JP6083550B1 - Liquid supply mechanism - Google Patents

Abstract

A liquid supply mechanism capable of automatically stopping liquid supply to a main body tank by a liquid supply tank with a compact configuration that does not require a power source. A liquid supply mechanism includes a main body tank, a liquid supply tank, a float, and a valve operating mechanism. The liquid supply tank 60 is configured to be detachable from the housing 11, stores liquid for supplying liquid to the main body tank 15, and a liquid supply port 80 is pushed upward to push the liquid supply port. The liquid is supplied to the main body tank 15 through the inlet 15b. The valve operating mechanism 40 is disposed between the inlet 15b and the float 30, and has a pressing portion that pushes up the liquid supply valve 80 when the liquid supply tank 60 is attached while the liquid level of the main body tank 15 is below a predetermined level. In addition, the float 30 rises as the liquid is supplied, so that the force from the float 30 is received and the push-up of the liquid supply valve 80 by the pressing portion is released. [Selection] Figure 5

Description

  The present invention mainly relates to a liquid supply mechanism for supplying liquid from a liquid supply tank to a main body tank.

  Patent Documents 1 to 3 disclose techniques related to a liquid supply mechanism.

  The mist generator of Patent Document 1 includes a water storage chamber, a water storage sensor, a water supply tank, and a solenoid. The water storage chamber stores water for releasing mist to the outside. The water storage sensor electrically detects the water level in the water storage chamber. The water supply tank supplies water to the water storage chamber through a water supply valve provided at the lower part. The solenoid is disposed below the water supply valve. When the solenoid is energized, the solenoid moves upward and presses the water supply valve upward to open the water supply port. The solenoid moves upward when energized based on the detection result of the water storage sensor or the like. When the solenoid moves upward, the water supply valve is pressed, and water is supplied from the water supply tank to the water storage chamber.

  The ball tap of patent document 2 is arrange | positioned at the water storage tank which stores the water supplied from a water pipe, and stops supply of the water from a water pipe based on the water level of a water storage tank. Specifically, the ball tap includes a float, a lever member, and a valve function unit. The float moves up and down with the water level of the water storage tank. The lever member is connected to the float and rotates up and down as the float moves up and down. A valve function part switches the presence or absence of the water supply from a water pipe by switching the presence or absence of opening of a pilot valve hole by moving up and down with the vertical rotation of a lever member.

  The humidifier of Patent Literature 3 includes a heating tank, a water supply tank, a float, a pressing operation unit, and an interlocking rod. Water is stored in the heating tank, and steam is released to the outside by heating the water in the heating tank. The water supply tank is a member that supplies water to the heating tank, and a water supply opening / closing valve is formed in the lower part. The float is arrange | positioned in a heating tank, and raises / lowers according to the water level of a heating tank. The pressing operation unit is disposed below the water supply opening / closing valve, and can move the water supply opening by moving upward. The interlocking rod is arranged on the bottom of the heating tank and operates as a seesaw. A float is connected to one of the interlocking rods, and a pressing operation unit is connected to the other. With this configuration, when the water level of the heating tank is higher than a predetermined value, the water supply port is closed, and when the water level of the heating tank is lower than another predetermined value, the water supply port is opened.

Japanese Patent Laying-Open No. 2015-59672 JP-A-6-147356 JP2013-2797A

  However, since Patent Document 1 electrically detects the water level and operates the water supply valve, water supply cannot be controlled in a situation where the mist generator is not connected to the power source. Moreover, since an electrical wiring and a sensor are needed, a structure becomes complicated.

  Moreover, since patent document 2 is the structure which connects to a water pipe and stores water, the position which can be installed is restrict | limited. Moreover, when extending a water pipe to a required position, great cost is needed. Furthermore, since the valve function part moves up and down in the same direction as the raising and lowering of the float and switches the presence or absence of opening of the pilot valve hole, a general water supply valve provided in the lower part of the water supply tank (Patent Documents 1 and 3) It cannot be applied to water supply valves.

  Moreover, since patent document 3 needs to provide an interlocking rod in the bottom part of a heating tank, and to provide the float and the press operation part in succession, the mechanism which operates a valve becomes large. In particular, when the horizontal size of the heating tank is small, it is difficult to provide an interlocking rod. Moreover, when the size of the heating tank in the depth direction is large, it becomes difficult to provide the interlocking rod, or the interlocking rod is further enlarged.

