EP3514775A1 - Fire sensor base and fire sensor - Google Patents
Fire sensor base and fire sensor Download PDFInfo
- Publication number
- EP3514775A1 EP3514775A1 EP17850698.6A EP17850698A EP3514775A1 EP 3514775 A1 EP3514775 A1 EP 3514775A1 EP 17850698 A EP17850698 A EP 17850698A EP 3514775 A1 EP3514775 A1 EP 3514775A1
- Authority
- EP
- European Patent Office
- Prior art keywords
- bottom portion
- fire detector
- wall
- connection terminal
- base
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 110
- NJPPVKZQTLUDBO-UHFFFAOYSA-N novaluron Chemical compound C1=C(Cl)C(OC(F)(F)C(OC(F)(F)F)F)=CC=C1NC(=O)NC(=O)C1=C(F)C=CC=C1F NJPPVKZQTLUDBO-UHFFFAOYSA-N 0.000 claims abstract description 31
- 230000000149 penetrating effect Effects 0.000 claims description 3
- 238000012790 confirmation Methods 0.000 description 9
- 239000002184 metal Substances 0.000 description 8
- 239000000779 smoke Substances 0.000 description 7
- 210000000078 claw Anatomy 0.000 description 6
- 230000008878 coupling Effects 0.000 description 6
- 238000010168 coupling process Methods 0.000 description 6
- 238000005859 coupling reaction Methods 0.000 description 6
- 238000010276 construction Methods 0.000 description 5
- 230000003287 optical effect Effects 0.000 description 5
- 239000000758 substrate Substances 0.000 description 4
- 241000238631 Hexapoda Species 0.000 description 3
- 238000003780 insertion Methods 0.000 description 3
- 230000037431 insertion Effects 0.000 description 3
- 239000007769 metal material Substances 0.000 description 1
- 238000000034 method Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 239000002245 particle Substances 0.000 description 1
- 230000002093 peripheral effect Effects 0.000 description 1
- 238000003825 pressing Methods 0.000 description 1
Images
Classifications
-
- G—PHYSICS
- G08—SIGNALLING
- G08B—SIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
- G08B17/00—Fire alarms; Alarms responsive to explosion
- G08B17/10—Actuation by presence of smoke or gases, e.g. automatic alarm devices for analysing flowing fluid materials by the use of optical means
- G08B17/11—Actuation by presence of smoke or gases, e.g. automatic alarm devices for analysing flowing fluid materials by the use of optical means using an ionisation chamber for detecting smoke or gas
- G08B17/113—Constructional details
Definitions
- This invention relates generally to a fire detector base and a fire detector, and more particularly relates to a fire detector base with a circumference wall having a tubular shape, and a fire detector with the fire detector base.
- the fire detector disclosed in the Patent Literature 1 includes a base (a fire detector base) to be attached to a construction surface, and a main body (a detector body) attached on the floor side with respect to the base (i.e., the downside of the base).
- the main body has a cover shaped into a disk plate.
- the cover is provided so as to cover a bowl-shaped bottom wall of the main body.
- the cover is provided on an upper surface thereof with a descending part, formed so as to descend from the vicinity of the central part of the cover to the outer peripheral part thereof. That is, the descending part is inclined by a prescribed angle with respect to the construction surface.
- the main body is provided in the bottom wall thereof with a water discharge groove formed so as to surround the cover.
- the water discharge groove has a drain hole penetrating the bottom wall. Accordingly, when water is on the upper surface of the cover, the water is guided into the water discharge groove, thereby being discharged from the drain hole to the outside of the main body.
- the fire detector disclosed in the Patent Literature 1 cannot guide, when water is on an upper surface (a first surface) of the bottom wall of the base, the water in the base to discharge the water to the outside of the fire detector.
- Patent Literature 1 JP 2013-8082 A
- An object of the present invention is to provide a fire detector base and a fire detector, which, when water is on a first surface of a bottom wall of the fire detector base, can guide the water in the fire detector base to discharge the water to the outside of the fire detector.
- a fire detector base includes a pedestal.
- the pedestal is for attaching thereto a detector body of a fire detector configured to detect fire.
- the pedestal includes a bottom wall and a circumference wall.
- the circumference wall has a tubular shape.
- the circumference wall protrudes from a circumferential edge of the bottom wall.
- the bottom wall has a first surface and a second surface.
- the first surface and the second surface are disposed opposite to each other along a protruding direction of the circumference wall.
- the circumference wall includes an end in the protruding direction of the circumference wall, the end being closer to the first surface than the second surface in the protruding direction.
- the pedestal further includes a water collecting surface and a hole.
- the water collecting surface is adjacent to the first surface in a direction orthogonal to the protruding direction.
- the hole penetrates from the water collecting surface to an outside of the pedestal.
- the first surface includes an inclined surface.
- the inclined surface is inclined to be closer to the second surface at its end adjacent to the water collecting surface than at its end remote from the water collecting surface along the direction orthogonal to the protruding direction.
- a fire detector according to an aspect of the present invention includes the fire detector base and the detector body.
- FIG. 1 is a cross-sectional view taken along line A-A in FIG. 3 .
- respective sides on which a fire detector base 2 and a detector body 3 of a fire detector 1 shown in FIG. 1 are located are referred to as an "upside” and a “downside", for example.
- the fire detector 1 As shown in FIG. 2 , the fire detector 1 according to the present embodiment is attached to a construction surface 500.
- the fire detector 1 includes the fire detector base 2 and the detector body 3.
- the fire detector base 2 is configured such that an external wiring 600 passing through a hole formed in the construction surface 500 is inserted thereinto.
- the detector body 3 includes a casing 300, a cover 310, an electric circuit 320, an optical base 330 and an insect proof cover 340.
- the fire detector base 2 includes a pedestal 4, two or more external connection units 5 (six in the example of the drawing), and two or more contact parts 6 (three in the example of the drawing).
- the pedestal 4 includes a lower base 8 and an upper base 7. The upper base 7 is attached so as to cover a second bottom portion 80 of the lower base 8 (refer to FIG. 5 ).
- the lower base 8 includes the second bottom portion 80 with a disk shape, a first circumference wall 82 (circumference wall) with a cylindrical shape, and a second circumference wall 83 with a cylindrical shape (refer to FIGS. 7 and 8 ).
- the second bottom portion 80 has a second upper surface 84 and a second lower surface 85 (refer to FIG. 7 ).
- the second lower surface 85 is positioned on the opposite side of the second bottom portion 80 to the second upper surface 84.
- the second upper surface 84 and second lower surface 85 have annular shapes.
- the second bottom portion 80 further has a circle-shaped opening 86 in the center in a radial direction thereof. The opening 86 is concentric with the second upper surface 84.
- the second bottom portion 80 further has a projecting base 92 adjacent to a circumferential edge 840 of the second upper surface 84.
- the projecting base 92 has an annular shape, and disposed around the second upper surface 84. The projecting base 92 projects upward with respect to the second upper surface 84.
- the first circumference wall 82 protrudes upward from the second bottom portion 80.
- the second circumference wall 83 protrudes downward from the second bottom portion 80.
- the first circumference wall 82 and second circumference wall 83 are concentric with each other, when viewed along an up-down direction.
- the first circumference wall 82 is slightly larger in diameter than the second circumference wall 83.
- the first circumference wall 82 protrudes from a circumferential edge 81 of the second bottom portion 80 (refer to FIG. 8 ).
- the first circumference wall 82 is inscribed in a circumferential edge 920 of the projecting base 92.
- the second circumference wall 83 protrudes from a position slightly inside the first circumference wall 82 in the radial direction of the second bottom portion 80. More specifically, when viewed along the up-down direction, the second circumference wall 83 is at a position of partially overlapping with the projecting base 92.
- the second circumference wall 83 includes in an outside surface 830 thereof three recessed parts 831.
- Each recessed part 831 of the second circumference wall 83 is recessed inward in a radial direction of the second circumference wall 83.
- the second circumference wall 83 further includes in the outside surface 830 thereof six recesses 832.
- Each recess 832 of the second circumference wall 83 is recessed inward in the radial direction of the second circumference wall 83.
- One of the three recessed parts 831 is provided as integrally communicated with three of the six recesses 832.
- the other one of the three recessed parts 831 is provided as integrally communicated with the other two of the six recesses 832.
- the remaining one of the three recessed parts 831 is provided as integrally communicated with the remaining one of the six recesses 832.
- the first circumference wall 82 further includes three knockout parts 87.
- Each knockout part 87 includes a wall portion 870 and two side portions 871.
- the first circumference wall 82 has an end 820 in a protruding direction 821 (upward) in which the first circumference wall 82 is protruded (refer to FIG. 1 ), and each side portion 871 is provided to extend from the end 820 in the protruding direction 821. That is, the side portions 871 are extended from the end 820 toward the second bottom portion 80 (i.e., downward).
- Each side portion 871 has a width along a circumferential direction of the first circumference wall 82.
- the wall portion 870 is disposed between the two side portions 871.
- the wall portion 870 is adjacent to the two side portions 871.
- the wall portion 870 is provided integrally with the two side portions 871.
- the knockout part 87 is surrounded in all directions by a first edge 872 as an upside edge, a second edge 873 as a downside edge, a third edge 874 and a fourth edge 875.
- the third edge 874 and fourth edge 875 each connects the first edge 872 and the second edge 873.
- the first edge 872 is included in the end 820 of the first circumference wall 82.
- the second edge 873 is substantially linear to be in parallel to the first edge 872.
- Each of the third edge 874 and fourth edge 875 is an edge on the opposite side of a corresponding side portion 871 to the wall portion 870.
- the whole of the second edge 873, third edge 874 and fourth edge 875 has a substantially U-shape, when viewed from the radial direction of the first circumference wall 82. More specifically the second edge 873 and third edge 874 are curved into arc-shapes at near an intersection point 876 at which they intersect with each other. Similarly the second edge 873 and fourth edge 875 are curved into arc-shapes at near an intersection point 877 at which they intersect with each other.
- Each side portion 871 has an edge 878 on the side of the wall portion 870. The edge 878 passes through a corresponding intersection point (876 or 877).
- the knockout part 87 is provided such that the inside and outside thereof in the radial direction of the first circumference wall 82 are recessed with respect to a portion around the knockout part 87, of the first circumference wall 82. Accordingly, the knockout part 87 is smaller in thickness than the portion around the knockout part 87, of the first circumference wall 82. Furthermore, the side portion 871 has an inner surface 879 in the radial direction of the first circumference wall 82, and the inner surface 879 is recessed outward in the radial direction of the first circumference wall 82 with respect to the wall portion 870. For that reason, the side portion 871 is smaller in thickness than the wall portion 870.
- the lower base 8 further includes four projected parts 88 that are projected upward from the vicinity of the projecting base 92 on the second upper surface 84 of the second bottom portion 80.
- the four projected parts 88 are arranged at equal intervals along a circumferential direction of the second bottom portion 80.
- Each projected part 88 includes a columnar part 880 with a rectangular parallelepiped shape, protruded from the second bottom portion 80, and a claw part 881 provided near an end in a protruding direction (upward), of the columnar part 880.
- the columnar part 880 has elasticity capable of warping outward in the radial direction of the second bottom portion 80.
- the claw part 881 is protruded from the columnar part 880 inward in the radial direction of the second bottom portion 80.
- the lower base 8 further includes two projected parts 89 that are projected upward from the second upper surface 84 of the second bottom portion 80.
- Each projected part 89 has a tubular shape.
- the projected part 89 is provided between the opening 86 and the projecting base 92.
- the two projected parts 89 face each other so that the opening 86 is interposed therebetween.
- Each projected part 89 has an elliptic shape long in the radial direction of the second bottom portion 80, when viewed along the up-down direction.
- the projected part 89 also has in the inside thereof an opening 890, when viewed along the up-down direction.
- the lower base 8 further includes two projected parts 90 that are projected upward from the second upper surface 84 of the second bottom portion 80.
- the respective two projected parts 90 correspond to the two projected parts 89 in one-to-one.
- Each projected part 90 is provided between a corresponding projected part 89 and the opening 86 in the second bottom portion 80.
- the projected part 90 includes a columnar part 900 with a rectangular parallelepiped shape, protruded from the second bottom portion 80, and a claw part 901 provided near an end in a protruding direction (upward), of the columnar part 900. That is, the projected part 90 has a shape similar to that of the projected part 88.
- the columnar part 900 has elasticity capable of warping inward in the radial direction of the second bottom portion 80.
- the claw part 901 is protruded from the columnar part 900 outward in the radial direction of the second bottom portion 80.
- the upper base 7 includes a first bottom portion 70 with a disk shape (refer to FIG. 3 ) and a circumference wall portion 701 protruded downward from a circumferential edge 71 of the first bottom portion 70, and the upper base 7 therefore has a disk shape as a whole.
- the first bottom portion 70 has a first upper surface 74 with an annular shape (refer to FIG. 3 ) and a first lower surface 75 with an annular shape. As shown in FIG. 1 , the first upper surface 74 is positioned on the opposite side of the first bottom portion 70 to the first lower surface 75.
- the first bottom portion 70 of the upper base 7 is attached to the second bottom portion 80 in a state where the first lower surface 75 of the first bottom portion 70 faces the second upper surface 84 of the second bottom portion 80 of the lower base 8.
- the first bottom portion 70 faces the second bottom portion 80 in the protruding direction 821 of the first circumference wall 82.
- the end 820 of the first circumference wall 82 is closer to the first upper surface 74 than the second lower surface 85 in the protruding direction 821.
- the first bottom portion 70 of the upper base 7 is slightly smaller in diameter than the first circumference wall 82 of the lower base 8, and disposed in an inside space of the first circumference wall 82.
- the first upper surface 74 of the first bottom portion 70 is disposed in the inside space of the first circumference wall 82.
