JP2017009369A - Liquid surface detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid surface detector that can prevent a float from contacting the inner wall of a tank when the float is being equipped in the tank.SOLUTION: The liquid surface detector detects the level of the surface of a liquid stored in a tank 10, and includes: a float 130 floating on a liquid surface; and a float arm 140 in the shape of a long and thin rod, having one end fixed to the float 130 and the other end rotatably supported by a supporting member 110 and rotating according to the float 130, which is vertically moved by variations in the liquid surface level; and a bypass unit 1410 at one end of the float arm 140, bypassing a position distant from at least a part of the region around the float 130.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a liquid level detection device that detects the height of a liquid level.

  As a conventional liquid level detection device, for example, the one described in Patent Document 1 is known. The liquid level detection device of Patent Document 1 is mounted in a tank in which liquid is stored, and floats (floats) floating on the liquid level in the tank, and holds the float, and responds to the vertical movement of the float. And a float arm (lever) that rotates.

  The float arm is formed from an elongated rod-like member. And the U-shaped part bent in the U-shape is formed in the front end side of a float arm, and the latching | locking part is formed in the front-end | tip part of the opening side of a U-shaped part. . On the other hand, a groove portion corresponding to the U-shaped portion is provided on the side surface of the float. Then, the opening side of the U-shaped part is expanded in the elastic deformation region, the float is inserted so that the U-shaped part enters the groove, and the locking part prevents the float from coming off from the float arm. Has been.

Japanese Utility Model Publication No. 56-1128

  However, when the conventional liquid level detection device is mounted in the tank, it is inserted from the opening of the tank with the float as the tip side. At this time, since the opening of the tank has a minimum size, the work cannot be performed while sufficiently observing the insertion state of the float in the tank.

  Therefore, when the liquid level detecting device is inserted into the tank, the float may come into contact with the inner wall of the tank, and the float may be chipped or damaged. If float breakage or scratches occur, the float characteristics of the float will deteriorate, or the fragments at the time of scratches will become foreign matter that will interfere with the sliding part when the float arm rotates. Problems can arise.

  In view of the above problems, an object of the present invention is to provide a liquid level detection device capable of preventing a float from coming into contact with an inner wall of a tank when mounted in the tank.

  In order to achieve the above object, the present invention employs the following technical means.

In the present invention, a liquid level detection device for detecting the liquid level height of the liquid stored in the tank (10),
A float (130) floating on the liquid surface;
A float which is formed in an elongated rod shape, has a float (130) fixed to one end side, and is supported rotatably on the other end side with respect to the support (110), and moves up and down by fluctuations in liquid level. A float arm (140) that rotates according to (130),
On one end side of the float arm (140), a detour portion (1410) that detours a position away from at least a part of the periphery of the float (130) is formed.

  According to the present invention, even when the float (130) interferes with the inner wall of the tank (10) when the liquid level detection device (100) is inserted and installed in the tank (10), the float (130) is floated. The detour portion (1410) comes into contact with the inner wall of the tank (10) before (130). Therefore, the float (130) can be prevented from coming into direct contact with the inner wall of the tank (10), and the float (130) can be prevented from being chipped or damaged.

  In addition, the code | symbol in the bracket | parenthesis of each said means shows a corresponding relationship with the specific means of embodiment description mentioned later.

It is explanatory drawing which shows the liquid level detection apparatus attached in a fuel tank. (A) which shows the float and float arm in 1st Embodiment is a perspective view, (b) is a front view. It is explanatory drawing which shows the point at the time of inserting a fuel pump module and a liquid level detection apparatus in a fuel tank. It is a perspective view which shows the modification 1 of a float and a float holding | maintenance part. It is a perspective view which shows the modification 2 of a float and a float holding | maintenance part. It is a perspective view which shows the modification 3 of a float and a float holding | maintenance part. It is a perspective view which shows the modification 4 of a float and a float holding | maintenance part.

  The liquid level detection apparatus 100 in 1st Embodiment is demonstrated using FIGS. 1-3. First, the configuration of the liquid level detection device 100 will be described.

  The liquid level detection device 100 is applied to a vehicle, and is attached (installed) in a fuel tank 10 that stores fuel as liquid as shown in FIG. The fuel tank 10 corresponds to the tank of the present invention. The liquid level detection device 100 is a device that detects the liquid level height of the fuel stored in the fuel tank 10 while being held by the fuel pump module 50.