  The present invention has been made in view of the above circumstances, and a main object of the present invention is to be able to automatically stop the liquid supply to the main body tank by the liquid supply tank with a compact and power-free configuration. It is to provide a liquid supply mechanism.

Means and effects for solving the problems

  The problems to be solved by the present invention are as described above. Next, means for solving the problems and the effects thereof will be described.

According to an aspect of the present invention, a liquid supply mechanism having the following configuration is provided. That is, the liquid supply mechanism includes a main body tank, a liquid supply tank, a float, and a valve operation mechanism. The main body tank is disposed inside the housing, stores liquid, and has an inlet at the top. The liquid supply tank is configured to be detachable from the housing, stores liquid for supplying liquid to the main body tank, and a liquid supply valve provided at a lower part is pushed upward to open a liquid supply port. Then, liquid is supplied to the main body tank through the inlet. The float is disposed near or below the inlet, and moves up and down according to the liquid level of the main body tank. The valve operating mechanism is disposed between the inlet and the float, and pushes the liquid supply valve upward when the liquid supply tank is attached in a state where the liquid level of the main body tank is below a predetermined level. While having a press part, it operates so that the lift of the liquid supply valve by the press part may be canceled by receiving a force from the float as the float rises with liquid supply. In addition, even when the float is lowered after the height of the liquid level of the main body tank is lowered again after releasing the push of the liquid supply valve by the pressing portion, the valve operating mechanism Operates so that the lifted state of the feed valve is released

Accordingly, the liquid supply to the main body tank by the liquid supply tank can be automatically stopped with a compact configuration that does not require a power source. Further, since the valve operating mechanism is disposed near or below the liquid supply port of the main body tank, a highly versatile liquid supply mechanism that can be applied regardless of the container shape of the main body tank can be realized. In addition, after the lift of the liquid supply valve by the pressing portion is released, the lift of the liquid supply valve is released even when the liquid level of the main body tank is lowered again and the float is lowered. By operating so as to maintain the state, it is possible to prevent liquid supply from being started again at a timing not intended by the user.

  The liquid supply mechanism preferably has the following configuration. That is, during the liquid supply from the liquid supply tank to the main body tank, the contact surface formed on the liquid supply valve is in contact with the pressing surface formed on the pressing portion. The valve operating mechanism is configured so that the contact surface and the pressing surface do not overlap when viewed in a vertical direction by raising the float from a state where the contact surface and the pressing surface are in contact with each other. By operating, the push-up of the liquid supply valve by the pressing portion is released.

  Thereby, since it is only necessary to provide a mechanism for converting the rise of the float into a direction including the horizontal direction, the structure of the valve operating mechanism can be simplified. Moreover, compared with the structure which moves a press part below, especially the size of the up-down direction of a valve operation mechanism can be reduced.

  In the liquid supply mechanism, after the lift of the liquid supply valve by the pressing portion is released, the valve operation mechanism again lowers the liquid level of the main body tank and lowers the float. It is preferable to operate so as to push up the liquid supply valve.

  Thereby, since liquid supply is started automatically, a user's effort can be reduced. Moreover, since the liquid supply tank can be used as an auxiliary tank, the tank capacity can be easily increased.

The front view of the housing | casing provided with the liquid supply mechanism which concerns on one Embodiment of this invention. The partial cross section perspective view which shows the structure of the lower part of a liquid supply tank, and the upper part of a main body tank. The partial cross section perspective view which shows the state which the 1st opening / closing member and the 2nd opening / closing member have closed. The partial cross section perspective view which shows the state which the 1st opening / closing member and the 2nd opening / closing member open | released. Sectional drawing which shows a mode that a 1st opening / closing member and a 2nd opening / closing member open and close when the liquid level of a main body tank raises. The schematic front view which shows the structure of the valve operation mechanism which concerns on a 1st modification. The schematic front view which shows the structure of the valve operation mechanism which concerns on a 2nd modification.

  Next, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a front view of a housing 11 provided with a liquid supply mechanism 10 according to an embodiment of the present invention.

  As shown in FIG. 1, the liquid supply mechanism 10 of the present embodiment is provided in a housing 11. The liquid supply mechanism 10 includes a main body tank 15 and a liquid supply tank 60. The liquid supply mechanism 10 is provided in, for example, a humidifier that stores water for humidification, a water server that stores drinking water (cold water, hot water), or a heating appliance that stores heating kerosene. As long as the liquid supply mechanism 10 is configured to supply a predetermined liquid to the main body tank 15 using the liquid supply tank 60, the liquid supply mechanism 10 may be provided in a device other than the above.