- the circumference wall portion 701 of the upper base 7 is placed on an upper face 93 (refer to FIG. 6 ) of the projecting base 92 (refer to FIG. 6 ) of the second bottom portion 80.
- the fire detector includes an isolator (not shown) that is provided in a space 700 formed between the first bottom portion 70 and the second bottom portion 80.
- the isolator has a function of detecting short-circuiting in the fire detector 1 and electrically cutting off the short-circuiting.
- the fire detector has a gap 94 between the circumference wall portion 701 and the first circumference wall 82. As shown in FIG.
- the upper face 93 of the projecting base 92 is adjacent to the first upper surface 74 in a direction orthogonal to the protruding direction 821 (refer to FIG. 1 ) of the first circumference wall 82.
- the direction orthogonal to the protruding direction 821 of the first circumference wall 82 corresponds to a radial direction of the first bottom portion 70.
- a surface including the upper face 93 of the projecting base 92 is referred to as a "water collecting surface 742".
- the water collecting surface 742 is disposed in the inside space of the first circumference wall 82.
- the gap 94 corresponds to a "groove” surrounded by the water collecting surface 742, the first circumference wall 82 and the circumference wall portion 701. That is, since the circumference wall portion 701 protruded from the first bottom portion 70 is placed on the upper face 93 of the water collecting surface 742 as described above, the gap 94 has a groove-shape, a bottom of which is a portion between the first circumference wall 82 and the circumference wall portion 701, of the water collecting surface 742.
- the gap 94 has the groove-shape, recessed with respect to the first upper surface 74 (that corresponds to a first surface 44 described later), and constituted by the water collecting surface 742, the first circumference wall 82 and the circumference wall portion 701.
- the first circumference wall 82 is inscribed in the circumferential edge 920 of the projecting base 92, and the first upper surface 74 is disposed in the inside space of the first circumference wall 82. Therefore, a part along the circumferential edge 920, of the water collecting surface 742, surrounds the first upper surface 74. In other words, at least a part of the water collecting surface 742 surrounds the first upper surface 74 (that corresponds to the first surface 44 described later).
- the water collecting surface 742 has therein three holes 95.
- the projecting base 92 is projected with respect to the second upper surface 84 so as to avoid a region where each hole 95 is provided.
- the respective three holes 95 correspond to the three recessed parts 831 of the second circumference wall 83 in one-to one.
- Each hole 95 is provided at the same location as a corresponding recessed part 831, when viewed along the up-down direction. More specifically the hole 95 penetrates the second bottom portion 80 and the second circumference wall 83 from the upper face 93 (refer to FIG. 5 ) of the projecting base 92 (refer to FIG. 5 ) to the corresponding recessed part 831.
- the hole 95 penetrates from the water collecting surface 742 to the outside of the second circumference wall 83 in the radial direction of the second bottom portion 80.
- the hole 95 penetrates from the water collecting surface 742 to an outside of the pedestal 4.
- the "outside" of the pedestal 4 mentioned herein means a space outside the inside space of the first circumference wall 82.
- the three holes 95 are arranged at substantially equal intervals along the radial direction of the second bottom portion 80.
- the water collecting surface 742 further has therein one hole 96.
- the projecting base 92 (refer to FIG 5 ) is projected with respect to the second upper surface 84 (refer to FIG. 5 ) so as to avoid a region where the hole 96 is provided.
- the hole 96 is larger in width than the second circumference wall 83 in the radial direction of the second bottom portion 80.
- the hole 96 penetrates the second bottom portion 80 from the upper face 93 (refer to FIG. 5 ) of the projecting base 92 to the second lower surface 85 in a region partially overlapping with the second circumference wall 83, when viewed along the up-down direction.
- the hole 96 as shown in FIG. 1 , penetrates the second circumference wall 83 along the radial direction of the second circumference wall 83 on the side of the second lower surface 85. In other words, the hole 96 penetrates from the water collecting surface 742 to the outside of the pedestal 4.
- the pedestal 4 includes the upper base 7 and the lower base 8. Accordingly, the pedestal 4 includes a bottom wall 40 that includes the first bottom portion 70 of the upper base 7 and the second bottom portion 80 of the lower base 8.
- the bottom wall 40 includes the first upper surface 74 of the first bottom portion 70.
- a surface including the first upper surface 74 is referred to as the "first surface 44" of the bottom wall 40.
- the first surface 44 in the present embodiment corresponds to the first upper surface 74.
- the bottom wall 40 further includes the second surface 45.
- the second surface 45 is disposed opposite to the first surface 44 along the protruding direction 821.
- the second surface 45 includes the second lower surface 85 of the second bottom portion 80.
- the second surface 45 in the present embodiment corresponds to the second lower surface 85.
- the first upper surface 74 includes a flat surface 744 and an inclined surface 745 inclined to the flat surface 744. More specifically the inclined surface 745 is inclined to be closer to the second surface 45 at its end adjacent to the water collecting surface 742 (refer to FIG. 3 ) than at its end remote from the water collecting surface 742 along the direction (the radial direction of the first bottom portion 70) orthogonal to the protruding direction 821. As shown in FIG 3 , the first bottom portion 70 further has a circle-shaped opening 76 in the center in a radial direction thereof. The opening 76 is concentric with the circumferential edge 71 of the first bottom portion 70. The inclined surface 745 is provided around the opening 76, and has an annular shape concentric with the circumferential edge 71.
- the inclined surface 745 is shaped like a side surface of a truncated cone.
- the flat surface 744 is provided around the inclined surface 745, and has an annular shape concentric with the circumferential edge 71.
- the flat surface 744 is formed integrally with the inclined surface 745 and continuously from the inclined surface 745 to the circumferential edge 71 of the first bottom portion 70 in the radial direction of the first bottom portion 70.
- the first upper surface 74 is provided without a projection (e.g., surrounding the inclined surface 745 and having a relatively long projection length with respect to the first upper surface 74).
- the upper base 7, as shown in FIGS. 3 and 4 further includes four projected parts 77 projected from the vicinity of the circumferential edge 71 on the first upper surface 74 of the first bottom portion 70.
- the four projected parts 77 are arranged at equal intervals along the circumferential direction of the first bottom portion 70.
- Each projected part 77 is shaped like a tubular shape and has an opening 771 inside thereof, when viewed along the up-down direction.
- the projected part 77 further has a recess 772 inside thereof in the radial direction of the first bottom portion 70.
- the recess 772 is recessed downward.
- Each projected part 77 is configured such that a corresponding projected part 88 of the lower base 8 is fitted thereinto.
- the recess 772 is configured such that the claw part 881 (refer to FIG. 6 ) of the projected part 88 is caught thereby.
- the upper base 7 further includes two projected parts 78 and two projected parts 79, all of which are projected upward from the first upper surface 74 of the first bottom portion 70. All of the two projected parts 78 and the two projected parts 79 are provided between the opening 76 and the circumferential edge 71.
- the two projected parts 78 and the two projected parts 79 are arranged at equal intervals along the circumferential direction of the first bottom portion 70, and more specifically, they are alternately arranged in that order of one projected part 78, one projected part 79, the other projected part 78 and the other projected part 79 in the circumferential direction of the first bottom portion 70.
- Each projected part 78 is shaped like a tubular shape, and has therein an opening 780.
- Each projected part 79 has a columnar shape.
- the projected parts 78 and the projected parts 79 have elliptic shapes long in the radial direction of the first bottom portion 70, when viewed along the up-down direction.
- the projected part 78 has a recess 781 (refer to FIG. 9 ) on the side of the opening 76.
- the recess 781 is recessed downward.
- the opening 780 of each projected part 78 is configured such that a corresponding projected part 89 of the lower base 8 is fitted thereinto.
- the recess 781 of each projected part 78 is configured such that a corresponding projected part 90 of the lower base 8 is positioned inside thereof in the radial direction of the first bottom portion 70.
- the recess 781 is configured such that the claw part 901 (refer to FIG. 5 ) of the projected part 90 is caught thereby.
- the first bottom portion 70 of the upper base 7 includes six pairs of ribs 100, namely, twelve ribs 100 in total (only four ribs are shown in FIG. 9 ).
- Each rib 100 protrudes from the first lower surface 75 of the first bottom portion 70 toward the second bottom portion 80 (refer to FIG. 1 ). That is, the ribs 100 are protruded downward.
- the ribs 100 have long rectangular parallelepiped shapes.
- the two ribs 100 paired are arranged in parallel to each other so as to direct longitudinal directions thereof to the radial direction of the first bottom portion 70.
- the first bottom portion 70 further includes six ribs 101 (only three ribs are shown in FIG. 9 ). Each rib 101 protrudes from the first lower surface 75 toward the second bottom portion 80 (i.e., downward).
- the ribs 101 have rectangular parallelepiped shapes long in the circumferential direction of the first bottom portion 70.
- each external connection unit 5 includes an external connection terminal 50, an external connection terminal block 51 and a release button 52 (refer to FIG. 8 ).
- the external connection terminal block 51 has a square cylindrical shape, and is protruded upward from the second upper surface 84 of the second bottom portion 80.
- the external connection terminal block 51 is formed integrally with the second bottom portion 80.
- the external connection terminal block 51 has a space 510 inside thereof.
- the second bottom portion 80 is provided in the second lower surface 85 with an opening 520.
- the opening 520 is communicated with the space 510.
- the release button 52 is fitted into the opening 520.
- the external connection terminal block 51 houses, in the space 510, the external connection terminal 50.
- the second bottom portion 80 holds the external connection terminal 50 via the external connection terminal block 51.
- the external connection terminal 50 has two springs 54 (refer to FIG. 10 ), which are located on the upside thereof and exposed to the outside of the second bottom portion 80.
- the first bottom portion 70 covers the external connection terminal 50 from the two springs 54 side (i.e., the upside).
- the external connection terminal 50 includes a terminal part 53, the two springs 54 and two coupling parts 55.
- the terminal part 53, the two springs 54 and the two coupling parts 55 are integrally as the whole made of an electrically conductive metal material and the like.
- the terminal part 53 includes a frame 530, two contact pieces 531 (refer to FIG. 9 ) and a projection piece 532, and they are integrally formed.
- the frame 530 is shaped like a rectangular flat plate shape elongated, and has a rectangular-shaped opening 533 inside thereof.
- the frame 530 is substantially orthogonal to the up-down direction with the external connection terminal 50 being fixed to the second bottom portion 80 (refer to FIG 6 ). That is, the frame 530 is substantially in parallel to the second upper surface 84 (refer to FIG. 6 ) of the second bottom portion 80.
- the two contact pieces 531 are protruded upward obliquely from the frame 530 so as to partially cover the opening 533.
- the two contact pieces 531 are provided to be arranged along a longitudinal direction of the frame 530.
- the projection piece 532 is protruded downward obliquely from the frame 530 so as to partially cover the opening 533.
- the projection piece 532 is located to face the two contact pieces 531 such that the opening 533 is interposed between the projection piece 532 and the two contact pieces 531 in the frame 530.
- Each coupling part 55 includes a first piece 550 and a second piece 551, which are integrally formed into an L-shape plate in cross-section as a whole.
- the first piece 550 and the frame 530 are on the same plane.
- the first piece 550 is connected to the frame 530.
- the second piece 551 is protruded upward and perpendicularly from an end 552 of the first piece 550.
- Each spring 54 is shaped into a substantially U-shape plate in cross section.
- the spring 54 includes a first plate 540, a second plate 541, and a curved plate 542 connecting the first plate 540 and the second plate 541 and having a semicircle shape in cross section, all of which are integrally formed.
- the spring 54 is located on the upside of the terminal part 53.
- the first plate 540 is located to face the first lower surface 75 (refer to FIG. 9 ) of the first bottom portion 70 (refer to FIG. 9 ).
- the respective two first plates 540 are protruded from upper ends of the second pieces 551 of the two coupling parts 55 to face the frame 530 of the terminal part 53.
- the respective second plates 541 are located below the first plates 540 to face them.
- the respective two springs 54 correspond to the two contact pieces 531 in one-to-one.
- the second plate 541 of each spring 54 is in contact with a corresponding contact piece 531.
- two operation pieces 58 are protruded.
- the operation pieces 58 are located inside the opening 533 not to overlap with the contact piece 531, when the external connection terminal 50 is viewed from the downside.
- each external connection terminal 50 is in contact with corresponding one pair of ribs 100 and one rib 101 in the protruding direction 821 (refer to FIG. 1 ) of the first circumference wall 82 (refer to FIG. 1 ). More specifically, each external connection terminal 50 is located below the ribs 100 with the frame 530 being in contact with the lower surfaces of the pair of ribs 100 and the lower surface of the one rib 101.
- the lower surfaces of the pair of ribs 100 are surfaces of ends 102 in a protruding direction (downward), of the ribs 100, and the lower surface of the one rib 101 is a surface of an end 103 in a protruding direction (downward), of the rib 101.
- the second bottom portion 80 is provided in the second lower surface 85 with six hollow parts 56 (refer to FIG. 7 ).
- the respective six hollow parts 56 correspond to six external connection terminal blocks 51 in one-to-one (refer to FIG. 6 ).
- Each hollow part 56 is located inside the space 510 (refer to FIG. 6 ) in a corresponding external connection terminal block 51, in the radial direction of the second bottom portion 80. In other words, the hollow part 56 is adjacent to the space 510.
- the hollow part 56 in the second lower surface 85 is recessed upward.
- Each hollow part 56 is provided in the bottom thereof with one or two insertion holes 57. The one or two insertion holes 57 of each hollow part 56 are communicated with the space 510 in the corresponding external connection terminal block 51.
- the external wiring 600 (refer to FIG. 2 ), inserted into the fire detector base 2 from the upside, is inserted into the insertion hole 57.
- the external wiring 600 is inserted between the second plate 541 of the spring 54 and the contact piece 531 corresponding to the spring 54 while elastically deforming the spring 54 of the external connection terminal 50 shown in FIG. 10 .