  The fuel pump module 50 is a device that supplies fuel to the engine. For example, a fuel filtration filter, a fuel discharge pump, a pressure regulator for maintaining fuel pressure, and the like are provided in the cylindrical cup portion 51. It is housed and formed. The detection result detected by the liquid level detection device 100 is output to, for example, an ECU (electronic control device) of the combination meter, and is displayed to the driver by the combination meter as fuel remaining amount information.

  The liquid level detection device 100 includes a variable resistor, and a variable resistance type liquid level that detects the liquid level of the fuel by changing the resistance value of the variable resistor according to the change in the liquid level of the fuel. It is a detection device. The liquid level detection apparatus 100 includes a housing 110, an insulator 120, a float 130, a float arm 140, and the like.

  The housing 110 is a main body portion of the liquid level detection device 100 and is a support body that supports the insulator 120 and the float arm 140, and is formed of a resin material such as polyacetal (POM) resin. The housing 110 is attached to a predetermined portion of the peripheral surface of the cup portion 51 of the fuel pump module 50, and is fixed to the fuel tank 10 through the fuel pump module 50. The housing 110 is provided with a support portion that rotatably supports the insulator 120 and the float arm 140, a resistor for a variable resistor, and a stopper that regulates the rotational positions of the insulator 120 and the float arm 140.

  The insulator 120 is a plate-like member whose front shape is an oval shape, and is formed of a resin material such as POM resin, for example, like the housing 110. One end side in the longitudinal direction of the insulator 120 is rotatably supported by the support portion of the housing 110. In addition, an arm insertion hole 121 into which the pivot shaft (the other end side of the present invention) of the float arm 140 is inserted is provided on one end side in the longitudinal direction of the insulator 120. Further, a locking claw 122 for fixing the float arm 140 so as not to move with respect to the insulator 120 around the arm insertion hole 121 is provided at an intermediate portion in the longitudinal direction of the insulator 120. Therefore, the insulator 120 rotates with respect to the housing 110 integrally with the float arm 140.

  In addition, a sliding plate that contacts the resistor of the housing 110 is provided on the surface of the insulator 120 on the housing 110 side, and the position of contact with the resistor changes as the insulator 120 rotates, The resistance value of the resistor is changed. A variable resistor is formed by the resistor of the housing 110 and the sliding plate of the insulator 120.

  The rotating operation of the insulator 120 is such that the middle part (longer extending portion) of the float arm 140 is at the position on the minimum side of the liquid level that is substantially horizontal, and no further moves to the minimum side of the liquid level. The position is regulated by a stopper provided on the housing 110 side.

  As shown in FIG. 2, the float 130 is a rectangular plate-like member, and is formed of a material having a specific gravity smaller than that of a fuel such as foamed ebonite. The float 130 can float on the liquid level of the fuel. The float 130 is fixed to a float holding part 141 provided on one end side of the float arm 140.

  The main body 131 of the float 130 is formed with an insertion hole 132 that penetrates the center in the direction along the plate surface. Further, a groove 133 extending in the longitudinal direction of the side surface 1311 is formed on the side surface 1311 of the float 130 which is one opening side of the insertion hole 132. The cross-sectional shape of the groove 133 is a shape (semicircular shape) corresponding to about half of the cross-sectional shape of the float arm 140, and a part of the float arm 140 is fitted into the groove 133. .

  The float arm 140 is formed of an elongated round bar-shaped core made of a metal material such as stainless steel. A float holding portion 141 is formed on one end side in the longitudinal direction of the float arm 140, and a rotation shaft is formed on the other end side in the longitudinal direction. In the description of the shape of the float arm 140, for example, as shown in FIG. 2, an example is shown in which the intermediate portion of the float arm 140 extending from the insulator 120 is in a position extending in the horizontal direction. An intermediate portion of the float arm 140 extends so as to pass under the side surface 1312 facing the side surface 1311 of the float 130.

  The float holding part 141 is formed by bending one end side of the float arm 140. In this embodiment, the float holding part 141 is formed by a first bent part 1411, a second bent part 1412, a third bent part 1413, a fourth bent part 1414, and a fifth bent part 1415.

  The first bent portion 1411 is separated from the front end side of the intermediate portion of the float arm 140 by a predetermined amount L with respect to a virtual line along the longitudinal direction in a direction that is the maximum side of the liquid level, and from the float 130. It is a part that is bent obliquely upward so as to be separated.