  The housing | casing 11 is a member which accommodates and supports the various components with which the above-mentioned humidifier, a water server, a heating appliance, etc. are provided. The casing 11 is configured so that the liquid supply tank 60 can be attached and detached. The liquid supply tank 60 may be detachable from the upper part of the housing 11 or may be detachable from other parts of the housing 11. A main body tank 15 is provided inside the housing 11.

  As described above, the main body tank 15 has the main body container portion 15a for storing liquid for humidification, beverage use, or heating use. The main body tank 15 is disposed inside the housing 11, specifically in the vicinity of the upper portion of the housing 11. In the upper part of the main body tank 15, an injection port 15 b is formed for injecting liquid to supply liquid when the stored liquid decreases. By attaching the liquid supply tank 60 shown in FIG. 1 to the housing 11, liquid supply is performed from the liquid supply tank 60 to the main body tank 15 (specifically, the main body container portion 15a). Although it is assumed that the liquid supply tank 60 is basically attached to the housing 11 only during liquid supply, it may be always attached to the housing 11. In the following description, the liquid or the like stored in the main body container portion 15a of the main body tank 15 is simply referred to as “liquid stored in the main body tank 15” or the like. Details of liquid supply from the liquid supply tank 60 to the main body tank 15 will be described later.

  The liquid supply tank 60 includes a liquid supply container portion 61 that stores liquid for supplying liquid to the main body tank 15. The volume of the liquid supply container portion 61 of this embodiment is smaller than the volume of the main body container portion 15a, but may be larger. In the liquid supply tank 60, a replenishment unit 63 and a liquid supply unit 64 are formed.

  The supply part 63 is formed in the upper part of the liquid supply tank 60, and is comprised from the supply port for supplying a liquid to the liquid supply tank 60, and the cover part which plugs up the said supply port. The lid is detachable from the replenishing port. Further, the replenishing unit 63 also functions as an air hole for introducing air into the liquid supply tank 60 when supplying liquid from the liquid supply tank 60 to the main body tank 15.

  The liquid supply part 64 is formed in the lower part of the liquid supply tank 60, and a liquid supply port 72 for supplying liquid to the main body tank 15 is formed.

  Next, the details of the liquid supply from the liquid supply tank 60 to the main body tank 15 will be described with reference to FIGS. FIG. 2 is a partial cross-sectional perspective view showing the configuration of the lower part of the liquid supply tank 60 and the upper part of the main body tank 15. FIG. 3 is a partial cross-sectional perspective view showing a state in which the first opening / closing member 42 and the second opening / closing member 43 are closed. FIG. 4 is a partial cross-sectional perspective view showing a state where the first opening / closing member 42 and the second opening / closing member 43 are opened. In FIGS. 2 to 4, members other than the float 30 and the valve operating mechanism 40 are shown as cross sections cut along a plane parallel to the central axis of the liquid supply port 72 and the like.

  First, the liquid supply structure (liquid supply unit 64) on the liquid supply tank 60 side will be described. As shown in FIG. 2, the liquid supply unit 64 includes a liquid supply valve mounting member 70 and a liquid supply valve 80. The liquid supply valve mounting member 70 is disposed so as to block a hole (specifically, part of the hole) formed in the lower part of the liquid supply tank 60. The liquid supply valve attachment member 70 is detachably attached to the liquid supply tank 60. The liquid supply valve mounting member 70 includes a base portion 71, and a liquid supply port 72, a first cylindrical portion 73, a second cylindrical portion 74, and a flange portion 75 are formed in the base portion 71. Has been.

  The base portion 71 is a disk-shaped member that closes a hole formed in the lower portion of the liquid supply tank 60. The liquid supply port 72 is a circular hole formed in the base portion 71. The liquid supply port 72 is for flowing the liquid stored in the liquid supply tank 60 to the main body tank 15. The first cylindrical portion 73 and the second cylindrical portion 74 are cylindrical portions formed so as to extend further downward (from the main body tank 15 side) from the base portion 71. The first cylindrical portion 73 is larger in diameter than the liquid supply port 72 and smaller in diameter than the second cylindrical portion 74. The flange portion 75 is a portion formed so as to spread outward in the vicinity of the upper end portion of the second cylindrical portion 74. As shown in FIG. 5, the lower end of the first cylindrical portion 73 is located above the lower end of the second cylindrical portion 74. With this configuration, when the liquid supply tank 60 is placed on the floor, the first cylindrical portion 73 does not come into contact with the floor, so that dust or the like hardly adheres to the first cylindrical portion 73. Can be prevented more reliably.