- the external connection terminal 50 holds the external wiring 600 by pinching the external wiring 600 between the second plate 541 and the contact piece 531 to be electrically connected to the external wiring 600.
- the external connection terminal 50 is a so-called "quick connection terminal".
- the operation pieces 58 are pressed upward to elastically deform the spring 54, and the second plate 541 can be therefore separated from the terminal part 53. Accordingly, the external wiring 600 held by the external connection terminal 50 can be removed from the external connection terminal 50. Note that the external wiring 600 may be inserted into the fire detector base 2 from a knockout hole formed by removing the wall portion 870 of the knockout part 87 shown in FIG. 4 .
- Each of the three contact parts 6, as shown in FIG. 7 includes an internal terminal 60, and an internal terminal block 61 fixed to the second bottom portion 80 of the lower base 8. Respective three internal terminals 60 (internal terminal blocks 61) correspond to three of the six external connection terminals 50, in one-to-one.
- Each internal terminal block 61 is formed integrally with the second bottom portion 80. Each internal terminal block 61 is located on the second lower surface 85 of the second bottom portion 80. Each internal terminal block 61 is provided to be adjacent to a corresponding external connection unit 5, along the circumferential direction of the second bottom portion 80. As shown in FIG. 8 , the internal terminal block 61 includes two projection plates 610 with rectangular shapes and a projection plate 611 with a rectangular shape. The two projection plates 610 are projected downward from the second lower surface 85 so as to face each other in parallel. The projection plate 611 is projected downward from the second lower surface 85.
- the projection plate 611 is provided to be substantially orthogonal to both of the two projection plates 610, and connected to one side 612 in a projecting direction (up-down direction), of each projection plate 610.
- the projection plate 611 has an opening 613 formed along the up-down direction.
- the internal terminal block 61 houses therein the internal terminal 60 between the two projection plates 610.
- the second bottom portion 80 has a through-hole 614 (refer to FIG. 7 ) between the two projection plates 610.
- the through-hole 614 penetrates from the second upper surface 84 (refer to FIG. 6 ) to the second lower surface 85, of the second bottom portion 80.
- the internal terminal 60 includes two metal pieces 62.
- the metal pieces 62 have plate shapes.
- the two metal pieces 62 are fixed with facing each other and being substantially in contact with each other.
- the two metal pieces 62 when displaced to be separated from each other, can apply, by spring elasticity, force in a direction of approaching each other. Accordingly, each internal terminal 60 can pinch a blade 322 (refer to FIG. 11 ) of the electric circuit 320 (refer to FIG. 1 ) of the detector body 3 (refer to FIG. 1 ) between the two metal pieces 62, thereby being electrically connected to the electric circuit 320.
- the external connection terminal 50 and the internal terminal 60 are connected to each other with a coupling piece 65 interposed therebetween.
- the internal terminal 60 is therefore electrically connected to the corresponding external connection terminal 50.
- the external connection terminal 50 is located above the internal terminal 60.
- the coupling piece 65 includes a bottom plate 651 and two side plates 652.
- the bottom plate 651 is provided to extend from the frame 530 of the external connection terminal 50.
- Each side plate 652 is provided to extend downward from the bottom plate 651 to a corresponding metal piece 62 of the internal terminal 60.
- the external connection terminal 50 is held by the external connection terminal block 51, and accordingly, the external connection terminal 50 and the internal terminal 60 are fixed to the second bottom portion 80.
- the respective three internal terminals 60 correspond to three of the six external connection terminals 50 in one-to-one. That is, each internal terminal 60 and one external connection terminal 50 corresponding to the internal terminal 60 constitute a terminal group 800. Three terminal groups 800 mutually have the same shape. Each of the three internal terminals 60 are formed integrally with the corresponding external connection terminal 50. Accordingly, distances LI, L2 and L3 (refer to FIGS. 12A to 12C ) from the respective internal terminals 60 to the external connection terminals 50 are zero.
- FIGS. 12A to 12C are drawings schematically showing arrangements of the three terminal groups 800, when viewed from the same view point as FIG. 5 .
- terminal groups 800A, 800B and 800C are referred to as terminal groups 800A, 800B and 800C.
- the terminal group 800A includes the external connection terminal 50A and the internal terminal 60A.
- the terminal group 800B includes the external connection terminal 50B and the internal terminal 60B.
- the terminal group 800C includes the external connection terminal 50C and the internal terminal 60C.
- the distance L1 from the internal terminal 60A to the external connection terminal 50A, of the terminal group 800A is shorter than any of respective distances L61 and L62 from the internal terminal 60A of the terminal group 800A to the internal terminals 60B and 60C of the terminal groups 800B and 800C. Also the distance L1 is shorter than any of respective distances L51 and L52 from the external connection terminal 50A of the terminal group 800A to the external connection terminals 50B and 50C of the terminal groups 800B and 800C.
- the distance L1 from the internal terminal 60A to the external connection terminal 50A, of the terminal group 800A, represents a length of the shortest line segment joining the internal terminal 60A and the external connection terminal 50A.
- the respective distances L61 and L62 represent lengths of the shortest line segments joining: the internal terminal 60A; and the internal terminals 60B and 60C.
- the respective distances L51 and L52 represent lengths of the shortest line segments joining: the external connection terminal 50A; and the external connection terminals 50B and 50C.
- FIG 12A shows the distances according to the terminal group 800A. Also in the case of each of the terminal groups 800B and 800C, the distances between the terminals meet the relationship similar to that of the terminal group 800A.
- the distance L2 from the internal terminal 60B to the external connection terminal 50B, of the terminal group 800B, as shown in FIG. 12B is shorter than any of respective distances L61 and L63 from the internal terminal 60B to the internal terminals 60A and 60C. Also the distance L2 is shorter than any of respective distances L51 and L53 from the external connection terminal 50B to the external connection terminals 50A and 50C.
- the distance L3 from the internal terminal 60C to the external connection terminal 50C, of the terminal group 800C, as shown in FIG. 12C is shorter than any of respective distances L62 and L63 from the internal terminal 60C to the internal terminals 60A and 60B. Also the distance L3 is shorter than any of respective distances L52 and L53 from the external connection terminal 50C to the external connection terminals 50A and 50B.
- the other three without the internal terminals 60, of the six external connection terminals 50 in FIG. 5 may be connected to wirings to be unused, or to input sides and output sides of wirings to be used for relaying the input sides to output sides.
- the casing 300 of the detector body 3, as shown in FIG. 2 includes a tubular part 301 and a basket part 306.
- the tubular part 301 includes a circumference wall 302 with a cylindrical shape and a bottom wall 303 located at a lower end of the circumference wall 302.
- the tubular part 301 is formed into a cylindrical shape with a bottom, as a whole.
- the basket part 306 includes a circumference wall 307 with a lattice and cylindrical shape, and a bottom wall 308 located at a lower end of the circumference wall 307.
- the basket part 306 is formed into a cylindrical shape with a bottom, as a whole.
- the circumference wall 302 of the tubular part 301 is larger in diameter than the circumference wall 307 of the basket part 306.
- the bottom wall 303 of the tubular part 301 is connected to the circumference wall 307 of the basket part 306.
- the circumference wall 302 of the tubular part 301 includes six protrusions 304 inside thereof.
- the respective six protrusions 304 correspond to the six recesses 832 (refer to FIG. 8 ) formed in the second circumference wall 83 (refer to FIG. 8 ) of the pedestal 4 (refer to FIG 8 ) of the fire detector base 2 (refer to FIG. 8 ) in one-to-one.
- the detector body 3 is attached to the fire detector base 2 by the six protrusions 304.
- each protrusion 304 of the detector body 3 may be inserted upward from the downside with respect to a corresponding recess 832 of the fire detector base 2 while the detector body 3 is removed from the fire detector base 2. Then, the detector body 3 may be turned in the circumferential direction thereof such that each protrusion 304 is moved to a location not adjacent to the recess 832 in the recessed part 831 (refer to FIG. 8 ). The detector body 3 can be therefore attached to the fire detector base 2.
- the bottom wall 303 of the tubular part 301 has, in an inside surface 400 thereof, a water discharge groove 401.
- the water discharge groove 401 is an annular shaped groove, and located near the circumference wall 302.
- the water discharge groove 401 is recessed downward in the inside surface 400.
- the water discharge groove 401 has therein two holes 402 (refer to FIG 11 ) penetrating the bottom wall 303.
- the two holes 402 are provided at locations symmetric to each other in the water discharge groove 401.
- the inside surface 400 of the bottom wall 303 includes an inclined surface 403 between the water discharge groove 401 and the circumference wall 302.
- the inclined surface 403 is located around the water discharge groove 401, and inclined to be lower to at its end adjacent to the inside in the radial direction of the circumference wall 302 than at its end remote from the inside.
- an impervious wall 404 is provided inside the water discharge groove 401.
- the impervious wall 404 is adjacent to the water discharge groove 401, and protruded upward from the inside surface 400 of the bottom wall 303.
- the impervious wall 404 can prevent water, which has flowed in the water discharge groove 401, from entering a space inside the impervious wall 404 in the radial direction of the circumference wall 302.
- the cover 310 as shown in FIG. 11 has a disk shape.
- the cover 310 is configured to cover a major portion of the bottom wall 303 of the tubular part 301, when the detector body 3 is viewed from the upside. That is, the cover 310 as shown in FIG 1 is located below the fire detector base 2 such that an upper surface 311 thereof faces the fire detector base 2.
- the cover 310 is located above the impervious wall 404 so as to cover it.
- the cover 310 is configured such that an outer edge 312 thereof is outside the impervious wall 404 in the radial direction of the circumference wall 302 of the tubular part 301.
- the upper surface 311 is inclined like a circular arc shape, such that the vicinity of the outer edge 312 is lower at its outer end than at its inner end.
- the upper surface 311 includes an inclined surface 313.
- the inclined surface 313 has an apex corresponding to a center 314 of the upper surface 311, and is inclined to be lower at its outer end than at its apex in the radial direction of the cover 310.
- two walls 315 are protruded from the upper surface 311.
- the two walls 315 are provided along the inclined surface 313 on the upper surface 311.
- the two walls 315 are provided to face each other such that the center 314 of the upper surface 311 is interposed therebetween.
- On the upper surface 311, three projecting bases 316 are provided outside each wall 315 in the radial direction of the cover 310.
- Each projecting base 316 is projected from the upper surface 311, and has a flat upper face 317.
- the cover 310 has two or more through-holes 318 (three in the example of the drawing) in the upper face 317.
- the electric circuit 320 is disposed below the cover 310.
- the electric circuit 320 includes a substrate 321.
- the substrate 321 mounts thereon two or more blades 322 (refer to FIG. 11 ; three blades 322 in FIG. 11 ) according to the electric circuit 320, a thermal sensor 323, a smoke sensor 324, two confirmation lamps (not shown) and a light projector (not shown).
- the two confirmation lamps include a confirmation lamp for the thermal sensor and a confirmation lamp for the smoke sensor. Examples of each confirmation lamp include a light emitting element such as an LED element. Examples of the light projector include a light emitting element such as an LED element.
- the substrate 321 is located inside the impervious wall 404 in the radial direction of the circumference wall 302 of the tubular part 301.
- Each blade 322 shown in FIG. 11 is made of an electrically conductive metal plate and the like.
- the respective three blades 322 pass through the three through-holes 318 of the cover 310, and are protruded upward from the cover 310.
- the respective three blades 322 correspond to the three internal terminals 60 in one-to-one (refer to FIG. 7 ).
- Each blade 322 is electrically connected to a corresponding internal terminal 60. That is, each blade 322 is pinched by the two metal pieces 62 (refer to FIG. 10 ) of the corresponding internal terminal 60.
- the electric circuit 320 (refer to FIG. 1 ) is electrically connected to the external wiring 600 (refer to FIG. 2 ).
- the thermal sensor 323 in FIG 1 is configured to detect fire by sensing an ambient temperature with a thermistor 325. If the fire is detected, the electric circuit 320 allows the confirmation lamp for the thermal sensor to emit light, and further inform an externally located receiver (not shown) of occurrence of the fire through the external wiring 600 (refer to FIG 2 ). The light emitted from the confirmation lamp is output to the outside of the detector body 3.
- the thermal sensor 323 may be configured to detect the ambient temperature with a bimetal instead of the thermistor 325.
- the smoke sensor 324 and the light projector are located to be surrounded by the optical base 330.
- the optical base 330 is provided below the substrate 321.
- the smoke sensor 324 includes a lens 331 and a photodetector (not shown) fixed to face the lens 331. Light from the light projector is diffusely reflected by smoke particles, which have entered the optical base 330, and therefore the light enters the lens 331. Accordingly, the photodetector detects the light from the light projector. Thus the smoke sensor 324 detects the fire. If the fire is detected, the electric circuit 320 allows the confirmation lamp for the smoke sensor to emit light, and further inform an externally located receiver (not shown) of occurrence of the fire through the external wiring 600 (refer to FIG. 2 ). The light emitted from the confirmation lamp is output to the outside of the detector body 3.
- the insect proof cover 340 is provided to cover the optical base 330.
- the insect proof cover 340 as shown in FIG. 2 includes a disk-shaped bottom wall 341 and a lattice-shaped lattice part 343 protruded, from an outer edge 342 of the bottom wall 341, upward in a direction perpendicular to the bottom wall 341.
- the water When water is on the inclined surface 745 of the first upper surface 74, the water flows along the inclined surface 745. More specifically, since the water flows outward in the radial direction of the first bottom portion 70, the water can reach the circumferential edge 71 of the first bottom portion 70 from the inclined surface 745 via the flat surface 744. Furthermore the water flows into the side of the second bottom portion 80 (i.e., downside) from the gap 94 between the first bottom portion 70 and the first circumference wall 82. The water can be discharged to the downside of the fire detector base 2, after passing through the hole 95 or the hole 96 located in the water collecting surface 742 (refer to FIG 5 ) of the second bottom portion 80.