  The second bent portion 1412 is a portion that extends from the distal end portion of the first bent portion 1411 so as to extend along the longitudinal direction of the side surface 1313 of the float 130. The side surface 1313 is a surface adjacent to the side surface 1311 and the side surface 1312, and is a surface corresponding to the tip side of the float 130 where the float arm 140 extends from the insulator 120 side. The length of the second bent portion 1412 is equal to the length of the side surface 1313 in the longitudinal direction. Further, the vertical position of the second bent portion 1412 is equal to or higher than the position of the upper surface of the float 130.

  The third bent portion 1413 is a portion bent obliquely downward from the tip end portion of the second bent portion 1412 toward the center position in the height direction of the side surface 1311 of the float 130.

  The fourth bent portion 1414 is a portion bent from the tip end portion of the third bent portion 1413 toward the float 130, along the side surface 1311, and to one opening portion of the insertion hole 132. ing. A part of the fourth bent portion 1414 is fitted in the groove portion 133 of the float 130.

  The fifth bent portion 1415 is a portion bent from the tip end portion of the fourth bent portion 1414 so as to penetrate the insertion hole 132 and protrude from the opening on the opposite side (the other side). A washer 142 is attached to the distal end portion of the fifth bent portion 1415 so as to contact the side surface 1312, and further, a crushed portion 143 in which the distal end portion of the fifth bent portion 1415 is crushed.

  As described above, the fourth bent portion 1414 is fitted into the groove portion 133, the fifth bent portion 1415 is inserted into the insertion hole 132, and the crushed portion 143 is formed at the distal end portion of the fifth bent portion 1415. The float 130 is fixed to the float holding part 141 without rotating with respect to the fifth bending part 1415.

  Here, among the bent portions 1411 to 1415, the detour portion 1410 is mainly formed by the first bent portion 1411 to the third bent portion 1413. The detour portion 1410 is a portion that is routed so as to detour at a position away from at least a part of the periphery of the float 130 (here, the side surfaces 1311 to 1313) on one end side of the float arm 140.

  On the other hand, the pivot axis of the float arm 140 is formed by bending the other end of the float arm 140 about 90 degrees in the direction along the axis of the arm insertion hole 121 of the insulator 120. The rotation shaft is inserted into the arm insertion hole 121 and is supported so as to be rotatable with respect to the housing 110 together with the insulator 120.

  Therefore, the float arm 140 converts the vertical movement of the float 130 accompanying the fluctuation of the liquid level into the rotational movement of the insulator 120 and changes the resistance value of the resistor in the housing 110.

  Next, a procedure for mounting the liquid level detection device 100 formed as described above into the fuel tank 10 will be described with reference to FIG.

  First, in the liquid level detection device 100 assembled to the fuel pump module 50, the position of the insulator 120 is regulated by the stopper of the housing 110 by rotating the float arm 140 with respect to the cup portion 51, so that the fuel tank When the posture within 10 is assumed, the positional relationship is set so as to be the minimum side of the liquid level (corresponding to FIG. 1).

  Next, the float 130 is inserted from the opening 11 of the fuel tank 10 so that the float 130 is on the lower side and the cup portion 51 is on the upper side, so that the middle part of the float arm 140 is inclined (white in FIG. 3). Arrow). And the float arm 140 and the cup part 51 are rotated in the opening part 11 so that the inclination of the intermediate part of the float arm 140 may become a horizontal direction one by one. As a result, the float 130 is sequentially moved to the bottom side away from the bottom of the fuel tank 10 corresponding to the opening 11, and the cup 51 is opened in an original mounting posture in which the cylindrical axis is directed in the vertical direction. It passes through the part 11 and is inserted. The cup 51 is fixed in position so as to ride on the bottom of the fuel tank 10.

  In the present embodiment, a bypass portion 1410 is provided on one end side of the float arm 140. Thus, even when the float 130 is interfered with the bottom (inner wall) of the fuel tank 10 when the liquid level detection device 100 is inserted and installed in the fuel tank 10 (contact in FIG. 3), The detour portion 1410 comes into contact with the bottom of the fuel tank 10 before the float 130. Therefore, the float 130 can be prevented from coming into direct contact with the bottom of the fuel tank 10, and chipping or scratching of the float 130 can be prevented.