  The liquid supply valve 80 is a member that switches between a state in which the liquid supply port 72 is opened and a state in which the liquid supply port 72 is closed. As shown in FIG. 2, the liquid supply valve 80 includes a valve rod 81, a valve body 82, and a return spring 83. The valve stem 81 is supported by the base 71 so as to be movable in the vertical direction (vertical direction). A contact surface 81 a for pressing and moving the valve stem 81 upward is formed at the lower portion of the valve stem 81. A valve body 82 is attached to the upper part of the valve stem 81. The valve element 82 is a disk-shaped member having a diameter larger than that of the liquid supply port 72. The valve body 82 closes the liquid supply port 72 when the valve rod 81 is positioned on the lower side, and opens the liquid supply port 72 when the valve rod 81 is positioned on the upper side. The return spring 83 is disposed on the valve stem 81 (specifically, between the base portion 71 and the contact surface 81a). The valve stem 81 is urged downward by the return spring 83.

  With this configuration, in a situation where the contact surface 81a is not pressed upward, the valve stem 81 is positioned below by the return spring 83, so that the liquid supply port 72 is closed and liquid supply to the main body tank 15 is performed. (The state of FIG. 2). On the other hand, in a situation where the contact surface 81a is pressed upward with a force greater than a predetermined force (a force that overcomes the biasing force of the return spring 83), the valve rod 81 is positioned on the upper side, so the liquid supply port 72 is opened, Liquid supply to the main body tank 15 is performed (state shown in FIG. 3). In addition, since the 1st cylindrical part 73 is arrange | positioned so that the valve rod 81 may be covered, it can prevent that a user touches the liquid supply valve 80 and a liquid spills.

  Next, the liquid supply structure on the main body tank side will be described. As shown in FIGS. 1 and 2, the liquid supply mechanism 10 includes a liquid supply auxiliary member 20, a float 30, and a valve operation mechanism 40 in the vicinity of the inlet 15 b of the main body tank 15.

  The liquid supply auxiliary member 20 is disposed so as to straddle the main body tank 15 and the upper part thereof. The liquid supply auxiliary member 20 is formed with a liquid supply tank receiving part 21 and a float insertion part 22.

  The liquid supply tank receiving portion 21 has a flange shape, and includes a cylindrical portion and a bowl-shaped portion that spreads outward. As shown in FIG. 3, when the liquid supply tank 60 is attached to the housing 11, the second cylindrical portion 74 is located inside the cylindrical portion of the liquid supply tank receiver 21, and the liquid supply tank receiver The collar portion 75 comes into contact with the collar portion 21. In this way, the liquid supply tank receiving part 21 receives and supports the liquid supply tank 60 (liquid supply part 64). The liquid supply tank receiving portion 21 also has a function of holding the liquid overflowing from the main body tank 15.

  The float insertion part 22 is formed in the lower part of the liquid supply tank receiving part 21. Moreover, the float insertion part 22 is arrange | positioned so that at least one part may be located inside the main body container part 15a. The float insertion part 22 is a cylindrical part with a bottom plate formed on the lower side as shown in FIG. A float 30 is inserted into the float insertion portion 22. The diameter of the float insertion portion 22 is larger than the liquid supply port 72 and the first cylindrical portion 73 and smaller than the second cylindrical portion 74. As shown in FIG. 3, when the liquid supply tank 60 is attached to the housing 11, the first cylindrical portion 73 is located above the float insertion portion 22. A plurality of slits 22 a are formed on the side surface of the float insertion portion 22. The liquid supplied into the float insertion portion 22 through the liquid supply port 72 flows into the main body tank 15 through the slit 22a.

  In addition, although the liquid supply tank receiving part 21 and the float insertion part 22 have a different function, respectively, as a structure, the liquid supply auxiliary member 20 which is an integral member is configured by combining two (in other words, 1 The liquid supply auxiliary member 20, which is one member, is described separately from the liquid supply tank receiving portion 21 and the float insertion portion 22 from the viewpoint of function). Instead of this configuration, the liquid supply tank receiving portion 21 and the float insertion portion 22 may be configured as separate members, and these may be connected by bolts or snap fits.