- the water then drops on the inclined surface 403 of the bottom wall 303 of the tube part 301 in the detector body 3.
- the water further flows inward along inclination of the inclined surface 403 in the radial direction of the tube part 301. Therefore the water can flow into the water discharge groove 401 and be discharged from the hole 402 (refer to FIG 11 ) to the outside of the fire detector 1.
- the water If water enters the detector body 3 for example via not the hole 95 or the hole 96 but the opening 76 and the opening 86 located in the center of the fire detector base 2, the water reaches the upper surface 311 of the cover 310. The water then flows outward along inclination of the inclined surface 313 of the upper surface 311 in the radial direction of the cover 310, and drop on the inclined surface 403 of the bottom wall 303 of the tube part 301 from the outer edge 312 of the cover 310. Accordingly, the water can flow along inclination of the inclined surface 403, flow into the water discharge groove 401, and be discharged from the hole 402 (refer to FIG. 11 ) to the outside of the fire detector 1.
- a fire detector base 2 includes a pedestal 4.
- the pedestal 4 is for attaching thereto a detector body 3 of a fire detector configured to detect fire.
- the pedestal 4 includes a bottom wall 40 and a first circumference wall 82 (circumference wall).
- the first circumference wall 82 has a tubular shape.
- the first circumference wall 82 protrudes from a circumferential edge 81 of the bottom wall 40.
- the bottom wall 40 has a first surface 44 and a second surface 45.
- the first surface 44 and the second surface 45 are disposed opposite to each other along a protruding direction 821 of the first circumference wall 82.
- the first circumference wall 82 includes an end 820 in the protruding direction 821 of the first circumference wall 82, and the end 820 is closer to the first surface 44 than the second surface 45 in the protruding direction 821.
- the pedestal 4 further includes a water collecting surface 742 and a hole 95 (96).
- the water collecting surface 742 is adjacent to the first surface 44 in a direction orthogonal to the protruding direction 821.
- the hole 95 (96) penetrates from the water collecting surface 742 to an outside of the pedestal 4.
- the first surface 44 includes an inclined surface 745.
- the inclined surface 745 is inclined to be closer to the second surface 45 at its end adjacent to the water collecting surface 742 than at its end remote from the water collecting surface 742 along the direction orthogonal to the protruding direction 821.
- the water if water is on the first upper surface 74 (first surface 44) of the fire detector base 2, the water flows to the water collecting surface 742 along inclination of the inclined surface 745. Since the hole 95 and the hole 96 located in the water collecting surface 742 penetrate to the side of the detector body 3, the water can be intensively discharged to a specific location of the detector body 3 through the hole 95 and the hole 96 of the fire detector base 2. Accordingly, in the detector body 3, the water can be easily discharged so as to avoid a portion that should be prevented from being wet with the water. Note that in case where the hole 95 or the hole 96 penetrates to the outside of the fire detector 1, the water can be discharged to the outside of the fire detector 1 through the hole 95 or the hole 96 of the fire detector base 2, without entering the detector body 3.
- a fire detector base 2 further includes an external connection terminal 50 (connection terminal).
- an external wiring 600 (wiring) is electrically connected to the external connection terminal 50.
- the bottom wall 40 includes a first bottom portion 70 and a second bottom portion 80.
- the second bottom portion 80 faces the first bottom portion 70 in the protruding direction 821.
- the second bottom portion 80 is configured to hold the external connection terminal 50 in a state where a spring 54 of the external connection terminal 50 (a portion of the connection terminal) is exposed to an outside of the second bottom portion 80.
- the first bottom portion 70 is configured to cover the spring 54 of the external connection terminal 50.
- the fire detector base 2 holds, with the second bottom portion 80, the external connection terminal 50 (connection terminal). Furthermore the fire detector base 2 covers, with the first bottom portion 70, the portion of the connection terminal (spring 54 in the present embodiment). Accordingly, the connection terminal can be attached to the bottom wall 40 without the other member for fixing. In case where a plurality of the connection terminals are provided, the plurality of the connection terminals can be attached with a common member (first bottom portion 70 and second bottom portion 80). Thus, each connection terminal can be more efficiently attached, compared with that the respective plurality of the connection terminals are attached with individual members. Note that, instead of the external connection terminal 50, for example, the internal terminal 60 may be held to the second bottom portion 80 by the above-mentioned configuration, and covered with the first bottom portion 70, and that case also has an advantage similar to the above matter.
- the external connection terminal 50 (connection terminal) includes a terminal part 53 and a spring 54.
- the external wiring 600 wiring
- the spring 54 is configured to hold the external wiring 600 in cooperation with the terminal part 53 by pinching the external wiring 600 between the spring 54 and the terminal part 53.
- the first bottom portion 70 includes a rib 100 (101).
- the rib 100 (101) protrudes toward the second bottom portion 80.
- the external connection terminal 50 is configured to be in contact with the rib 100 (101) in the protruding direction 821.
- the rib 100 and the rib 101 receive, from the external connection terminal 50 (connection terminal), a load applied by the spring 54. Therefore, the load by the spring 54 is hardly applied directly to a portion other than the rib 100 and the rib 101, of the first bottom portion 70. Thus, the first bottom portion 70 can ensure strength with respect to the load by the spring 54. Furthermore, since the first bottom portion 70 includes the inclined surface 745, it is possible to easily ensure the space 700 between the first bottom portion 70 and the second bottom portion 80.
- the first lower surface 75 of the first bottom portion 70 may be provided to have an inclination parallel to the inclined surface 745 of the first upper surface 74, such that the second upper surface 84 of the second bottom portion 80 is inclined to the inclined surface 745, thereby ensuring the space 700 between the first bottom portion 70 and the second bottom portion 80.
- the space 700 can be effectively used by disposing the rib 100 and the rib 101 therein.
- the internal terminal 60 may have the above-mentioned configuration, and that case also has an advantage similar to the above matter.
- the first circumference wall 82 (circumference wall) includes a knockout part 87.
- the knockout part 87 includes two side portions 871 and a wall portion 870.
- the two side portions 871 extend from the end 820 of the first circumference wall 82 in the protruding direction 821.
- the wall portion 870 is disposed between the two side portions 871 to be adjacent to the two side portions 871.
- Each of the two side portions 871 is smaller in thickness than the wall portion 870.
- each of the two side portions 871 of the knockout part 87 is smaller in thickness than the wall portion 870, it is possible to easily cut the knockout part 87 along the side portion 871. Accordingly, it is possible to easily form a knockout hole in the first circumference wall 82 (circumference wall) by removing the wall portion 870. Then, it is possible to make the external wiring 600 pass through the knockout hole formed in the first circumference wall 82 to be inserted inside of the first circumference wall 82.
- the knockout part 87 can be easily formed, compared with a knockout part where the vicinity of a lower edge (second edge 873) of the wall portion 870 is small in thickness to the same level as the side portion 871.
- the water collecting surface 742 includes at least a part surrounding the first surface 44.
- the pedestal 4 further includes a groove (gap 94). At least a part of the groove is constituted by the water collecting surface 742. The groove is recessed with respect to the first surface 44.
- a fire detector 1 according to a seventh aspect includes the fire detector base 2 of any one of the first to the sixth aspects and the detector body 3.
- the water when water is on the first upper surface 74 (first surface 44) of the fire detector base 2, the water can be made to flow along the inclined surface 745 to be guided to the hole 95 or the hole 96. Accordingly, it is possible to prevent a portion (such as the electric circuit 320), which should be prevented from being wet, in the detector body 3 from being wet with the water.
- the bottom wall 40 does not necessarily include the first bottom portion 70 and the second bottom portion 80 formed separately from each other.
- the bottom wall 40 may be configured to include a single member where the first bottom portion 70 and the second bottom portion 80 are formed integrally with each other.
- the first bottom portion 70 does not necessarily cover the connection terminal (the internal terminal 60 or the external connection terminal 50). Also the second bottom portion 80 does not necessarily hold the connection terminal.
- connection terminal is not necessarily in contact with the rib 100 and the rib 101.
- the first circumference wall 82 does not necessarily include the knockout part 87.
- the water collecting surface 742 in the present embodiment is provided along the first circumference wall 82, but may be provided separately from the first circumference wall 82. Also the shape of the water collecting surface 742 is not limited to an annular shape. For example, the shape of the water collecting surface 742 may be a circular shape or a rectangular shape.
- the water collecting surface 742 is the surface including the upper face 93 of the projecting base 92, but not limited to the upper face of the pedestal 4.
- the water collecting surface 742 may include a part of an inner surface of the first circumference wall 82.
- the hole 95 and the hole 96 in the present embodiment penetrate from the water collecting surface 742 to the inside of the detector body 3, but are not limited to those configurations.
- the hole 95 or the hole 96 may penetrate from the water collecting surface 742 to the outside of the fire detector 1.
- the hole 95 and the hole 96 may penetrate to the outside along the protruding direction 821 of the first circumference wall 82, or along a direction orthogonal to the protruding direction 821.
- the external connection terminal 50 is not necessarily a quick connection terminal.
- the external connection terminal 50 may be a screw terminal that connects the external wiring 600 to a terminal with a screw.
- the terminal part 53 of the external connection terminal 50 may be formed separately from the spring 54.
- the spring 54 can be replaced with another spring with a different spring constant, depending on a diameter of the external wiring 600, and the external connection terminal 50 can be therefore connected to the external wirings 600 with various diameters.
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Abstract
Description
- This invention relates generally to a fire detector base and a fire detector, and more particularly relates to a fire detector base with a circumference wall having a tubular shape, and a fire detector with the fire detector base.
- As a conventional example, there has been a fire detector disclosed in a Patent Literature 1 below. The fire detector disclosed in the Patent Literature 1 includes a base (a fire detector base) to be attached to a construction surface, and a main body (a detector body) attached on the floor side with respect to the base (i.e., the downside of the base). The main body has a cover shaped into a disk plate. The cover is provided so as to cover a bowl-shaped bottom wall of the main body. The cover is provided on an upper surface thereof with a descending part, formed so as to descend from the vicinity of the central part of the cover to the outer peripheral part thereof. That is, the descending part is inclined by a prescribed angle with respect to the construction surface. The main body is provided in the bottom wall thereof with a water discharge groove formed so as to surround the cover. The water discharge groove has a drain hole penetrating the bottom wall. Accordingly, when water is on the upper surface of the cover, the water is guided into the water discharge groove, thereby being discharged from the drain hole to the outside of the main body.
- However, the fire detector disclosed in the Patent Literature 1 cannot guide, when water is on an upper surface (a first surface) of the bottom wall of the base, the water in the base to discharge the water to the outside of the fire detector.
- Patent Literature 1:
JP 2013-8082 A - An object of the present invention is to provide a fire detector base and a fire detector, which, when water is on a first surface of a bottom wall of the fire detector base, can guide the water in the fire detector base to discharge the water to the outside of the fire detector.
- To solve the above-mentioned problem, a fire detector base according to an aspect of the present invention includes a pedestal. The pedestal is for attaching thereto a detector body of a fire detector configured to detect fire. The pedestal includes a bottom wall and a circumference wall. The circumference wall has a tubular shape. The circumference wall protrudes from a circumferential edge of the bottom wall. The bottom wall has a first surface and a second surface. The first surface and the second surface are disposed opposite to each other along a protruding direction of the circumference wall. The circumference wall includes an end in the protruding direction of the circumference wall, the end being closer to the first surface than the second surface in the protruding direction. The pedestal further includes a water collecting surface and a hole. The water collecting surface is adjacent to the first surface in a direction orthogonal to the protruding direction. The hole penetrates from the water collecting surface to an outside of the pedestal. The first surface includes an inclined surface. The inclined surface is inclined to be closer to the second surface at its end adjacent to the water collecting surface than at its end remote from the water collecting surface along the direction orthogonal to the protruding direction.
- A fire detector according to an aspect of the present invention includes the fire detector base and the detector body.
-
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FIG. 1 is a cross-sectional view of a fire detector according to an exemplary embodiment of the present invention. -
FIG. 2 is a perspective view of the fire detector attached to a construction surface, when viewed from the downside thereof. -
FIG. 3 is a top view of a fire detector base according to an exemplary embodiment of the present invention. -
FIG. 4 is a perspective view of an essential part of the fire detector base, when viewed from the upside thereof. -
FIG. 5 is a top view of the fire detector base in which an upper base thereof is removed. -
FIG. 6 is a perspective view of an essential part of the fire detector base in which the upper base thereof is removed, when viewed from the upside thereof. -
FIG. 7 is a bottom view of the fire detector base. -
FIG. 8 is a perspective view of an essential part of the fire detector base, when viewed from the downside thereof. -
FIG. 9 is a perspective view of an essential part of the fire detector base in which a lower base thereof is removed, when viewed from the downside thereof. -
FIG. 10 is a perspective view of an external connection terminal and an internal terminal of the fire detector base, when viewed from the upside thereof. -
FIG 11 is a perspective view of a detector body of the fire detector. -
FIGS. 12A to 12C are schematic drawings of external connection terminals and internal terminals of the fire detector base. - Hereinafter, a fire detector base and a fire detector according to an exemplary embodiment will be explained with reference to drawings.
