FIELD OF THE INVENTION
This invention relates to lighters (igniter) that drive a piezoelectric unit by operation of an operating component and that emit a flame from the tip of a swingarm that extends from the body, and especially relates to folding lighters onto each of which is installed a swingarm with ability to swing to the lighter body.
BACKGROUND OF THE INVENTION
Formerly, lighters have been used for such as lighting gas burners and solid fuels and for igniting fireworks. As an example of such a lighter, a lighter having a tip pipe (extension) extended in a rod-shape from the body for emitting a flame is well known (Japanese Examined Patent H9-133359 (FIG. 1)). This lighter possesses in its body a gas tank and a piezoelectric unit operated by an operating component, and by operating the operating component a flame is emitted from the tip of the tip pipe. Due to the separation of the tip of the tip pipe emitting the flame from the body held by the hand, a lighter of this form can safely and easily ignite objects without burning the user, but there is a problem in that comparatively more space is required to store the lighter due to lengthening of the lighter overall form.
To solve this problem, there are well known lighters that can be made compact by extending and collapsing from the body a rod-shaped extension for emitting the flame or can be folded when not in use. For example, a folding type lighter with a rod-shaped tip component installed with swinging enabled to one end of the body is known (Japanese Examined Patent H5-14172 (FIGS. 2 and 3)). This lighter normally retains the tip component (extension tube) in a folded and swing-enabled position against the body, and at time of use (time of igniting) allows utilization by extending from the body through swinging of the tip component. The operating component is installed on the body so as to be positioned between it and the folded tip component.
DESCRIPTION OF THE INVENTION
With the lighter disclosed in Patent Citation 2, there is a danger of injury to a finger or object by compression between the extension tube and the operating component at time of folding the extension tube, and there is danger of ignition by inadvertent pressing of the button.
This invention considers the above described concerns and has as its purpose the providing of a safe folding lighter that does not inflict injury or damage to a finger or object by compression between the swingarm and lighter body at time of folding the swingarm to make compact, and prevents at such time ignition by inadvertent pressing of the button.
The folding lighter of this invention is a folding lighter comprising a body that houses a fuel tank and a piezoelectric unit, and possesses at the side surface an operating component exposed to the outside for operating with approximate contemporaneousness the
piezoelectric unit and a fuel supply valve that controls supply of fuel from the fuel tank,
and a swingarm connected with free swinging to one end of the body, and housing a flame emission nozzle in the vicinity of the opposite end, and opening and closing freely between a housing position being folded against the side surface of the body and a utilizing position being opened at 90 degrees or more from the body,
and housing in the body and the swingarm a flexible fuel conduit connected at one end to the fuel tank and connected at the opposite end to the flame emission nozzle,
and characterized by further possessing a safety mechanism for preventing folding of the swingarm when a foreign object such as a finger interposes between the swingarm and the operating component at time when the swingarm is being folded to the housing position,
with the safety mechanism possessing a swing preventer axially supported by a axle socket within the body and that oscillatingly shifts corresponding to operation of the operating component,
and with the swing preventer possessing a first arm projected to a position that intervenes within the movement range of the operating component to be depressed by a pressing inward operation of the operating component, and possesses on the side opposite of the axle socket a second arm that prevents the swingarm from being folded as a section of the swingarm shifts within a range for shifting in response to folding movement of the swingarm, at time when the first arm is pressed by the pressing inward operation of the operating component.
In addition, the second arm can be structured to mate with a portion of the swingarm so as to push open the swingarm by additional pressing of the operating component when the operating component is further pressed from the position preventing its folding.
The folding lighter of this invention achieves the following effects because it possesses a safety mechanism for preventing the swingarm from being folded at the interposition of a foreign object such as a finger when the swingarm connected for free swinging to one end of the body is being folded to the stored position, with such safety mechanism possessing a first arm extending to a position that intervenes with the operating component and a second arm that prevents the swingarm from being folded when the first arm is pressed by the operating component.
Specifically, at folding of the swingarm, because the swing preventer prevents the swingarm from being folded if a finger or object is interposed between the swingarm and the pushbutton, there is no injury to the finger or damage to the object. In addition, because the swingarm cannot be folded, the pushbutton cannot be inadvertently pressed by a finger or object and therefore there is no danger of ignition.
In addition, when the second arm is structured to mate with one portion of the swingarm so as to push open the swingarm by the further pressing of the operating component at time when the operating component is pressed further from a position preventing the swingarm from being folded, even if a finger or object is relatively forcefully interposed between the swingarm and the body, there is enabled additional and reliable preventing of inadvertent ignition, and there is enabled reliable preventing of injury or damage to fingers or objects.