  The float 30 is a member having a property of floating in a liquid such as a hollow structure, and is inserted into the float insertion portion 22. Accordingly, the float 30 is disposed below the liquid supply port 72 and the injection port 15b. Since the float insertion part 22 is located inside the main body container part 15a, the float 30 moves up and down according to the liquid level (water level, liquid level height) stored in the main body tank 15. However, since the bottom plate is formed in the float insertion part 22, the float 30 is configured not to lower below a predetermined level.

  The valve operating mechanism 40 is a member that operates the liquid supply valve 80 in accordance with the elevation of the float 30. The valve operation mechanism 40 is disposed below the liquid supply port 72 and the injection port 15b and above the float 30 (that is, disposed between the injection port 15b and the float 30). The valve operating mechanism 40 includes a rotating shaft member 41, a first opening / closing member 42, and a second opening / closing member 43. In the following description, “the first opening and closing member 42 and the second opening and closing member 43” may be referred to as “opening and closing members 42 and 43”.

  The rotary shaft member 41 is a columnar member, and is attached to the float insertion portion 22 so as to traverse the float insertion portion 22 in the radial direction (so that opposing positions of the float insertion portion 22 are connected to each other). Yes.

  The first opening / closing member 42 includes a shaft portion 101, a pressing portion 102, a weight portion 103, a stopper 104, and a float contact portion 105. The shaft portion 101 to the float contact portion 105 are integrally formed, but may be separate members connected to each other. The second opening / closing member 43 is a member that is symmetrical to the first opening / closing member 42, and includes a shaft portion 111, a pressing portion 112, a weight portion 113, a stopper 114, and a float contact portion 115. ing. Since each part of the second opening / closing member 43 has the same function and shape as the first opening / closing member 42, the first opening / closing member 42 will be described below.

  The shaft portion 101 is rotatably attached to the rotating shaft member 41. Moreover, since the press part 102 and the weight part 103 are connected to the axial part 101, the axial part 101-the float contact part 105 are comprised so that it may rotate integrally with respect to the rotating shaft member 41 (FIG. 3 and FIG. 4). In the following description, the state of the open / close members 42 and 43 shown in FIG. 3 is referred to as a closed state, and the state of the open / close members 42 and 43 shown in FIG. 4 is referred to as an open state.

  The pressing part 102 is a member that presses the contact surface 81 a of the liquid supply valve 80. As shown in FIG. 2, the pressing portion 102 has a pressing surface 102 a. The pressing surface 102a is a surface formed at the tip of a portion extending in one direction from the shaft portion 101 (portion extending upward in the closed state). Note that only one end of the pressing portion 102 is chamfered in a curved surface or an arc shape. When the liquid supply tank 60 is attached to the housing 11, the pressing surface 102 a contacts the contact surface 81 a and pushes the valve rod 81 upward.

  The weight part 103 is a part located mainly on the lower side of the shaft part 101 in the closed state. The weight part 103 is a weight for making it easy to be closed by its own weight when no external force is applied to the first opening / closing member 42.

  The stopper 104 is formed at a position overlapping the pressing portion 112 of the second opening / closing member 43 at the axial position of the rotary shaft member 41. When the opening / closing members 42 and 43 are in the open state, the stopper 104 contacts the pressing portion 112 and restricts rotation in order to prevent excessive rotation of the second opening / closing member 43.

  The float contact part 105 is an arc-shaped part constituting the lower part of the second opening / closing member 43. In the present embodiment, when viewed in the axial direction, the direction in which the pressing portion 102 is positioned with respect to the shaft portion 101 and the direction in which the float contact portion 105 is positioned are greater than a predetermined angle (for example, 90 degrees or more). , 180 degrees or less). As shown in FIGS. 2 and 3, the lower surface of the float contact portion 105 is in contact with the upper surface of the float contact portion 105.

  With the above configuration, when the float 30 is positioned below a predetermined level, the opening and closing members 42 and 43 are in the closed position due to their own weight. And the float 30 raises, the said float 30 presses the float contact part 105 and the float contact part 115 upwards. Thereby, the opening and closing members 42 and 43 are rotated to the open position.

  Next, the flow when supplying liquid to the main body tank 15 using the liquid supply tank 60 will be described with reference to FIG. FIG. 5 is a cross-sectional view showing how the open / close members 42 and 43 are opened and closed as the liquid level of the main body tank 15 rises.