FIG. 1 is a cross-sectional view taken along line A-A inFIG. 3 . Unless otherwise specifically noted in the following explanations, respective sides on which afire detector base 2 and adetector body 3 of a fire detector 1 shown inFIG. 1 are located are referred to as an "upside" and a "downside", for example. - As shown in
FIG. 2 , the fire detector 1 according to the present embodiment is attached to aconstruction surface 500. The fire detector 1 includes thefire detector base 2 and thedetector body 3. Thefire detector base 2 is configured such that anexternal wiring 600 passing through a hole formed in theconstruction surface 500 is inserted thereinto. - As shown in
FIG. 1 , thedetector body 3 includes acasing 300, acover 310, anelectric circuit 320, anoptical base 330 and aninsect proof cover 340. - As shown in
FIG. 7 , thefire detector base 2 includes apedestal 4, two or more external connection units 5 (six in the example of the drawing), and two or more contact parts 6 (three in the example of the drawing). As shown inFIG. 3 , thepedestal 4 includes alower base 8 and anupper base 7. Theupper base 7 is attached so as to cover asecond bottom portion 80 of the lower base 8 (refer toFIG. 5 ). - As shown in
FIG. 5 , thelower base 8 includes thesecond bottom portion 80 with a disk shape, a first circumference wall 82 (circumference wall) with a cylindrical shape, and asecond circumference wall 83 with a cylindrical shape (refer toFIGS. 7 and8 ). - The
second bottom portion 80 has a secondupper surface 84 and a second lower surface 85 (refer toFIG. 7 ). The secondlower surface 85 is positioned on the opposite side of thesecond bottom portion 80 to the secondupper surface 84. The secondupper surface 84 and secondlower surface 85 have annular shapes. Thesecond bottom portion 80 further has a circle-shaped opening 86 in the center in a radial direction thereof. The opening 86 is concentric with the secondupper surface 84. Thesecond bottom portion 80 further has a projectingbase 92 adjacent to acircumferential edge 840 of the secondupper surface 84. Theprojecting base 92 has an annular shape, and disposed around the secondupper surface 84. The projectingbase 92 projects upward with respect to the secondupper surface 84. - As shown in
FIG. 6 , thefirst circumference wall 82 protrudes upward from thesecond bottom portion 80. As shown inFIG. 8 , thesecond circumference wall 83 protrudes downward from thesecond bottom portion 80. As shown inFIG. 7 , thefirst circumference wall 82 andsecond circumference wall 83 are concentric with each other, when viewed along an up-down direction. Thefirst circumference wall 82 is slightly larger in diameter than thesecond circumference wall 83. Thefirst circumference wall 82 protrudes from acircumferential edge 81 of the second bottom portion 80 (refer toFIG. 8 ). As shown inFIG. 5 , thefirst circumference wall 82 is inscribed in acircumferential edge 920 of the projectingbase 92. Thesecond circumference wall 83 protrudes from a position slightly inside thefirst circumference wall 82 in the radial direction of thesecond bottom portion 80. More specifically, when viewed along the up-down direction, thesecond circumference wall 83 is at a position of partially overlapping with the projectingbase 92. - As shown in
FIGS. 7 and8 , thesecond circumference wall 83 includes in anoutside surface 830 thereof three recessedparts 831. Each recessedpart 831 of thesecond circumference wall 83 is recessed inward in a radial direction of thesecond circumference wall 83. Thesecond circumference wall 83 further includes in theoutside surface 830 thereof sixrecesses 832. Eachrecess 832 of thesecond circumference wall 83 is recessed inward in the radial direction of thesecond circumference wall 83. One of the three recessedparts 831 is provided as integrally communicated with three of the sixrecesses 832. The other one of the three recessedparts 831 is provided as integrally communicated with the other two of the sixrecesses 832. The remaining one of the three recessedparts 831 is provided as integrally communicated with the remaining one of the sixrecesses 832. - As shown in
FIGS. 5 and6 , thefirst circumference wall 82 further includes threeknockout parts 87. Eachknockout part 87 includes awall portion 870 and twoside portions 871. Thefirst circumference wall 82 has anend 820 in a protruding direction 821 (upward) in which thefirst circumference wall 82 is protruded (refer toFIG. 1 ), and eachside portion 871 is provided to extend from theend 820 in theprotruding direction 821. That is, theside portions 871 are extended from theend 820 toward the second bottom portion 80 (i.e., downward). Eachside portion 871 has a width along a circumferential direction of thefirst circumference wall 82. Thewall portion 870 is disposed between the twoside portions 871. Thewall portion 870 is adjacent to the twoside portions 871. Also thewall portion 870 is provided integrally with the twoside portions 871. - As shown in
FIG. 4 , theknockout part 87 is surrounded in all directions by afirst edge 872 as an upside edge, asecond edge 873 as a downside edge, athird edge 874 and afourth edge 875. Thethird edge 874 andfourth edge 875 each connects thefirst edge 872 and thesecond edge 873. Thefirst edge 872 is included in theend 820 of thefirst circumference wall 82. Thesecond edge 873 is substantially linear to be in parallel to thefirst edge 872. Each of thethird edge 874 andfourth edge 875 is an edge on the opposite side of acorresponding side portion 871 to thewall portion 870. The whole of thesecond edge 873,third edge 874 andfourth edge 875 has a substantially U-shape, when viewed from the radial direction of thefirst circumference wall 82. More specifically thesecond edge 873 andthird edge 874 are curved into arc-shapes at near anintersection point 876 at which they intersect with each other. Similarly thesecond edge 873 andfourth edge 875 are curved into arc-shapes at near anintersection point 877 at which they intersect with each other. Eachside portion 871 has anedge 878 on the side of thewall portion 870. Theedge 878 passes through a corresponding intersection point (876 or 877). - As shown in
FIG 5 , theknockout part 87 is provided such that the inside and outside thereof in the radial direction of thefirst circumference wall 82 are recessed with respect to a portion around theknockout part 87, of thefirst circumference wall 82. Accordingly, theknockout part 87 is smaller in thickness than the portion around theknockout part 87, of thefirst circumference wall 82. Furthermore, theside portion 871 has aninner surface 879 in the radial direction of thefirst circumference wall 82, and theinner surface 879 is recessed outward in the radial direction of thefirst circumference wall 82 with respect to thewall portion 870. For that reason, theside portion 871 is smaller in thickness than thewall portion 870. - As shown in
FIGS. 5 and6 , thelower base 8 further includes four projectedparts 88 that are projected upward from the vicinity of the projectingbase 92 on the secondupper surface 84 of thesecond bottom portion 80. The four projectedparts 88 are arranged at equal intervals along a circumferential direction of thesecond bottom portion 80. Each projectedpart 88 includes acolumnar part 880 with a rectangular parallelepiped shape, protruded from thesecond bottom portion 80, and aclaw part 881 provided near an end in a protruding direction (upward), of thecolumnar part 880. Thecolumnar part 880 has elasticity capable of warping outward in the radial direction of thesecond bottom portion 80. Theclaw part 881 is protruded from thecolumnar part 880 inward in the radial direction of thesecond bottom portion 80. - The
lower base 8 further includes two projectedparts 89 that are projected upward from the secondupper surface 84 of thesecond bottom portion 80. Each projectedpart 89 has a tubular shape. The projectedpart 89 is provided between theopening 86 and the projectingbase 92. The two projectedparts 89 face each other so that theopening 86 is interposed therebetween. Each projectedpart 89 has an elliptic shape long in the radial direction of thesecond bottom portion 80, when viewed along the up-down direction. The projectedpart 89 also has in the inside thereof anopening 890, when viewed along the up-down direction. - The
lower base 8 further includes two projectedparts 90 that are projected upward from the secondupper surface 84 of thesecond bottom portion 80. The respective two projectedparts 90 correspond to the two projectedparts 89 in one-to-one. Each projectedpart 90 is provided between a corresponding projectedpart 89 and theopening 86 in thesecond bottom portion 80. The projectedpart 90 includes acolumnar part 900 with a rectangular parallelepiped shape, protruded from thesecond bottom portion 80, and aclaw part 901 provided near an end in a protruding direction (upward), of thecolumnar part 900. That is, the projectedpart 90 has a shape similar to that of the projectedpart 88. Thecolumnar part 900 has elasticity capable of warping inward in the radial direction of thesecond bottom portion 80. Theclaw part 901 is protruded from thecolumnar part 900 outward in the radial direction of thesecond bottom portion 80. - As shown in
FIG. 9 , theupper base 7 includes afirst bottom portion 70 with a disk shape (refer toFIG. 3 ) and acircumference wall portion 701 protruded downward from acircumferential edge 71 of thefirst bottom portion 70, and theupper base 7 therefore has a disk shape as a whole. Thefirst bottom portion 70 has a firstupper surface 74 with an annular shape (refer toFIG. 3 ) and a firstlower surface 75 with an annular shape. As shown inFIG. 1 , the firstupper surface 74 is positioned on the opposite side of thefirst bottom portion 70 to the firstlower surface 75. - The
first bottom portion 70 of theupper base 7 is attached to thesecond bottom portion 80 in a state where the firstlower surface 75 of thefirst bottom portion 70 faces the secondupper surface 84 of thesecond bottom portion 80 of thelower base 8. In other words, thefirst bottom portion 70 faces thesecond bottom portion 80 in theprotruding direction 821 of thefirst circumference wall 82. Accordingly, theend 820 of thefirst circumference wall 82 is closer to the firstupper surface 74 than the secondlower surface 85 in theprotruding direction 821. Thefirst bottom portion 70 of theupper base 7 is slightly smaller in diameter than thefirst circumference wall 82 of thelower base 8, and disposed in an inside space of thefirst circumference wall 82. In other words, the firstupper surface 74 of thefirst bottom portion 70 is disposed in the inside space of thefirst circumference wall 82. Thecircumference wall portion 701 of theupper base 7 is placed on an upper face 93 (refer toFIG. 6 ) of the projecting base 92 (refer toFIG. 6 ) of thesecond bottom portion 80. The fire detector includes an isolator (not shown) that is provided in aspace 700 formed between thefirst bottom portion 70 and thesecond bottom portion 80. The isolator has a function of detecting short-circuiting in the fire detector 1 and electrically cutting off the short-circuiting. Also the fire detector has agap 94 between thecircumference wall portion 701 and thefirst circumference wall 82. As shown inFIG. 3 , theupper face 93 of the projectingbase 92 is adjacent to the firstupper surface 74 in a direction orthogonal to the protruding direction 821 (refer toFIG. 1 ) of thefirst circumference wall 82. The direction orthogonal to theprotruding direction 821 of thefirst circumference wall 82 corresponds to a radial direction of thefirst bottom portion 70. - As shown in
FIGS. 1 and5 , a surface including theupper face 93 of the projectingbase 92 is referred to as a "water collecting surface 742". Thewater collecting surface 742 is disposed in the inside space of thefirst circumference wall 82. Thegap 94 corresponds to a "groove" surrounded by thewater collecting surface 742, thefirst circumference wall 82 and thecircumference wall portion 701. That is, since thecircumference wall portion 701 protruded from thefirst bottom portion 70 is placed on theupper face 93 of thewater collecting surface 742 as described above, thegap 94 has a groove-shape, a bottom of which is a portion between thefirst circumference wall 82 and thecircumference wall portion 701, of thewater collecting surface 742. Thus, thegap 94 has the groove-shape, recessed with respect to the first upper surface 74 (that corresponds to afirst surface 44 described later), and constituted by thewater collecting surface 742, thefirst circumference wall 82 and thecircumference wall portion 701. - As described above, the
first circumference wall 82 is inscribed in thecircumferential edge 920 of the projectingbase 92, and the firstupper surface 74 is disposed in the inside space of thefirst circumference wall 82. Therefore, a part along thecircumferential edge 920, of thewater collecting surface 742, surrounds the firstupper surface 74. In other words, at least a part of thewater collecting surface 742 surrounds the first upper surface 74 (that corresponds to thefirst surface 44 described later). - The
water collecting surface 742 has therein threeholes 95. The projectingbase 92 is projected with respect to the secondupper surface 84 so as to avoid a region where eachhole 95 is provided. As shown inFIG. 7 , the respective threeholes 95 correspond to the three recessedparts 831 of thesecond circumference wall 83 in one-to one. Eachhole 95 is provided at the same location as a corresponding recessedpart 831, when viewed along the up-down direction. More specifically thehole 95 penetrates thesecond bottom portion 80 and thesecond circumference wall 83 from the upper face 93 (refer toFIG. 5 ) of the projecting base 92 (refer toFIG. 5 ) to the corresponding recessedpart 831. That is, thehole 95 penetrates from thewater collecting surface 742 to the outside of thesecond circumference wall 83 in the radial direction of thesecond bottom portion 80. In other words, thehole 95 penetrates from thewater collecting surface 742 to an outside of thepedestal 4. The "outside" of thepedestal 4 mentioned herein means a space outside the inside space of thefirst circumference wall 82. The threeholes 95 are arranged at substantially equal intervals along the radial direction of thesecond bottom portion 80. - The
water collecting surface 742 further has therein onehole 96. The projecting base 92 (refer toFIG 5 ) is projected with respect to the second upper surface 84 (refer toFIG. 5 ) so as to avoid a region where thehole 96 is provided. Thehole 96 is larger in width than thesecond circumference wall 83 in the radial direction of thesecond bottom portion 80. Thehole 96 penetrates thesecond bottom portion 80 from the upper face 93 (refer toFIG. 5 ) of the projectingbase 92 to the secondlower surface 85 in a region partially overlapping with thesecond circumference wall 83, when viewed along the up-down direction. Furthermore thehole 96, as shown inFIG. 1 , penetrates thesecond circumference wall 83 along the radial direction of thesecond circumference wall 83 on the side of the secondlower surface 85. In other words, thehole 96 penetrates from thewater collecting surface 742 to the outside of thepedestal 4. - As described above, the
pedestal 4 includes theupper base 7 and thelower base 8. Accordingly, thepedestal 4 includes abottom wall 40 that includes thefirst bottom portion 70 of theupper base 7 and thesecond bottom portion 80 of thelower base 8. - The