  Further, the detour portion 1410 is formed so as to be positioned on the distal end side of the float 130 along the longitudinal direction of the float arm 140. This makes it possible to reliably protect the front end side of the float 130 that is likely to be interfered with in the direction of insertion into the fuel tank 10.

  Further, the detouring part 1410 is disposed away from the virtual line along the longitudinal direction of the float arm 140 by a predetermined amount L in the rotation direction that is the maximum side of the liquid level. As a result, when the detour portion 1410 hits the bottom of the fuel tank 10, a moment for rotation is likely to be generated, and the float arm 140 is likely to rotate in a direction corresponding to the higher liquid level. (Rotation in FIG. 3), the insertion work into the fuel tank 10 becomes easy.

(Modification 1)
A first modification to the first embodiment is shown in FIG. In the first modification, the shape of the float 130 is changed to a float 130A, and the shape of the float holding unit 141 is changed to a float holding unit 141A with respect to the first embodiment. Further, in place of the washer 142 and the crushing portion 143 for fixing the float 130A, locking portions 144 and 145 are provided.

  In the float 130A, the insertion hole 132 is abolished, and a groove 133 is formed on each of the side surface 1311 and the side surface 1312.

  The intermediate portion of the float arm 140 extends so as to correspond to the center position in the height direction of the side surface 1312 of the float 130A. A locking portion 144 bent in a crank shape for locking the float 130 </ b> A is formed on the distal end side of the intermediate portion of the float arm 140. Further, the distal end side of the locking portion 144 is formed in the groove portion 133 of the side surface 1312. It is inset. And the float holding | maintenance part 141A in the float arm 140 is formed of the site | part inserted in the groove part 133 of the side surface 1312, and the 1st bending part 1411-the 4th bending part 1414.

  The first bent portion 1411 is separated from the distal end side of the intermediate portion of the float arm 140 by a predetermined amount L1 in the direction that is the maximum side of the liquid level with respect to the virtual line along the longitudinal direction, and from the float 130A. It is a part that is bent obliquely upward so as to be separated.

  The second bent portion 1412 is a portion extending from the tip end portion of the first bent portion 1411 so as to extend along the longitudinal direction of the side surface 1313 of the float 130A. The length of the second bent portion 1412 is equal to the length of the side surface 1313 in the longitudinal direction. The vertical position of the second bent portion 1412 is equal to or higher than the position of the upper surface of the float 130A.

  The third bent portion 1413 is a portion that is bent obliquely downward from the distal end portion of the second bent portion 1412 toward the center position in the height direction of the side surface 1311 of the float 130A.

  The fourth bent portion 1414 is a portion bent from the tip end portion of the third bent portion 1413 so as to extend along the side surface 1311. The fourth bent portion 1414 is fitted in the groove portion 133 of the side surface 1311.

  A locking portion 144 that is bent into a hook shape for locking the float 130A is formed on the distal end side of the fourth bending portion 1414.

  As described above, in the first modification, the detour portion 1410 is mainly formed by the first bent portion 1411 to the third bent portion 1413, and the same effects as in the first embodiment can be obtained.

  Moreover, in the modification 1, the opening side of the U-shaped part of the float holding | maintenance part 141A is expanded in an elastic deformation area | region, and the float 130 is inserted and assembled | attached in a U-shaped part. After assembly, the float 130 is locked by the locking portions 144 and 145. Therefore, the washer 142 and the crushing part 143 (crushing process) as in the first embodiment can be eliminated.

(Modification 2)
A second modification to the first embodiment is shown in FIG. In the second modification, the shape of the float 130 is changed to the float 130B, and the shape of the float holding unit 141 is changed to the float holding unit 141B with respect to the first embodiment.

  In the float 130 </ b> B, the groove 133 on the side surface 1311 is abolished, and the groove 133 is formed on the side surface 1312. The insertion hole 132 is formed in the same manner as the float 130.

  The intermediate portion of the float arm 140 corresponds to the center position in the height direction of the side surface 1312 of the float 130B, and extends to a position away from the side surface 1312. And the float holding | maintenance part 141B in the float arm 140 is formed of the 1st bending part 1411-the 5th bending part 1415. FIG.

  The first bent portion 1411 is separated from the front end side of the intermediate portion of the float arm 140 by a predetermined amount L1 in a direction that is the maximum side of the liquid level with respect to the virtual line along the longitudinal direction, and obliquely upward. It is a bent part.

