates the cam 54 by driving the motor 55 to rotate. Then, when the rotating cam 54 comes into contact with the arm portion 523 of the ratchet pawl 52, the ratchet pawl 52 rotates together with the cam 54.

In the states shown in FIGS. 3A and 3B, the cam 54 does not exert a force on the ratchet pawl 52, and the ratchet pawl 522 of the ratchet pawl 52 is urged toward the ratchet tooth 511 by the wire spring 53. The ratchet teeth 511 and the ratchet claws 522 are engaged.

As shown in FIG. 3A, when the ratchet tooth 511 and the ratchet claw 522 are engaged and the handle 40 is to be rotated in the water discharge direction (indicated by the arrow A in FIG. 3A), The ratchet claw 522 bites into the ratchet tooth 511. Therefore, the ratchet tooth 511 cannot get over the ratchet claw 522, and the ratchet tooth 511 cannot rotate. Therefore, when the ratchet teeth 511 and the ratchet claws 522 are engaged with each other, the handle 40 and the valve 30 cannot be rotated in the water discharge direction A, and water cannot be discharged.

On the other hand, as shown in FIG. 3 (b), when the handle 40 is rotated in the water stopping direction (indicated by the arrow B in FIG. 3 (b)), the ratchet teeth 511 act on the ratchet claw 522 with the wire spring 53. It overcomes the ratchet claw 522 and rotates against the elastic force of. Therefore, the handle 40 and the valve 30 can be rotated in the water stop direction B, and water can be stopped.

As described above, in the locked state, the water discharge operation of the valve 30 (handle 40) is restricted, but the water stop operation is permitted.

The motor 55 is driven to rotate the cam 54 in the direction of arrow C shown in FIG. 3 (b). After the cam 54 comes into contact with the arm portion 523 of the ratchet pawl 52, the cam 54 rotates the ratchet pawl 52 to the position shown in FIG. 4 against the elastic force of the wire spring 53. The state shown in FIG. 4 is a state in which the ratchet teeth 511 and the ratchet claw 522 are disengaged, and represents an unlocked state. The cam 54 is controlled to stop at the position shown in FIG. 4 by, for example, the elastic force of the wire spring 53, the detection of the position of the cam 54 by a sensor, or the rotation angle control of the motor 55 (using a stepping motor). .. In the unlocked state, since the ratchet teeth 511 and the ratchet claws 522 are not engaged with each other, the valve 30 (handle 40) can be rotated in both the water discharge direction A and the water stop direction B.

In order to switch from the unlocked state to the locked state, the cam 54 is rotated in the direction of the arrow D shown in FIG. When the cam 54 rotates in the arrow D direction, the ratchet pawl 52 automatically rotates in the arrow D direction due to the elastic force (restoring force) of the wire spring 53, and the ratchet claw 522 engages with the ratchet tooth 511.

As described above, in the faucet 10 of the present invention, the valve 30 and the handle 40 can be rotated only in the water stop direction B by the lock mechanism 50, and the valve 30 and the handle 40 are in the water discharge direction A and the water stop direction. It is possible to switch to a state where it can be rotated to both B. That is, in the locked state, the water discharge operation is restricted but the water stop operation is permitted, and in the unlocked state, both the water discharge operation and the water stop operation are permitted. Therefore, even when water is discharged from the discharge port 22 in the locked state, water can be stopped only by rotating the handle 40 in the water stop direction B. The faucet 10 is particularly useful as an outdoor faucet installed outdoors in a building.

<Modified example of faucet structure>
In the locked state, when the handle 40 is rotated in the water stop direction, the valve 30 also rotates, but when the handle 40 is rotated in the water discharge direction, the connection between the handle 40 and the valve 30 is released, and only the handle 40 is released. The handle 40 may rotate in the water discharge direction (that is, the handle 40 may idle). In this case as well, even if the handle 40 is rotated in the water discharge direction, the valve 30 does not rotate in the water discharge direction, so that the water discharge operation is restricted and water theft can be prevented.

<Faucet control system>
Hereinafter, a control system for controlling the lock mechanism 50 of the faucet 10 will be described. The faucet 10 further includes a control means 80 for controlling the lock mechanism 50. The control means 80 is housed in the faucet main body 20. When the user operates the information terminal S to transmit a signal to the faucet 10, the control means 80 executes a locking operation, an unlocking operation, and the like of the locking mechanism 50. The information terminal S is an information terminal capable of wireless communication, and a portable information terminal such as a smartphone or a tablet is assumed.

As shown in FIG. 5, the control means 80 includes a communication unit 81 and a control unit 82.

The communication unit 81 performs wireless communication or wired communication with the information terminal S. It is preferable that the communication unit 81 can wirelessly communicate with the information terminal S so that the faucet 10 can be remotely controlled by the information terminal S. The communication unit 81 transmits a request from the information terminal S to the control unit 82. The communication unit 81 may be configured to enable bidirectional communication so as to transmit the information of the faucet 10 to the information terminal S. Examples of the wireless communication method include short-range wireless communication such as Bluetooth (registered trademark). Short-range wireless communication is wireless communication within several tens of meters. The wireless communication may be mobile communication (for example, 4G), Wi-Fi (registered trademark), or the like.