bottom wall 40 includes the firstupper surface 74 of thefirst bottom portion 70. In thebottom wall 40, a surface including the firstupper surface 74 is referred to as the "first surface 44" of thebottom wall 40. Thefirst surface 44 in the present embodiment corresponds to the firstupper surface 74. Thebottom wall 40 further includes thesecond surface 45. Thesecond surface 45 is disposed opposite to thefirst surface 44 along theprotruding direction 821. Thesecond surface 45 includes the secondlower surface 85 of thesecond bottom portion 80. Thesecond surface 45 in the present embodiment corresponds to the secondlower surface 85. - The first
upper surface 74 includes aflat surface 744 and aninclined surface 745 inclined to theflat surface 744. More specifically theinclined surface 745 is inclined to be closer to thesecond surface 45 at its end adjacent to the water collecting surface 742 (refer toFIG. 3 ) than at its end remote from thewater collecting surface 742 along the direction (the radial direction of the first bottom portion 70) orthogonal to theprotruding direction 821. As shown inFIG 3 , thefirst bottom portion 70 further has a circle-shapedopening 76 in the center in a radial direction thereof. Theopening 76 is concentric with thecircumferential edge 71 of thefirst bottom portion 70. Theinclined surface 745 is provided around theopening 76, and has an annular shape concentric with thecircumferential edge 71. In short, theinclined surface 745 is shaped like a side surface of a truncated cone. Theflat surface 744 is provided around theinclined surface 745, and has an annular shape concentric with thecircumferential edge 71. Theflat surface 744 is formed integrally with theinclined surface 745 and continuously from theinclined surface 745 to thecircumferential edge 71 of thefirst bottom portion 70 in the radial direction of thefirst bottom portion 70. The firstupper surface 74 is provided without a projection (e.g., surrounding theinclined surface 745 and having a relatively long projection length with respect to the first upper surface 74). - The
upper base 7, as shown inFIGS. 3 and4 , further includes four projectedparts 77 projected from the vicinity of thecircumferential edge 71 on the firstupper surface 74 of thefirst bottom portion 70. The four projectedparts 77 are arranged at equal intervals along the circumferential direction of thefirst bottom portion 70. Each projectedpart 77 is shaped like a tubular shape and has anopening 771 inside thereof, when viewed along the up-down direction. The projectedpart 77 further has arecess 772 inside thereof in the radial direction of thefirst bottom portion 70. Therecess 772 is recessed downward. Each projectedpart 77 is configured such that a corresponding projectedpart 88 of thelower base 8 is fitted thereinto. Therecess 772 is configured such that the claw part 881 (refer toFIG. 6 ) of the projectedpart 88 is caught thereby. - The
upper base 7 further includes two projectedparts 78 and two projectedparts 79, all of which are projected upward from the firstupper surface 74 of thefirst bottom portion 70. All of the two projectedparts 78 and the two projectedparts 79 are provided between theopening 76 and thecircumferential edge 71. The two projectedparts 78 and the two projectedparts 79 are arranged at equal intervals along the circumferential direction of thefirst bottom portion 70, and more specifically, they are alternately arranged in that order of one projectedpart 78, one projectedpart 79, the other projectedpart 78 and the other projectedpart 79 in the circumferential direction of thefirst bottom portion 70. Each projectedpart 78 is shaped like a tubular shape, and has therein anopening 780. Each projectedpart 79 has a columnar shape. The projectedparts 78 and the projectedparts 79 have elliptic shapes long in the radial direction of thefirst bottom portion 70, when viewed along the up-down direction. The projectedpart 78 has a recess 781 (refer toFIG. 9 ) on the side of theopening 76. Therecess 781 is recessed downward. Theopening 780 of each projectedpart 78 is configured such that a corresponding projectedpart 89 of thelower base 8 is fitted thereinto. Therecess 781 of each projectedpart 78 is configured such that a corresponding projectedpart 90 of thelower base 8 is positioned inside thereof in the radial direction of thefirst bottom portion 70. Therecess 781 is configured such that the claw part 901 (refer toFIG. 5 ) of the projectedpart 90 is caught thereby. - As shown in
FIG. 9 , thefirst bottom portion 70 of theupper base 7 includes six pairs ofribs 100, namely, twelveribs 100 in total (only four ribs are shown inFIG. 9 ). Eachrib 100 protrudes from the firstlower surface 75 of thefirst bottom portion 70 toward the second bottom portion 80 (refer toFIG. 1 ). That is, theribs 100 are protruded downward. Theribs 100 have long rectangular parallelepiped shapes. The tworibs 100 paired are arranged in parallel to each other so as to direct longitudinal directions thereof to the radial direction of thefirst bottom portion 70. Thefirst bottom portion 70 further includes six ribs 101 (only three ribs are shown inFIG. 9 ). Eachrib 101 protrudes from the firstlower surface 75 toward the second bottom portion 80 (i.e., downward). Theribs 101 have rectangular parallelepiped shapes long in the circumferential direction of thefirst bottom portion 70. - As shown in
FIG. 6 , eachexternal connection unit 5 includes anexternal connection terminal 50, an externalconnection terminal block 51 and a release button 52 (refer toFIG. 8 ). - The external
connection terminal block 51 has a square cylindrical shape, and is protruded upward from the secondupper surface 84 of thesecond bottom portion 80. The externalconnection terminal block 51 is formed integrally with thesecond bottom portion 80. The externalconnection terminal block 51 has aspace 510 inside thereof. As shown inFIG. 8 , thesecond bottom portion 80 is provided in the secondlower surface 85 with anopening 520. Theopening 520 is communicated with thespace 510. Therelease button 52 is fitted into theopening 520. As shown inFIG. 6 , the externalconnection terminal block 51 houses, in thespace 510, theexternal connection terminal 50. In other words, thesecond bottom portion 80 holds theexternal connection terminal 50 via the externalconnection terminal block 51. Theexternal connection terminal 50 has two springs 54 (refer toFIG. 10 ), which are located on the upside thereof and exposed to the outside of thesecond bottom portion 80. The first bottom portion 70 (refer toFIG. 1 ) covers theexternal connection terminal 50 from the twosprings 54 side (i.e., the upside). - As shown in
FIG. 10 , theexternal connection terminal 50 includes aterminal part 53, the twosprings 54 and twocoupling parts 55. Theterminal part 53, the twosprings 54 and the twocoupling parts 55 are integrally as the whole made of an electrically conductive metal material and the like. - The
terminal part 53 includes aframe 530, two contact pieces 531 (refer toFIG. 9 ) and aprojection piece 532, and they are integrally formed. Theframe 530 is shaped like a rectangular flat plate shape elongated, and has a rectangular-shapedopening 533 inside thereof. Theframe 530 is substantially orthogonal to the up-down direction with theexternal connection terminal 50 being fixed to the second bottom portion 80 (refer toFIG 6 ). That is, theframe 530 is substantially in parallel to the second upper surface 84 (refer toFIG. 6 ) of thesecond bottom portion 80. The twocontact pieces 531 are protruded upward obliquely from theframe 530 so as to partially cover theopening 533. The twocontact pieces 531 are provided to be arranged along a longitudinal direction of theframe 530. Theprojection piece 532 is protruded downward obliquely from theframe 530 so as to partially cover theopening 533. Theprojection piece 532 is located to face the twocontact pieces 531 such that theopening 533 is interposed between theprojection piece 532 and the twocontact pieces 531 in theframe 530. - Each
coupling part 55 includes afirst piece 550 and asecond piece 551, which are integrally formed into an L-shape plate in cross-section as a whole. Thefirst piece 550 and theframe 530 are on the same plane. Thefirst piece 550 is connected to theframe 530. Thesecond piece 551 is protruded upward and perpendicularly from anend 552 of thefirst piece 550. - Each
spring 54 is shaped into a substantially U-shape plate in cross section. Thespring 54 includes afirst plate 540, asecond plate 541, and acurved plate 542 connecting thefirst plate 540 and thesecond plate 541 and having a semicircle shape in cross section, all of which are integrally formed. Thespring 54 is located on the upside of theterminal part 53. Thefirst plate 540 is located to face the first lower surface 75 (refer toFIG. 9 ) of the first bottom portion 70 (refer toFIG. 9 ). The respective twofirst plates 540 are protruded from upper ends of thesecond pieces 551 of the twocoupling parts 55 to face theframe 530 of theterminal part 53. The respectivesecond plates 541 are located below thefirst plates 540 to face them. The respective twosprings 54 correspond to the twocontact pieces 531 in one-to-one. Thesecond plate 541 of eachspring 54 is in contact with acorresponding contact piece 531. From thesecond plate 541 of eachspring 54, twooperation pieces 58 are protruded. Theoperation pieces 58 are located inside theopening 533 not to overlap with thecontact piece 531, when theexternal connection terminal 50 is viewed from the downside. - As shown in
FIG 9 , eachexternal connection terminal 50 is in contact with corresponding one pair ofribs 100 and onerib 101 in the protruding direction 821 (refer toFIG. 1 ) of the first circumference wall 82 (refer toFIG. 1 ). More specifically, eachexternal connection terminal 50 is located below theribs 100 with theframe 530 being in contact with the lower surfaces of the pair ofribs 100 and the lower surface of the onerib 101. The lower surfaces of the pair ofribs 100 are surfaces ofends 102 in a protruding direction (downward), of theribs 100, and the lower surface of the onerib 101 is a surface of anend 103 in a protruding direction (downward), of therib 101. - As shown in
FIG. 8 , thesecond bottom portion 80 is provided in the secondlower surface 85 with six hollow parts 56 (refer toFIG. 7 ). The respective sixhollow parts 56 correspond to six external connection terminal blocks 51 in one-to-one (refer toFIG. 6 ). Eachhollow part 56 is located inside the space 510 (refer toFIG. 6 ) in a corresponding externalconnection terminal block 51, in the radial direction of thesecond bottom portion 80. In other words, thehollow part 56 is adjacent to thespace 510. Thehollow part 56 in the secondlower surface 85 is recessed upward. Eachhollow part 56 is provided in the bottom thereof with one or two insertion holes 57. The one or twoinsertion holes 57 of eachhollow part 56 are communicated with thespace 510 in the corresponding externalconnection terminal block 51. - The external wiring 600 (refer to
FIG. 2 ), inserted into thefire detector base 2 from the upside, is inserted into theinsertion hole 57. Theexternal wiring 600 is inserted between thesecond plate 541 of thespring 54 and thecontact piece 531 corresponding to thespring 54 while elastically deforming thespring 54 of theexternal connection terminal 50 shown inFIG. 10 . Thus, theexternal connection terminal 50 holds theexternal wiring 600 by pinching theexternal wiring 600 between thesecond plate 541 and thecontact piece 531 to be electrically connected to theexternal wiring 600. In short, theexternal connection terminal 50 is a so-called "quick connection terminal". By pressing the release button 52 (refer toFIG 8 ) from the downside, theoperation pieces 58 are pressed upward to elastically deform thespring 54, and thesecond plate 541 can be therefore separated from theterminal part 53. Accordingly, theexternal wiring 600 held by theexternal connection terminal 50 can be removed from theexternal connection terminal 50. Note that theexternal wiring 600 may be inserted into thefire detector base 2 from a knockout hole formed by removing thewall portion 870 of theknockout part 87 shown inFIG. 4 . - Each of the three
contact parts 6, as shown inFIG. 7 , includes aninternal terminal 60, and aninternal terminal block 61 fixed to thesecond bottom portion 80 of thelower base 8. Respective three internal terminals 60 (internal terminal blocks 61) correspond to three of the sixexternal connection terminals 50, in one-to-one. - Each internal
terminal block 61 is formed integrally with thesecond bottom portion 80. Each internalterminal block 61 is located on the secondlower surface 85 of thesecond bottom portion 80. Each internalterminal block 61 is provided to be adjacent to a correspondingexternal connection unit 5, along the circumferential direction of thesecond bottom portion 80. As shown inFIG. 8 , theinternal terminal block 61 includes twoprojection plates 610 with rectangular shapes and aprojection plate 611 with a rectangular shape. The twoprojection plates 610 are projected downward from the secondlower surface 85 so as to face each other in parallel. Theprojection plate 611 is projected downward from the secondlower surface 85. Theprojection plate 611 is provided to be substantially orthogonal to both of the twoprojection plates 610, and connected to oneside 612 in a projecting direction (up-down direction), of eachprojection plate 610. Theprojection plate 611 has anopening 613 formed along the up-down direction. The internalterminal block 61 houses therein theinternal terminal 60 between the twoprojection plates 610. Thesecond bottom portion 80 has a through-hole 614 (refer toFIG. 7 ) between the twoprojection plates 610. The through-hole 614 penetrates from the second upper surface 84 (refer toFIG. 6 ) to the secondlower surface 85, of thesecond bottom portion 80. - The
internal terminal 60, as shown inFIG. 10 , includes twometal pieces 62. Themetal pieces 62 have plate shapes. The twometal pieces 62 are fixed with facing each other and being substantially in contact with each other. The twometal pieces 62, when displaced to be separated from each other, can apply, by spring elasticity, force in a direction of approaching each other. Accordingly, eachinternal terminal 60 can pinch a blade 322 (refer toFIG. 11 ) of the electric circuit 320 (refer toFIG. 1 ) of the detector body 3 (refer toFIG. 1 ) between the twometal pieces 62, thereby being electrically connected to theelectric circuit 320. - The
external connection terminal 50 and theinternal terminal 60 are connected to each other with acoupling piece 65 interposed therebetween. Theinternal terminal 60 is therefore electrically connected to the correspondingexternal connection terminal 50. Theexternal connection terminal 50 is located above theinternal terminal 60. Thecoupling piece 65 includes abottom plate 651 and twoside plates 652. Thebottom plate 651 is provided to extend from theframe 530 of theexternal connection terminal 50. Eachside plate 652 is provided to extend downward from thebottom plate 651 to acorresponding metal piece 62 of theinternal terminal 60. As shown inFIG. 5 , theexternal connection terminal 50 is held by the externalconnection terminal block 51, and accordingly, theexternal connection terminal 50 and theinternal terminal 60 are fixed to thesecond bottom portion 80. - As described above, the respective three
internal terminals 60 correspond to three of the sixexternal connection terminals 50 in one-to-one. That is, eachinternal terminal 60 and oneexternal connection terminal 50 corresponding to theinternal terminal 60 constitute aterminal group 800. Threeterminal groups 800 mutually have the same shape. Each of the threeinternal terminals 60 are formed integrally with the correspondingexternal connection terminal 50. Accordingly, distances LI, L2 and L3 (refer toFIGS. 12A to 12C ) from the respectiveinternal terminals 60 to theexternal connection terminals 50 are zero. - The relationship between the three