  The liquid level of the main body tank 15 is lower than a predetermined level (low liquid level), and the float 30 is in contact with the bottom surface of the float insertion part 22 before the liquid supply tank 60 is attached. Therefore, since the float 30 does not push up the float contact portion 105, the open / close members 42 and 43 are closed due to their own weight.

  FIG. 5A is a diagram illustrating a state immediately after the liquid supply tank 60 is attached in a state where the main body tank 15 is at a relatively low predetermined liquid level. By attaching the liquid supply tank 60, the pressing surfaces 102a and 112a come into contact with the contact surface 81a to push the valve stem 81 upward. As a result, the liquid supply port 72 is opened, so that liquid is supplied from the liquid supply tank 60 to the main body tank 15 as shown by the arrow in FIG. Since the shaft 101 to the float contact portion 105 (particularly the pressing portion 102) is rotatably supported by the rotating shaft member 41, the reaction force of the force that pushes up the valve stem 81 upward is received by the rotating shaft member 41. ing. Since the float 30 is in contact with the lower surfaces of the opening and closing members 42 and 43, the opening and closing members 42 and 43 do not rotate even when a force is applied to the pressing surfaces 102a and 112a. Here, in this embodiment, since the replenishment part 63 which functions also as an air hole is formed in the upper part of the liquid supply tank 60, compared with the case where the liquid supply tank sealed except the liquid supply valve is used, The liquid can be supplied quickly.

  Thereafter, the liquid supply to the main body tank 15 is continued, and the main body tank 15 becomes a relatively high predetermined liquid level (high liquid level). Thereby, the float 30 presses the opening and closing members 42 and 43 upward. Thereby, the opening and closing members 42 and 43 rotate. Here, as described above, one of the pressing surfaces 102a and 112a (the end opposite to the rotation direction rotating from the closed state to the open state) is chamfered in a curved surface or an arc shape, so that the opening / closing member 42 , 43 can be easily rotated even in a situation where the members 43, 43 are pressed in the vertical direction. When the opening and closing members 42 and 43 are rotated, the contact surface 81a and the pressing surfaces 102a and 112a do not overlap when viewed in the vertical direction (up and down direction) (in other words, the pressing units 102 and 112 have a horizontal direction component). The pressing surfaces 102a and 112a are retracted from below the valve stem 81 by performing a movement including

  Thereby, the push-up of the liquid supply valve 80 by the pressing parts 102 and 112 is released. Thereby, since the liquid supply port 72 is closed, the liquid supply from the liquid supply tank 60 to the main body tank 15 can be automatically stopped with a mechanical configuration without using a power source. Therefore, it is possible to prevent the liquid from overflowing from the main body tank 15.

  After that, when the main body tank 15 becomes a low liquid level again, the float 30 descends and the open / close members 42 and 43 try to be closed, but the pressing portions 102 and 112 interfere with the valve stem 81, so that the closure is closed. It will not be in a state. Accordingly, liquid is not automatically supplied from the liquid supply tank 60 to the main body tank 15. Thereby, it can prevent that liquid supply is started again at the timing which a user does not intend.

  As described above, the liquid supply mechanism 10 of the present embodiment includes the main body tank 15, the liquid supply tank 60, the float 30, and the valve operation mechanism 40. The main body tank 15 is disposed inside the housing 11, stores liquid, and has an inlet 15b at the top. The liquid supply tank 60 is configured to be detachable from the housing 11, stores liquid for supplying liquid to the main body tank 15, and a liquid supply valve 80 (specifically, a valve rod 81) provided in the lower portion is upward. By being pushed up, the liquid supply port 72 opens and supplies liquid to the main body tank 15 through the injection port 15b. The float 30 is disposed below the inlet 15 b and moves up and down according to the liquid level of the main body tank 15. The valve operating mechanism 40 is disposed between the inlet 15b and the float 30, and a pressing unit 102 that pushes up the liquid supply valve 80 when the liquid supply tank 60 is attached while the liquid level of the main body tank 15 is below a predetermined level. 112, and the float 30 ascends with the liquid supply, so that the pressure of the liquid supply valve 80 (specifically, the valve rod 81) by the pressing portions 102 and 112 is released by receiving the force from the float 30. To work.

  Thereby, the liquid supply to the main body tank 15 by the liquid supply tank 60 can be automatically stopped with a compact configuration that does not require a power source. Moreover, since the valve operating mechanism 40 is disposed below the liquid supply port 72 of the main body tank 15, a highly versatile liquid supply mechanism that can be applied regardless of the shape of the main body container portion 15a can be realized.