BEST MODE OF PRACTICING THE INVENTION
The following section references the attached drawings while describing in detail a preferred implementation form for the folding lighter (hereafter, simply referred to as lighter) of this invention. FIG. 1 is a perspective drawing showing lighter 1 in the folded form. FIG. 2 is a perspective drawing showing lighter 1 in the form designed to enable use. As shown in FIGS. 1 and 2, lighter 1 possesses body 2 for grasping with a hand and swingarm 4 axially supported to swing freely at one end of body 2. Within body 2 are housed later described piezoelectric unit 102 (FIG. 8) and fuel tank 106 (FIG. 8). Swing-mount 6 is formed at one end of body 2, and swing-mount mate 10 is formed on one end of swingarm 4 and mounted to swing-mount 6 for support by swing-mount 6. Operating button 8 (operating component) is installed in body 2 to be exposed from opening 32 in the vicinity of swing-mount 6. Pressing this operating button 8 with a finger causes ignition.
In sidewall 14 of body 2 (FIG. 2), inspection window 12 is formed to enable checking of the remaining quantity of a fuel such as a liquefied gas. In addition, opening 18 is formed in body 2, from which protrudes adjustor protrusion 16 for adjusting the length of the flame to be emitted. In addition, pipe assembly 20 is housed in swingarm 4 with ability to slide in the lengthwise direction of swingarm 4. When swingarm 4 is in the closed position (housing position), specifically when it is folded to be overlapped by body 2 as shown in FIG. 1, pipe assembly 20 is in a condition pulled within swingarm 4. Conversely, when swingarm 4 is in the open position (utilizing position), specifically when it is opened to an angle of 90 degrees or more in relation to body 2 as shown in FIG. 2, tip tube 20a of pipe assembly 20 is in a condition projected from exposure port 60b of leading edge 4a of swingarm 4.
Body 2 possesses two reciprocally engaging components, specifically half-body 2a and half-body 2b, and it possesses full-body cover 2c that maintains the reciprocally combined condition of half-bodies 2a and 2b. The following section describes half-bodies 2a and 2b and full-body cover 2c by referencing FIGS. 3˜5. FIG. 3 is a perspective drawing showing half-body 2a which is the forward facing half-body in FIGS. 1 and 2, with FIG. 3(a) displaying the half-body 2a shape as seen from the outside and FIG. 3(b) displaying the half-body 2b shape as seen from the inside. FIG. 4 shows half-body 2b which is the half-body opposite half-body 2a of FIG. 3, with FIG. 4(a) being a front view drawing as seen from the inside and FIG. 4(b) being a perspective drawing also as seen from the inside. FIG. 5 shows full-body cover 2c, with FIG. 5(a) being a perspective drawing and FIG. 5(b) being a perspective drawing displaying the cross-section along line 5b-5b of FIG. 5(a).
As shown in FIG. 3, half-body 2a is integrally formed from a synthetic resin, for example, and it possesses cylindrically shaped axle 6a (swing axle) structured as part of swing-mount 6. At cylindrically shaped surface 28a of axle 6a, the half-body possesses circular opening 24a, cylindrically shaped axle socket 30a formed in succession with opening 24a, and annular wall (cylindrical wall) 26a formed at the outer side of axle socket 30a and along the same axis as axle socket 30a. In main section 22a, cutout 32a is formed to house the upper portion of operating button 8. Main section 22a possesses upper wall 34a and lower wall 36a extending approximately in parallel. At upper wall 34a and lower wall 36a flange sections 38a and 39a are integrally formed to extend on opposite sides of axle 6a. The outer surface of main section 22a is formed with channel 37a in a vertical direction for use in positioning full-body cover 2c. Furthermore, the vertical orientation shown here applies to the drawings referenced in the description.
This section describes in further detail axle 6a in reference to FIG. 3(b). At outer surface 3 la of axle socket 30a are formed two ribs, specifically stopping sections 40a and 41a, at a prescribed interval. In the inner direction of axle 6a and between outer peripheral surface 31a and each of stopping sections 40a and 41a are formed notches 42a and 43a. In addition, at the side of annular wall 26a toward main section 22a, cutout 44a is formed axially inward. Moreover, at the inner surface of main section 22a, protrusion 46a is formed to protrude inward in the vicinity of cutout 44a, and in a separated position at the opposite end of main section 22a from protrusion 46a is formed socket seat 50a possessing inward facing elliptical recess 48a. Socket seat 50a is the shaft receptacle for operating button 8.