external connection terminals 50 and the threeinternal terminals 60, of the threeterminal groups 800, will be explained.FIGS. 12A to 12C are drawings schematically showing arrangements of the threeterminal groups 800, when viewed from the same view point asFIG. 5 . InFIGS. 12A to 12C , for mutually distinguishing the threeterminal groups 800, they are referred to asterminal groups terminal group 800A includes theexternal connection terminal 50A and theinternal terminal 60A. Theterminal group 800B includes theexternal connection terminal 50B and theinternal terminal 60B. Theterminal group 800C includes theexternal connection terminal 50C and theinternal terminal 60C. - As shown in
FIG. 12A , the distance L1 from theinternal terminal 60A to theexternal connection terminal 50A, of theterminal group 800A, is shorter than any of respective distances L61 and L62 from theinternal terminal 60A of theterminal group 800A to theinternal terminals terminal groups external connection terminal 50A of theterminal group 800A to theexternal connection terminals terminal groups - The distance L1 from the
internal terminal 60A to theexternal connection terminal 50A, of theterminal group 800A, represents a length of the shortest line segment joining theinternal terminal 60A and theexternal connection terminal 50A. Similarly, the respective distances L61 and L62 represent lengths of the shortest line segments joining: theinternal terminal 60A; and theinternal terminals external connection terminal 50A; and theexternal connection terminals -
FIG 12A shows the distances according to theterminal group 800A. Also in the case of each of theterminal groups terminal group 800A. - That is, the distance L2 from the internal terminal 60B to the
external connection terminal 50B, of theterminal group 800B, as shown inFIG. 12B , is shorter than any of respective distances L61 and L63 from the internal terminal 60B to theinternal terminals external connection terminal 50B to theexternal connection terminals - Furthermore, the distance L3 from the
internal terminal 60C to theexternal connection terminal 50C, of theterminal group 800C, as shown inFIG. 12C , is shorter than any of respective distances L62 and L63 from theinternal terminal 60C to theinternal terminals external connection terminal 50C to theexternal connection terminals - The other three without the
internal terminals 60, of the sixexternal connection terminals 50 inFIG. 5 , may be connected to wirings to be unused, or to input sides and output sides of wirings to be used for relaying the input sides to output sides. - The
casing 300 of thedetector body 3, as shown inFIG. 2 , includes atubular part 301 and abasket part 306. Thetubular part 301 includes acircumference wall 302 with a cylindrical shape and abottom wall 303 located at a lower end of thecircumference wall 302. Thetubular part 301 is formed into a cylindrical shape with a bottom, as a whole. Thebasket part 306 includes acircumference wall 307 with a lattice and cylindrical shape, and abottom wall 308 located at a lower end of thecircumference wall 307. Thebasket part 306 is formed into a cylindrical shape with a bottom, as a whole. Thecircumference wall 302 of thetubular part 301 is larger in diameter than thecircumference wall 307 of thebasket part 306. Thebottom wall 303 of thetubular part 301 is connected to thecircumference wall 307 of thebasket part 306. - As shown in
FIG. 11 , thecircumference wall 302 of thetubular part 301 includes sixprotrusions 304 inside thereof. The respective sixprotrusions 304 correspond to the six recesses 832 (refer toFIG. 8 ) formed in the second circumference wall 83 (refer toFIG. 8 ) of the pedestal 4 (refer toFIG 8 ) of the fire detector base 2 (refer toFIG. 8 ) in one-to-one. Thedetector body 3 is attached to thefire detector base 2 by the sixprotrusions 304. More specifically, as an exemplary assembly procedure, eachprotrusion 304 of thedetector body 3 may be inserted upward from the downside with respect to acorresponding recess 832 of thefire detector base 2 while thedetector body 3 is removed from thefire detector base 2. Then, thedetector body 3 may be turned in the circumferential direction thereof such that eachprotrusion 304 is moved to a location not adjacent to therecess 832 in the recessed part 831 (refer toFIG. 8 ). Thedetector body 3 can be therefore attached to thefire detector base 2. - Also as shown in
FIG 1 , thebottom wall 303 of thetubular part 301 has, in aninside surface 400 thereof, awater discharge groove 401. Thewater discharge groove 401 is an annular shaped groove, and located near thecircumference wall 302. Thewater discharge groove 401 is recessed downward in theinside surface 400. Thewater discharge groove 401 has therein two holes 402 (refer toFIG 11 ) penetrating thebottom wall 303. The twoholes 402 are provided at locations symmetric to each other in thewater discharge groove 401. - The
inside surface 400 of thebottom wall 303 includes aninclined surface 403 between thewater discharge groove 401 and thecircumference wall 302. Theinclined surface 403 is located around thewater discharge groove 401, and inclined to be lower to at its end adjacent to the inside in the radial direction of thecircumference wall 302 than at its end remote from the inside. - In the radial direction of the
circumference wall 302, animpervious wall 404 is provided inside thewater discharge groove 401. Theimpervious wall 404 is adjacent to thewater discharge groove 401, and protruded upward from theinside surface 400 of thebottom wall 303. Theimpervious wall 404 can prevent water, which has flowed in thewater discharge groove 401, from entering a space inside theimpervious wall 404 in the radial direction of thecircumference wall 302. - The
cover 310 as shown inFIG. 11 has a disk shape. Thecover 310 is configured to cover a major portion of thebottom wall 303 of thetubular part 301, when thedetector body 3 is viewed from the upside. That is, thecover 310 as shown inFIG 1 is located below thefire detector base 2 such that anupper surface 311 thereof faces thefire detector base 2. Thecover 310 is located above theimpervious wall 404 so as to cover it. Also thecover 310 is configured such that anouter edge 312 thereof is outside theimpervious wall 404 in the radial direction of thecircumference wall 302 of thetubular part 301. Theupper surface 311 is inclined like a circular arc shape, such that the vicinity of theouter edge 312 is lower at its outer end than at its inner end. Theupper surface 311 includes aninclined surface 313. Theinclined surface 313 has an apex corresponding to acenter 314 of theupper surface 311, and is inclined to be lower at its outer end than at its apex in the radial direction of thecover 310. Furthermore, as shown inFIG 11 , twowalls 315 are protruded from theupper surface 311. The twowalls 315 are provided along theinclined surface 313 on theupper surface 311. The twowalls 315 are provided to face each other such that thecenter 314 of theupper surface 311 is interposed therebetween. On theupper surface 311, three projectingbases 316 are provided outside eachwall 315 in the radial direction of thecover 310. Each projectingbase 316 is projected from theupper surface 311, and has a flatupper face 317. Thecover 310 has two or more through-holes 318 (three in the example of the drawing) in theupper face 317. - As shown in
FIG. 1 , theelectric circuit 320 is disposed below thecover 310. Theelectric circuit 320 includes asubstrate 321. Thesubstrate 321 mounts thereon two or more blades 322 (refer toFIG. 11 ; threeblades 322 inFIG. 11 ) according to theelectric circuit 320, athermal sensor 323, asmoke sensor 324, two confirmation lamps (not shown) and a light projector (not shown). The two confirmation lamps include a confirmation lamp for the thermal sensor and a confirmation lamp for the smoke sensor. Examples of each confirmation lamp include a light emitting element such as an LED element. Examples of the light projector include a light emitting element such as an LED element. - The
substrate 321 is located inside theimpervious wall 404 in the radial direction of thecircumference wall 302 of thetubular part 301. Eachblade 322 shown inFIG. 11 is made of an electrically conductive metal plate and the like. The respective threeblades 322 pass through the three through-holes 318 of thecover 310, and are protruded upward from thecover 310. The respective threeblades 322 correspond to the threeinternal terminals 60 in one-to-one (refer toFIG. 7 ). Eachblade 322 is electrically connected to a correspondinginternal terminal 60. That is, eachblade 322 is pinched by the two metal pieces 62 (refer toFIG. 10 ) of the correspondinginternal terminal 60. Thus, the electric circuit 320 (refer toFIG. 1 ) is electrically connected to the external wiring 600 (refer toFIG. 2 ). - The
thermal sensor 323 inFIG 1 is configured to detect fire by sensing an ambient temperature with athermistor 325. If the fire is detected, theelectric circuit 320 allows the confirmation lamp for the thermal sensor to emit light, and further inform an externally located receiver (not shown) of occurrence of the fire through the external wiring 600 (refer toFIG 2 ). The light emitted from the confirmation lamp is output to the outside of thedetector body 3. Thethermal sensor 323 may be configured to detect the ambient temperature with a bimetal instead of thethermistor 325. - The
smoke sensor 324 and the light projector are located to be surrounded by theoptical base 330. Theoptical base 330 is provided below thesubstrate 321. Thesmoke sensor 324 includes alens 331 and a photodetector (not shown) fixed to face thelens 331. Light from the light projector is diffusely reflected by smoke particles, which have entered theoptical base 330, and therefore the light enters thelens 331. Accordingly, the photodetector detects the light from the light projector. Thus thesmoke sensor 324 detects the fire. If the fire is detected, theelectric circuit 320 allows the confirmation lamp for the smoke sensor to emit light, and further inform an externally located receiver (not shown) of occurrence of the fire through the external wiring 600 (refer toFIG. 2 ). The light emitted from the confirmation lamp is output to the outside of thedetector body 3. - The
insect proof cover 340 is provided to cover theoptical base 330. Theinsect proof cover 340 as shown inFIG. 2 includes a disk-shapedbottom wall 341 and a lattice-shapedlattice part 343 protruded, from anouter edge 342 of thebottom wall 341, upward in a direction perpendicular to thebottom wall 341. - Next, in the
fire detector base 2 and the fire detector 1 according to the present embodiment, when water is on the firstupper surface 74 of thefirst bottom portion 70 of theupper base 7 inFIG 1 , how the water is discharged to the outside of the fire detector 1 will be described. - When water is on the
inclined surface 745 of the firstupper surface 74, the water flows along theinclined surface 745. More specifically, since the water flows outward in the radial direction of thefirst bottom portion 70, the water can reach thecircumferential edge 71 of thefirst bottom portion 70 from theinclined surface 745 via theflat surface 744. Furthermore the water flows into the side of the second bottom portion 80 (i.e., downside) from thegap 94 between thefirst bottom portion 70 and thefirst circumference wall 82. The water can be discharged to the downside of thefire detector base 2, after passing through thehole 95 or thehole 96 located in the water collecting surface 742 (refer toFIG 5 ) of thesecond bottom portion 80. Then the water then drops on theinclined surface 403 of thebottom wall 303 of thetube part 301 in thedetector body 3. The water further flows inward along inclination of theinclined surface 403 in the radial direction of thetube part 301. Therefore the water can flow into thewater discharge groove 401 and be discharged from the hole 402 (refer toFIG 11 ) to the outside of the fire detector 1. - If water enters the
detector body 3 for example via not thehole 95 or thehole 96 but theopening 76 and theopening 86 located in the center of thefire detector base 2, the water reaches theupper surface 311 of thecover 310. The water then flows outward along inclination of theinclined surface 313 of theupper surface 311 in the radial direction of thecover 310, and drop on theinclined surface 403 of thebottom wall 303 of thetube part 301 from theouter edge 312 of thecover 310. Accordingly, the water can flow along inclination of theinclined surface 403, flow into thewater discharge groove 401, and be discharged from the hole 402 (refer toFIG. 11 ) to the outside of the fire detector 1. - As apparent from the foregoing description, a
fire detector base 2 according to a first aspect includes apedestal 4. Thepedestal 4 is for attaching thereto adetector body 3 of a fire detector configured to detect fire. Thepedestal 4 includes abottom wall 40 and a first circumference wall 82 (circumference wall). Thefirst circumference wall 82 has a tubular shape. Thefirst circumference wall 82 protrudes from acircumferential edge 81 of thebottom wall 40. Thebottom wall 40 has afirst surface 44 and asecond surface 45. Thefirst surface 44 and thesecond surface 45 are disposed opposite to each other along aprotruding direction 821 of thefirst circumference wall 82. Thefirst circumference wall 82 includes anend 820 in theprotruding direction 821 of thefirst circumference wall 82, and theend 820 is closer to thefirst surface 44 than thesecond surface 45 in theprotruding direction 821. Thepedestal 4 further includes awater collecting surface 742 and a hole 95 (96). Thewater collecting surface 742 is adjacent to thefirst surface 44 in a direction orthogonal to theprotruding direction 821. The hole 95 (96) penetrates from thewater collecting surface 742 to an outside of thepedestal 4. Thefirst surface 44 includes aninclined surface 745. Theinclined surface 745 is inclined to be closer to thesecond surface 45 at its end adjacent to thewater collecting surface 742 than at its end remote from thewater collecting surface 742 along the direction orthogonal to theprotruding direction 821. - According to the above-mentioned configuration, if water is on the first upper surface 74 (first surface 44) of the
fire detector base 2, the water flows to thewater collecting surface 742 along inclination of theinclined surface 745. Since thehole 95 and thehole 96 located in thewater collecting surface 742 penetrate to the side of thedetector body 3, the water can be intensively discharged to a specific location of thedetector body 3 through thehole 95 and thehole 96 of thefire detector base 2. Accordingly, in thedetector body 3, the water can be easily discharged so as to avoid a portion that should be prevented from being wet with the water. Note that in case where thehole 95 or thehole 96 penetrates to the outside of the fire detector 1, the water can be discharged to the outside of the fire detector 1 through thehole 95 or thehole 96 of thefire detector base 2, without entering thedetector body 3. - A