  The second bent portion 1412 is a portion extending from the tip end portion of the first bent portion 1411 so as to extend along the longitudinal direction of the side surface 1313 of the float 130B. The length of the second bent portion 1412 is equal to the length from the intermediate portion of the float arm 140 to the side surface 1312. Further, the vertical position of the second bent portion 1412 is equal to or higher than the position of the upper surface of the float 130B.

  The third bent portion 1413 is a portion bent obliquely downward from the tip end portion of the second bent portion 1412 toward the center position in the height direction of the side surface 1312 of the float 130B.

  Further, the fourth bent portion 1414 is a portion bent so as to extend along the side surface 1312 from the distal end portion of the third bent portion 1413. The fourth bent portion 1414 is fitted in the groove portion 133 of the side surface 1312.

  The fifth bent portion 1415 is a portion bent from the tip end portion of the fourth bent portion 1414 so as to penetrate the insertion hole 132 and protrude from the opening portion of the side surface 1311. A washer is attached to the distal end portion of the fifth bent portion 1415 so as to abut on the side surface 1311, and further, a crushed portion 143 in which the distal end portion of the fifth bent portion 1415 is crushed.

  As described above, in the second modification, the detour portion 1410 is mainly formed by the first bent portion 1411 to the third bent portion 1413, and the same effect as in the first embodiment can be obtained.

(Modification 3)
A third modification to the first embodiment is shown in FIG. In the third modification, the shape of the float 130 is changed to the float 130C and the shape of the float holding unit 141 is changed to the float holding unit 141C with respect to the first embodiment.

  In the float 130C, the insertion hole 132 is formed so as to penetrate the center of the float 130C from the side surface 1313 side toward the side surface 1314 side. Further, the groove portion 133 on the side surface 1311 is abolished, and the groove portion 133 is formed on the side surface 1312.

  The intermediate portion of the float arm 140 extends so as to correspond to the center position in the height direction of the side surface 1312 of the float 130. The front end side of the intermediate portion of the float arm 140 is fitted into the groove portion 133 of the side surface 1312. And the float holding | maintenance part 141C in the float arm 140 is formed of the site | part inserted in the groove part 133 of the side surface 1312, and the 1st bending part 1411-the 4th bending part 1414.

  The first bent portion 1411 is separated from the front end side of the intermediate portion of the float arm 140 by a predetermined amount L1 in a direction that is the maximum side of the liquid level with respect to the virtual line along the longitudinal direction, and obliquely upward. It is a bent part.

  The second bent portion 1412 is a portion extending from the tip end portion of the first bent portion 1411 so as to extend along the longitudinal direction of the side surface 1313 of the float 130C. The length of the second bent portion 1412 is a length corresponding to half of the side surface 1313 in the longitudinal direction. The vertical position of the second bent portion 1412 is equal to or higher than the position of the upper surface of the float 130C.

  The third bent portion 1413 is a portion bent obliquely downward from the tip end portion of the second bent portion 1412 toward the center position in the height direction of the side surface 1313 of the float 130C.

  The fourth bent portion 1414 is a portion bent from the distal end portion of the third bent portion 1413 so as to penetrate the insertion hole 132 and protrude from the opening on the side surface 1314 side. A washer 142 is attached to the distal end portion of the fourth bent portion 1414 so as to abut on the side surface 1314, and further, a crushed portion 143 in which the distal end portion of the fourth bent portion 1414 is crushed.

  As described above, in the third modification, the bypass portion 1410 is mainly formed by the first bent portion 1411 to the third bent portion 1413, and the same effect as in the first embodiment can be obtained.

(Modification 4)
A modification 4 to the first embodiment is shown in FIG. In the fourth modification, the shape of the float 130 is changed to a float 130B and the shape of the float holding unit 141 is changed to a float holding unit 141D with respect to the first embodiment. The float 130B is the same as the second modification.

  An intermediate portion of the float arm 140 extends so as to correspond to the center position in the height direction of the side surface 1312 of the float 130B. The front end side of the intermediate portion of the float arm 140 is fitted into the groove portion 133 of the side surface 1312. And the float holding | maintenance part 141D in the float arm 140 is formed of the site | part inserted in the groove part 133 of the side surface 1312, and the 1st bending part 1411-the 3rd bending part 1413. FIG.