This section describes the opposing half-body 2b by referencing FIG. 4. Half-body 2b is a shape approximately reflective of half-body 2a, and it possesses axle 6b and main section 22b. Axle 6b possesses annular wall (cylindrical wall) 26b of the same outer diameter as axle 6a. Stopping sections 40b and 41b are on outer peripheral surface 31b of axle socket 30b and correspond to stopping sections 40a and 41a. Furthermore, mating section 40 is named to incorporate stopping sections 40a and 41a and stopper 41 is named to incorporate stopping sections 40a and 41a. In difference to axle socket 30a, within the periphery of axle socket 30b there are formed three reciprocally separated notches 30c, 30d and 30e. In main body 22b, cutout 32b is formed corresponding to cutout 32a. Moreover, cutouts 32a and 32b enable structuring of single opening 32 for receiving operating button 8 at time of unifying main sections 22a and 22b (FIGS. 1 and 2). Below cutout 32b, protrusion 46b and socket seat 50b are respectively identical to and corresponding to previously described protrusion 46a and socket seat 50a. In upper wall 34b and lower wall 36b of main section 22b are formed flange sections 38b and 39b in positions corresponding to previously described flange sections 38a and 39a. Furthermore, axle socket 50 is named to incorporate socket seat 50a and socket seat 50b. Support sections 38 and 39 are named to incorporate respectively flange sections 38a and 38b and flange sections 39a and 39b. Moreover, channel 37b is formed in main section 22b of half-body 2b corresponding to channel 37a.
This section describes full-body cover 2c by referencing FIG. 5. Full-body cover 2c is used by first reciprocally mating the inner surfaces of previously described half-bodies 2a and 2b and then fitting full-body cover 2c over half-bodies 2a and 2b from the opposite end of the combined half-bodies 2a and 2b. Full-body cover 2c possesses opening 54 formed by the pair of edges 52 and 52 curved upward at one end. As shown in FIG. 5(b), within full-body cover 2c are disposed to protrude ribs 56a, 56b and 56c for positioning previously described piezoelectric unit 102 and fuel tank 106 at time of housing (FIG. 8). Rib 56a is formed as a pair of ribs at left and right in the lengthwise direction of full-body cover 2c, and similarly rib 56b is formed as a pair of ribs at top and bottom in the lengthwise direction (FIG. 8). Furthermore, respective opposite side ribs 56a, 56b and 56c are not shown in FIG. 5(b). Rib 56c is formed vertically at the furthest inner section. In addition, at each inner surface of sidewalls 14, bead 58 is formed for mating respectively to channels 37a and 37b of half-bodies 2a and 2b at time of receiving previously described half-bodies 2a and 2b. Bead 58 is shown for only one side in FIG. 5. By mating beads 58 to channels 37a and 37b, full-body cover 2c is positioned and also fixed.
This section describes in detail swingarm 4 mounted for swinging to body 2 structured of half-bodies 2a and 2b and full-body cover 2c as explained above. FIG. 6 shows swingarm 4, with FIG. 6(a) being a perspective drawing and FIG. 6(b) being a front view drawing. Swingarm 4 possesses swing-mount mate 10 and long protective cover 60 integrally formed to swing-mount mate 10. Protective cover 60 possesses cavity 62 passing through the lengthwise direction within protective cover 60. Protective cover 60 is maintained to allow swinging of swingarm 4 without touching tip tube 20a of pipe assembly 20. Swing-mount mate 10 is mounted for swinging by interposition support with free swinging between axles 6a and 6b of half-bodies 2a and 2b. Swing-mount mate 10 possesses annular wall (cylindrical wall) 26c of approximately the same outer diameter as axles 6a and 6b. At annular wall 26c, annular step 64 is formed for crowning of annular walls 26a and 26b of body 2. Furthermore, at annular wall 26c and annular step 64, opening 66 is formed is formed for passage between the interior of annular wall 26c and cavity 62 of protective cover 60.
Within annular wall 26c, arching inner wall (outer cylinder) 70 is integrally supported on the same axis as annular wall 26c by three support walls 68a, 68b and 68c reciprocally separated in the circumferential direction. A cylindrical space is formed between arching inner wall 70 and annular wall 26c. Support walls 68a and 68c are positioned symmetrically to bind the center arching inner wall 70, and support walls 68b is positioned at the lower end of arching inner wall 70 midway between and 68c. Furthermore, previously described axle sockets 30a and 30b are named the inner cylinder in relation to the outer cylinder. The upper portion of arching inner wall 70 is a cutout form that specifically becomes opening 66.