  Next, a first modification and a second modification of the above embodiment will be described. In the description of the first modification and the second modification, the same or similar members as those in the above-described embodiment may be denoted by the same reference numerals in the drawings, and description thereof may be omitted.

  FIG. 6 is a schematic front view showing the configuration of the valve operating mechanism 120 according to the first modification. The valve operating mechanism 120 includes a first link 121, a second link 122, a third link 123, a fourth link 124, a first pressing portion 125, a second pressing portion 126, and a base member 127. It is configured. One end portions (lower end portions) of the first link 121 and the second link 122 are rotatably connected to the float 30. The other end of the first link 121 is rotatably connected to the third link 123. The other end of the second link 122 is rotatably connected to the fourth link 124.

  The third link 123 and the fourth link 124 are arranged so that the link longitudinal direction coincides with the horizontal direction. The third link 123 and the fourth link 124 are each formed with a long hole along the longitudinal direction of the link. Further, a first pressing portion 125 formed to extend upward is connected to the third link 123 so as not to rotate, and a second pressing portion 126 formed to extend upward is connected to the fourth link 124. It is connected non-rotatably.

  The base member 127 is fixed to a portion that does not operate with the float 30 and the valve operation mechanism 120 (for example, the float insertion portion 22). Two pins are formed on the base member 127. Both of these pins are inserted into the long holes of the third link 123 and the fourth link 124.

  With the above configuration, when the main body tank 15 has a low liquid level, the lower ends of the first link 121 and the second link 122 are positioned below, so that the third link 123 and the fourth link 124 are closer to the center. To position. Thereby, since the press parts 125 and 126 are located in the center, by attaching the liquid supply tank 60, the valve rod 81 can be pushed up and liquid supply can be started.

  In this state, when the main body tank 15 reaches a high liquid level, the lower ends of the first link 121 and the second link 122 are pushed upward, so that the third link 123 and the fourth link 124 spread outward in the horizontal direction. Moving. Thereby, the pressing parts 125 and 126 also move so as to spread outward in the horizontal direction. In other words, the contact surface (the lower surface of the valve stem 81) and the pressing surface (the upper surfaces of the pressing portions 125 and 126) do not overlap when viewed in the vertical direction (vertical direction). Thereby, the upward pressing of the valve stem 81 is released, and the liquid supply can be stopped.

  After that, when the main body tank 15 becomes a low liquid level again, the float 30 descends so that the pressing parts 125 and 126 move toward each other, but the pressing parts 125 and 126 interfere with the valve stem 81 and are closed. It will not be in a state. Accordingly, liquid is not automatically supplied from the liquid supply tank 60 to the main body tank 15. Thereby, it can prevent that liquid supply is started again at the timing which a user does not intend.

  FIG. 7 is a schematic front view showing the configuration of the valve operating mechanism 130 according to the second modification. The valve operating mechanism 130 is a known pantograph mechanism, and includes a first link 131, a second link 132, a third link 133, a fourth link 134, a fifth link 135, and a sixth link 136. Prepare.

  One ends (lower ends) of the first link 131 and the fourth link 134 are rotatably connected to the float 30. The other end of the first link 131 is rotatably connected to one end of the second link 132. The other end of the second link 132 is rotatably connected to one end of the third link 133. The other end of the fourth link 134 is rotatably connected to one end of the fifth link 135. The other end of the fifth link 135 is rotatably connected to one end of the sixth link 136. The other end of the third link 133 and the other end of the sixth link 136 are rotatably connected.

  Further, the first link 131, the third link 133, and the fifth link 135 are arranged so that the longitudinal direction of the link is substantially parallel, and the second link 132, the fourth link 134, and the sixth link 136 are The links are arranged so that their longitudinal directions are substantially parallel. The central portion of the second link 132 and the fifth link 135 is rotatably supported (fixed) by a support pin 137 on a portion that does not operate together with the float 30 and the valve operation mechanism 130 (for example, the float insertion portion 22). Yes.

  With the above configuration, when the main body tank 15 has a low liquid level, the lower ends of the first link 131 and the fourth link 134 are located below, so that the vertical distance between the links is widened. Thereby, since the 3rd link 133 and the 6th link 136 are located above, by attaching liquid supply tank 60, valve stem 81 can be pushed up and liquid supply can be started. Thus, in the 2nd modification, the 3rd link 133 and the 6th link 136 function also as a press part.