The control unit 82 controls the processing inside the faucet 10. The control unit 82 controls the drive of the motor 55 by, for example, a signal from the communication unit 81.

When the communication unit 81 receives the unlock request from the information terminal S, the communication unit 81 transmits the unlock request to the control unit 82. Upon receiving the unlock request, the control unit 81 drives the motor 55 to move the cam 54 to the unlock position shown in FIG. In this way, the lock mechanism 50 is in the unlocked state.

On the other hand, when the communication unit 81 receives the lock request from the information terminal S, the communication unit 81 transmits the lock request to the control unit 82. Upon receiving the lock request, the control unit 82 drives the motor 55 to move the cam 54 to the lock position shown in FIG. In this way, the lock mechanism 50 is in the locked state.

<Modification example of faucet control system>
The control means 80 may further include a sensor for detecting whether the lock mechanism 50 is in the locked state or the unlocked state. The sensor is not particularly limited, and may be a contact type sensor or a non-contact type sensor such as an optical sensor. The sensor may detect the position of the cam 54 or the ratchet pawl 52, thereby detecting whether it is locked or unlocked.

In the following, a faucet including a first sensor that detects that the cam 54 is in the locked position shown in FIG. 3 and a second sensor that detects that the cam 54 is in the unlocked position shown in FIG. 10 will be described as an example.

When the first sensor detects that the cam 54 is in the locked position, the control unit 82 cuts off the electrical connection between the motor 55 and the power supply 60. Further, the faucet 10 transmits to the information terminal S that it is in the locked state. When the communication unit 81 of the faucet 10 receives the unlock request from the information terminal S, the control unit 82 electrically connects the motor 55 and the power supply 60 and rotates the cam 54 to the unlocked position. When the second sensor detects the cam 54, the control unit 82 cuts off the electrical connection between the motor 55 and the power supply 60. Then, the faucet 10 transmits to the information terminal S that it is in the unlocked state. In this way, the user can know whether the lock mechanism 50 is in the locked state or the unlocked state via the information terminal S.

Instead of using both the first sensor and the second sensor, only one of the first sensor and the second sensor may be used. In this case, it is preferable that the control means 80 further includes a timer. For example, when using only the first sensor, when the faucet 10 receives an unlock request from the information terminal S, the control unit 82 of the faucet 10 electrically connects the motor 55 and the power supply 60, and the motor The 55 is driven and the cam 54 is rotated. As the cam 54 rotates, the first sensor does not detect the cam 54. Then, after a predetermined time preset in the timer has elapsed, the control unit 82 automatically cuts off the electrical connection between the motor 55 and the power supply 60. Then, the faucet 10 transmits to the information terminal S that it is in the unlocked state. As the predetermined time set in the timer, the time for the cam 54 to move from the locked position to the unlocked position is measured in advance, and a time equal to or longer than that time is set. When the faucet 10 receives the lock request in the unlocked state, the control unit 82 drives the motor 55 to move the cam 54 to the locked position. When the cam 54 is detected by the first sensor, the control unit 82 cuts off the electrical connection between the motor 55 and the power supply 60. Then, the faucet 10 transmits to the information terminal S that it is in the locked state. The same applies when only the second sensor is used.

10 Faucet 20 Faucet body 30 Valve 40 Handle 50 Lock mechanism 51 Ratchet tooth member 511 Ratchet tooth 52 Ratchet pawl 521 Shaft member 522 Ratchet claw 523 Arm 53 Wire spring (elastic member)
54 cam (means of transportation)
55 Motor (driving means)
60 Power supply 70 Volts 80 Control means 81 Communication unit 82 Control unit S Information terminal

Claims (2)

A valve that opens and closes the waterway,
A handle that moves the valve to open and close the water passage,
A lock mechanism that switches between a locked state in which the valve can be moved only in the water stop direction and an unlocked state in which the valve can be moved in both the water stop direction and the water discharge direction.
Equipped with a,
The lock mechanism is
With ratchet teeth that can rotate with the valve and the handle,
With a ratchet claw that can engage with the ratchet tooth,
An elastic member that urges the ratchet claw toward the ratchet tooth,
A moving means for moving the ratchet claw to engage and disengage the ratchet tooth and the ratchet claw.
With
When the ratchet tooth and the ratchet claw are in the engaged state, the locked state is set, and when the ratchet tooth and the ratchet claw are in the disengaged state, the unlocked state is set.
A faucet that is characterized by that. The locking mechanism further includes a driving means for driving the moving means.
The faucet further includes a power source electrically connected to the drive means and a control means for controlling the drive means.
The control means includes a communication unit that transmits and receives signals to and from an information terminal.
The control means drives the drive means by a signal transmitted from the information terminal.
The faucet according to claim 1.

Images