fire detector base 2 according to a second aspect, which may be implemented in conjunction with the first aspect, further includes an external connection terminal 50 (connection terminal). To theexternal connection terminal 50, an external wiring 600 (wiring) is electrically connected. Thebottom wall 40 includes afirst bottom portion 70 and asecond bottom portion 80. Thesecond bottom portion 80 faces thefirst bottom portion 70 in theprotruding direction 821. Thesecond bottom portion 80 is configured to hold theexternal connection terminal 50 in a state where aspring 54 of the external connection terminal 50 (a portion of the connection terminal) is exposed to an outside of thesecond bottom portion 80. Thefirst bottom portion 70 is configured to cover thespring 54 of theexternal connection terminal 50. - According to the above-mentioned configuration, the
fire detector base 2 holds, with thesecond bottom portion 80, the external connection terminal 50 (connection terminal). Furthermore thefire detector base 2 covers, with thefirst bottom portion 70, the portion of the connection terminal (spring 54 in the present embodiment). Accordingly, the connection terminal can be attached to thebottom wall 40 without the other member for fixing. In case where a plurality of the connection terminals are provided, the plurality of the connection terminals can be attached with a common member (first bottom portion 70 and second bottom portion 80). Thus, each connection terminal can be more efficiently attached, compared with that the respective plurality of the connection terminals are attached with individual members. Note that, instead of theexternal connection terminal 50, for example, theinternal terminal 60 may be held to thesecond bottom portion 80 by the above-mentioned configuration, and covered with thefirst bottom portion 70, and that case also has an advantage similar to the above matter. - In a
fire detector base 2 according to a third aspect, which may be implemented in conjunction with the second aspect, the external connection terminal 50 (connection terminal) includes aterminal part 53 and aspring 54. To theterminal part 53, the external wiring 600 (wiring) is electrically connected. Thespring 54 is configured to hold theexternal wiring 600 in cooperation with theterminal part 53 by pinching theexternal wiring 600 between thespring 54 and theterminal part 53. Thefirst bottom portion 70 includes a rib 100 (101). The rib 100 (101) protrudes toward thesecond bottom portion 80. Theexternal connection terminal 50 is configured to be in contact with the rib 100 (101) in theprotruding direction 821. - According to the above-mentioned configuration, the
rib 100 and therib 101 receive, from the external connection terminal 50 (connection terminal), a load applied by thespring 54. Therefore, the load by thespring 54 is hardly applied directly to a portion other than therib 100 and therib 101, of thefirst bottom portion 70. Thus, thefirst bottom portion 70 can ensure strength with respect to the load by thespring 54. Furthermore, since thefirst bottom portion 70 includes theinclined surface 745, it is possible to easily ensure thespace 700 between thefirst bottom portion 70 and thesecond bottom portion 80. For example, the firstlower surface 75 of thefirst bottom portion 70 may be provided to have an inclination parallel to theinclined surface 745 of the firstupper surface 74, such that the secondupper surface 84 of thesecond bottom portion 80 is inclined to theinclined surface 745, thereby ensuring thespace 700 between thefirst bottom portion 70 and thesecond bottom portion 80. In the case where thespace 700 is ensured between thefirst bottom portion 70 and thesecond bottom portion 80, thespace 700 can be effectively used by disposing therib 100 and therib 101 therein. Instead of theexternal connection terminal 50, for example, theinternal terminal 60 may have the above-mentioned configuration, and that case also has an advantage similar to the above matter. - In a
fire detector base 2 according to a fourth aspect, which may be implemented in conjunction with any one of the first to the third aspects, the first circumference wall 82 (circumference wall) includes aknockout part 87. Theknockout part 87 includes twoside portions 871 and awall portion 870. The twoside portions 871 extend from theend 820 of thefirst circumference wall 82 in theprotruding direction 821. Thewall portion 870 is disposed between the twoside portions 871 to be adjacent to the twoside portions 871. Each of the twoside portions 871 is smaller in thickness than thewall portion 870. - According to the above-mentioned configuration, since each of the two
side portions 871 of theknockout part 87 is smaller in thickness than thewall portion 870, it is possible to easily cut theknockout part 87 along theside portion 871. Accordingly, it is possible to easily form a knockout hole in the first circumference wall 82 (circumference wall) by removing thewall portion 870. Then, it is possible to make theexternal wiring 600 pass through the knockout hole formed in thefirst circumference wall 82 to be inserted inside of thefirst circumference wall 82. In addition, theknockout part 87 can be easily formed, compared with a knockout part where the vicinity of a lower edge (second edge 873) of thewall portion 870 is small in thickness to the same level as theside portion 871. - In a
fire detector base 2 according to a fifth aspect, which may be implemented in conjunction with any one of the first to the fourth aspects, thewater collecting surface 742 includes at least a part surrounding thefirst surface 44. - According to the above-mentioned configuration, when water is on the
first surface 44, it is possible to more surely guide the water to thewater collecting surface 742 to be discharged from thehole 95 or thehole 96 to the outside of thefire detector base 2. - In a
fire detector base 2 according to a sixth aspect, which may be implemented in conjunction with any one of the first to the fifth aspects, thepedestal 4 further includes a groove (gap 94). At least a part of the groove is constituted by thewater collecting surface 742. The groove is recessed with respect to thefirst surface 44. - According to the above-mentioned configuration, since the groove (gap 94), at least a part of which is constituted by the
water collecting surface 742, is recessed with respect to thefirst surface 44, the water guided to thewater collecting surface 742 can be easily guided to thehole 95 or thehole 96 along the groove. It is therefore possible to more surely discharge the water to the outside of thefire detector base 2. - A fire detector 1 according to a seventh aspect includes the
fire detector base 2 of any one of the first to the sixth aspects and thedetector body 3. - According to the above-mentioned configuration, when water is on the first upper surface 74 (first surface 44) of the
fire detector base 2, the water can be made to flow along theinclined surface 745 to be guided to thehole 95 or thehole 96. Accordingly, it is possible to prevent a portion (such as the electric circuit 320), which should be prevented from being wet, in thedetector body 3 from being wet with the water. - The
bottom wall 40 does not necessarily include thefirst bottom portion 70 and thesecond bottom portion 80 formed separately from each other. For example, thebottom wall 40 may be configured to include a single member where thefirst bottom portion 70 and thesecond bottom portion 80 are formed integrally with each other. - The
first bottom portion 70 does not necessarily cover the connection terminal (theinternal terminal 60 or the external connection terminal 50). Also thesecond bottom portion 80 does not necessarily hold the connection terminal. - The connection terminal is not necessarily in contact with the
rib 100 and therib 101. - The
first circumference wall 82 does not necessarily include theknockout part 87. - Also in those cases as above, when water is on the first upper surface 74 (first surface 44) of the
fire detector base 2, the water can be avoided from entering a portion, which should be prevented from being wet with the water, in thedetector body 3, and therefore discharged to the outside of the fire detector 1. - The
water collecting surface 742 in the present embodiment is provided along thefirst circumference wall 82, but may be provided separately from thefirst circumference wall 82. Also the shape of thewater collecting surface 742 is not limited to an annular shape. For example, the shape of thewater collecting surface 742 may be a circular shape or a rectangular shape. - In the present embodiment, the
water collecting surface 742 is the surface including theupper face 93 of the projectingbase 92, but not limited to the upper face of thepedestal 4. For example, thewater collecting surface 742 may include a part of an inner surface of thefirst circumference wall 82. - The
hole 95 and thehole 96 in the present embodiment penetrate from thewater collecting surface 742 to the inside of thedetector body 3, but are not limited to those configurations. For example, thehole 95 or thehole 96 may penetrate from thewater collecting surface 742 to the outside of the fire detector 1. Alternatively, for example, thehole 95 and thehole 96 may penetrate to the outside along theprotruding direction 821 of thefirst circumference wall 82, or along a direction orthogonal to theprotruding direction 821. - The
external connection terminal 50 is not necessarily a quick connection terminal. For example, theexternal connection terminal 50 may be a screw terminal that connects theexternal wiring 600 to a terminal with a screw. - The
terminal part 53 of theexternal connection terminal 50 may be formed separately from thespring 54. In this case, thespring 54 can be replaced with another spring with a different spring constant, depending on a diameter of theexternal wiring 600, and theexternal connection terminal 50 can be therefore connected to theexternal wirings 600 with various diameters. - The embodiments described above are merely examples of various embodiments according to the present invention. Therefore the present invention is not limited to those embodiments. The embodiments may be made various modifications based on designs or the like, as long as the object of the present invention can be achieved.
-
- 1 Fire Detector
- 2 Fire Detector Base
- 3 Detector Body
- 4 Pedestal
- 40 Bottom Wall
- 44 First Surface
- 45 Second Surface
- 50 External Connection Terminal (Connection Terminal)
- 53 Terminal Part
- 54 Spring
- 60 Internal Terminal (Connection Terminal)
- 70 First Bottom Portion
- 80 Second Bottom Portion
- 81 Circumferential Edge
- 82 First Circumference Wall (Circumference Wall)
- 87 Knockout Part
- 94 Gap (Groove)
- 95, 96 Hole
- 100, 101 Rib
- 600 External Wiring (Wiring)
- 742 Water Collecting Surface
- 745 Inclined Surface
- 820 End
- 821 Protruding Direction
- 870 Wall Portion
- 871 Side Portion
Claims (7)
- A fire detector base, comprising a pedestal for attaching thereto a detector body of a fire detector configured to detect fire,
the pedestal including:a bottom wall; anda circumference wall having a tubular shape and protruding from a circumferential edge of the bottom wall,the bottom wall having a first surface and a second surface that are disposed opposite to each other along a protruding direction of the circumference wall,
the circumference wall including an end in the protruding direction of the circumference wall, the end being closer to the first surface than the second surface in the protruding direction,
the pedestal further including:a water collecting surface adjacent to the first surface in a direction orthogonal to the protruding direction; anda hole penetrating from the water collecting surface to an outside of the pedestal, andthe first surface including an inclined surface that is inclined to be closer to the second surface at its end adjacent to the water collecting surface than at its end remote from the water collecting surface along the direction orthogonal to the protruding direction. - The fire detector base of claim 1, further comprising a connection terminal to which a wiring is electrically connected, wherein
the bottom wall includes:a first bottom portion; anda second bottom portion facing the first bottom portion in the protruding direction,the second bottom portion is configured to hold the connection terminal in a state where a portion of the connection terminal is exposed to an outside of the second bottom portion, and
the first bottom portion is configured to cover the portion of the connection terminal. - The fire detector base of claim 2, wherein
the connection terminal includes:a terminal part to which the wiring is electrically connected; anda spring configured to hold the wiring in cooperation with the terminal part by pinching the wiring between the spring and the terminal part,the first bottom portion includes a rib protruding toward the second bottom portion, and
the connection terminal is configured to be in contact with the rib in the protruding direction. - The fire detector base of any one of claims 1 to 3, wherein
the circumference wall includes a knockout part,
the knockout part includes:two side portions extending from the end of the circumference wall in the protruding direction; anda wall portion disposed between the two side portions to be adjacent to the two side portions, andeach of the two side portions is smaller in thickness than the wall portion. - The fire detector base of any one of claims 1 to 4, wherein
the water collecting surface includes at least a part surrounding the first surface. - The fire detector base of any one of claims 1 to 5, wherein
the pedestal further includes a groove recessed with respect to the first surface, at least a part of the groove being constituted by the water collecting surface. - A fire detector, comprising: the fire detector base of any one of claims 1 to 6; and the detector body.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2016182335A JP6667160B2 (en) | 2016-09-16 | 2016-09-16 | Fire detector base and fire detector |
PCT/JP2017/031290 WO2018051795A1 (en) | 2016-09-16 | 2017-08-31 | Fire sensor base and fire sensor |
Publications (3)
Publication Number | Publication Date |
---|---|
EP3514775A1 true EP3514775A1 (en) | 2019-07-24 |
EP3514775A4 EP3514775A4 (en) | 2019-09-11 |
EP3514775B1 EP3514775B1 (en) | 2020-10-28 |
Family
ID=61619960
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP17850698.6A Active EP3514775B1 (en) | 2016-09-16 | 2017-08-31 | Fire detector base and fire detector |
Country Status (3)
Country | Link |
---|---|
EP (1) | EP3514775B1 (en) |
JP (1) | JP6667160B2 (en) |
WO (1) | WO2018051795A1 (en) |
Families Citing this family (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP7208729B2 (en) * | 2018-07-24 | 2023-01-19 | ホーチキ株式会社 | fire detection device |
JP7433062B2 (en) | 2020-01-24 | 2024-02-19 | ニッタン株式会社 | sensor |
Family Cites Families (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH044315Y2 (en) * | 1985-08-24 | 1992-02-07 | ||
JP3210868B2 (en) * | 1996-10-11 | 2001-09-25 | ニッタン株式会社 | Ionized smoke detector |
JP5914847B2 (en) * | 2011-06-22 | 2016-05-11 | パナソニックIpマネジメント株式会社 | Fire detector |
JP5942139B2 (en) * | 2011-06-22 | 2016-06-29 | パナソニックIpマネジメント株式会社 | Fire detector |
JP6350934B2 (en) * | 2014-02-12 | 2018-07-04 | パナソニックIpマネジメント株式会社 | Combined fire detector |
-
2016
- 2016-09-16 JP JP2016182335A patent/JP6667160B2/en active Active
-
2017
- 2017-08-31 EP EP17850698.6A patent/EP3514775B1/en active Active
- 2017-08-31 WO PCT/JP2017/031290 patent/WO2018051795A1/en unknown
Also Published As
Publication number | Publication date |
---|---|
JP6667160B2 (en) | 2020-03-18 |
WO2018051795A1 (en) | 2018-03-22 |
EP3514775B1 (en) | 2020-10-28 |
JP2018045653A (en) | 2018-03-22 |
EP3514775A4 (en) | 2019-09-11 |
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