  In this state, when the main body tank 15 reaches a high liquid level, the lower ends of the first link 131 and the fourth link 134 are pushed upward, so that the vertical distance of each link moves so as to be narrowed. As a result, the third link 133 and the sixth link 136 move downward. In other words, while maintaining a state where the contact surface (the lower surface of the valve stem 81) and the pressing surface (the upper surfaces of the third link 133 and the sixth link 136) overlap each other when viewed in the vertical direction (vertical direction), The parts (the third link 133 and the sixth link 136) move downward. Thereby, the upward pressing of the valve stem 81 is released, and the liquid supply can be stopped.

  After that, when the main body tank 15 becomes a low liquid level again, the float 30 descends, so that the lower ends of the first link 131 and the fourth link 134 move downward, and the vertical distance between the links is increased. . Thereby, since the 3rd link 133 and the 6th link 136 move upward, the valve rod 81 can be pushed up and liquid supply can be started automatically. In other words, when viewed in the vertical direction, the pressing portion (the third link 133 is maintained while the contact surface (the lower surface of the valve stem 81) and the pressing surface (the upper surfaces of the third link 133 and the sixth link 136) are overlapped. When the link 133 and the sixth link 136) move upward, the liquid supply valve 80 is operated to push up again. By setting it as such a structure, since a press part hardly moves at all in a horizontal direction, the size in the horizontal direction of the valve operation mechanism 130 can be reduced.

  The preferred embodiments and modifications of the present invention have been described above, but the above configuration can be modified as follows, for example.

  In the above embodiment, the open / close members 42 and 43 are closed by their own weight, but may be configured to be closed by being biased by a biasing member such as a spring.

  In the above embodiment, the float 30 is located below the inlet 15b even in the case of a high liquid level, but at least a part thereof may protrude upward from the inlet 15b. However, even in this case, the float 30 is preferably located in the vicinity of the inlet 15b.

  In the above embodiment, when the main body tank 15 becomes the low liquid level again, the liquid supply is not started again. However, for example, the liquid supply is started again by making the contact surface 81a curved. it can. Similarly, also in the first modified example, when the main body tank 15 becomes a low liquid level again, the liquid supply can be started again. Further, in the second modification, it is also possible to adopt a configuration in which the liquid supply is not started again when the main body tank 15 becomes a low liquid level again.

  In the above embodiment, circular holes (injection port 15b, liquid supply port 72, etc.), cylindrical members / parts (liquid supply tank receiving unit 21, float insertion unit 22, float 30, first cylindrical unit 73, and first 2 cylindrical portions 74, etc.) all have the same central axis position, but at least one axis may be shifted from the other. The relationship between the diameters of these members may be different from that of the above embodiment. These members are not limited to a circular cross section, and may have a polygonal cross section.

DESCRIPTION OF SYMBOLS 10 Liquid supply mechanism 15 Main body tank 30 Float 40 Valve operation mechanism 60 Liquid supply tank 80 Liquid supply valve 81 Valve rod 81a Contact surface 102 Press part 102a Press surface

Claims (2)

A main body tank disposed inside the housing, storing liquid and having an inlet formed at the top;
It is configured to be detachable from the housing, stores a liquid for supplying liquid to the main body tank, and a liquid supply valve provided at a lower portion is pushed upward to open a liquid supply port, through the injection port. A liquid supply tank for supplying liquid to the main body tank;
A float that is arranged near or below the inlet, and that rises and falls according to the liquid level of the main body tank;
While having a pressing part that is disposed between the inlet and the float and pushes up the liquid supply valve by attaching the liquid supply tank in a state where the liquid level of the main body tank is not more than a predetermined level, A valve operating mechanism that operates so that the lift of the liquid supply valve by the pressing portion is released by receiving a force from the float by raising the float with liquid supply;
With
The valve operating mechanism is configured to release the liquid supply even when the liquid level of the main body tank is lowered again and the float is lowered after releasing the liquid supply valve from being pushed up by the pressing portion. A liquid supply mechanism that operates so as to maintain a state in which the push-up of the valve is released . The liquid supply mechanism according to claim 1,
In the liquid supply from the liquid supply tank to the main body tank, the contact surface formed on the liquid supply valve is in contact with the press surface formed on the pressing portion,
The valve operating mechanism is configured so that the contact surface and the pressing surface do not overlap when viewed in a vertical direction by raising the float from a state where the contact surface and the pressing surface are in contact with each other. The liquid supply mechanism, wherein the liquid supply valve is lifted by the pressing portion when released.

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