  The first bent portion 1411 is a portion bent from the distal end side of the intermediate portion of the float arm 140 so as to penetrate the insertion hole 132 and protrude from the opening on the side surface 1311 side.

  The second bent portion 1412 is separated from the tip end portion of the first bent portion 1411 by a predetermined amount L2 in a direction that is the maximum side of the liquid level with respect to a virtual line along the longitudinal direction of the intermediate portion of the float arm 140. And it is the site | part bent diagonally upward so that it may leave | separate from the float 130B (side surface 1313).

  The third bent portion 1413 is a portion bent from the distal end portion of the second bent portion 1412 in a direction toward the side surface 1314 opposite to the side surface 1313. The vertical position of the third bent portion 1413 is the same as or higher than the position of the upper surface of the float 130B.

  As described above, in the modified example 4, the detour portion 1410 is mainly formed by the second bent portion 1412 and the third bent portion 1413, and the same effect as in the first embodiment can be obtained.

  Moreover, in the modification 4, when the 1st bending part 1411 is formed in the float arm 140, it passes through the insertion hole 132 of the float 130B, and after that, the 2nd bending part 1412 and the 3rd bending part 1413 are formed. Thus, the float 130B is held on the float arm 140. Therefore, the washer 142 and the crushing part 143 (crushing process) as in the first embodiment can be eliminated.

(Other embodiments)
As mentioned above, although embodiment containing the modifications 1-4 by this invention was described, this invention is limited to the said embodiment and is not interpreted and various implementation is performed within the range which does not deviate from the summary of this invention. Applicable to forms and combinations.

  In the above-described embodiment, the detour portion 1410 of the float arm 140 is liquid level with respect to the virtual line along the longitudinal direction of the float arm 140 on the tip side of the float 130 along the longitudinal direction of the float arm 140 with respect to the float 130. It was arranged at a position separated by a predetermined amount (L, L1, L2) in the rotation direction which is the maximum height side.

  However, the bypass unit 1410 is arranged at a position away from at least a part of the periphery of the float 130 according to the insertion direction, the insertion angle, the shape of the fuel tank 10 or the like of the liquid level detection device 100 into the fuel tank 10. be able to.

  For example, the detour portion 1410 may be arranged on the side surface in the intersecting direction with respect to the distal end side in the longitudinal direction of the float arm 140.

  Further, the detour portion 1410 may be disposed on the extension line in the longitudinal direction of the float arm 140. Further, the detour portion 1410 may be arranged at a position away from the virtual line along the longitudinal direction of the float arm 140 by a predetermined amount in the rotation direction that is the minimum side of the liquid level.

  Moreover, in the said embodiment, although applied to the variable resistance type liquid level detection apparatus 100 using a variable resistor, it is not restricted to this, Hall IC element is arrange | positioned in a non-contact between a pair of magnets. Thus, the present invention may be applied to a non-contact type liquid level detecting device that detects the liquid level height based on a change in magnetic flux density in the Hall IC.

  Further, the present invention has been described based on an example in which the present invention is applied to a vehicle level detecting device for detecting the remaining amount of fuel. However, the application target of the present invention is not limited to such a liquid level detection device, but is a liquid level detection device in a container such as other fluids mounted on a vehicle, such as brake fluid, engine cooling water, and engine oil. May be. Furthermore, the present invention is applicable not only to vehicles but also to liquid level detection devices provided in liquid containers included in various consumer devices and various transport machines.

10 Fuel tank (tank)
100 Liquid Level Detection Device 110 Housing (Support)
130 Float 140 Float arm 1410 Detour

Claims (3)

A liquid level detection device for detecting a liquid level height of a liquid stored in a tank (10),
A float (130) floating on the liquid surface;
The float (130) is fixed to one end side, and is supported so as to be rotatable with respect to the support (110), and is moved up and down by the fluctuation of the liquid level. A float arm (140) that rotates according to the float (130)
The liquid level detection device according to claim 1, wherein a detour portion (1410) that detours a position away from at least a part of the periphery of the float (130) is formed on the one end side of the float arm (140).   The liquid level detection device according to claim 1, wherein the bypass portion (1410) is formed on a distal end side of the float (130) along a longitudinal direction of the float arm (140).   The detour portion (1410) is disposed a predetermined amount (L) away from the virtual line along the longitudinal direction of the float arm (140) in the rotation direction that is the maximum side of the liquid level. The liquid level detection device according to claim 2.

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