At arching inner wall 70, two protrusion sections 72a and 72b are formed to protrude facing the body 2 side. Protrusion section 72a is formed in the lower section vicinity of support wall 68a and protrusion section 72b is formed in a position approximately identical to that of support wall 68c. Swelled protrusions 73 are formed on the leading edges of these protrusion sections 72a and 72b facing inward. At assembly of swingarm 4 and body 2, these swelled protrusions 73 mate at three prescribed angles with notches 30c, 30d and 30e of axle socket 30b of body 2. Specifically, at swingarm 4 operation, this imparts a clicking sensation at the swingarm 4 folded position, the opened utilization position, and a midpoint position. In this way, for lighter 1 in any of various positions or attitudes, there is enabled stable utilization and prevention of swingarm 4 position changes from these prescribed angles.
In addition, as shown in FIG. 6, at the lower side of annular wall 26c, specifically at support wall 68b, protrusion (thick section) 74 is formed. Protrusion 74 is formed along the edge at the body 2b side of annular wall 26c and extends from the lower end of annular wall 26c in both directions toward support wall 68a and support wall 68c. Protrusion 74 extends slightly toward support wall 68a and extends more than half the distance along the circumference for support walls 68b and 68c. In addition, arching inner wall 70 is established with rib 76 protruding at a position approximately identical to that of support wall 68. Furthermore, arching inner wall 70 is formed with slot 78 directly below rib 76.
Protective cover 60 possesses metal cap 60a having exposure port 60b. By using latching hooks not shown in the drawing, for example, cap 60a is mated and latched to a recess or hole (not shown in drawing) established in protective cover 60. Furthermore, it is acceptable to use a thermally insulating material such as nylon for cap 60a.
This section describes pipe assembly 20 by referencing FIG. 7, with FIG. 7(a) being a perspective drawing and FIG. 7(b) being a component cross section drawing of the region shown by circle 7b in FIG. 7(a), and both showing the condition in which the gas pipe of the nozzle is inserted into pipe assembly 20. Pipe assembly 20 possesses tip tube 20a and tip pipe 20b on which tip tube 20a is installed. Tip tube 20a is of cylindrical shape, and it possesses flame port 82 for emitting a flame from the tip. Tip pipe 20b is formed of a synthetic resin, for example, and it possesses plate-shaped extension 86 integrally formed to cylinder 84 onto which is installed leading edge tube 20a. The tip of extension 8, specifically the end facing the body, is formed in a T-shape. Specifically, cylindrical protrusion 88 projects in opposing directions perpendicular to the lengthwise direction of pipe assembly 20 and to channels at both sides. As shown in FIG. 7(b), nozzle holder 90 is formed to pass through cylinder 84 in tip pipe 20b and to be stored within tip tube 20a. At tip tube 20a possessing cylinder 84 and nozzle holder 90, space 92 is formed in the lengthwise direction of tip tube 20a. In this space 92 is disposed nozzle (flame emitting nozzle) 94 and gas pipe 96 linked to nozzle 94.
Nozzle 94 possesses nozzle tip 94a and nozzle body 94b into the tip of which is inserted nozzle tip 94a. This nozzle 94 is fixed to the leading edge of nozzle holder 90 so that nozzle tip 94a is at the outer side of nozzle holder 90. Gas pipe (flexible fuel conduit) 96 is linked by linking pipe 98 to nozzle body 94b of nozzle 94. Nozzle cover 100 is installed at the outer side leading edge of nozzle holder 90 to protect nozzle tip 94a.
This section describes in further detail lighter 1 by referencing FIGS. 8 and 9. FIG. 8 is a cross section drawing along line 8-8 of lighter 1 shown in FIG. 1, and FIG. 9 is a cross section drawing along line 9-9 of lighter 1 shown in FIG. 1. As shown in FIG. 8, swingarm 4 is overlapping body 2 in the closed condition, specifically the folded condition. Within body 2 is disposed piezoelectric unit 102, housing 104 maintaining piezoelectric unit 102, and fuel tank 106. Piezoelectric unit 102 possesses sliding component 102a that is pressed for piezoelectric unit 102 to generate electricity. Fuel tank 106 is a cylindrically square component structured to be installed and fixed in housing 104 on the opposite side of piezoelectric unit 102. Piezoelectric unit 102 and fuel tank 106 are positioned and retained by previously described ribs 56a, 56b and 56c as well as support sections 38 and 39. In addition, operating button 8 of body 2 is axially supported for free swinging by axle socket 50 so as to face opening 32 of body 2.
This section describes operating button 8 by additionally referencing FIG. 10. FIG. 10 shows operating button 8, with FIG. 10(a) being a perspective drawing, FIG. 10(b) being a top view drawing, FIG. 10(c) being a side view drawing, and FIG. 10(d) being a front view drawing. Operating button 8 possesses upper wall 108 that in a top view is of transforming shape from circular to elliptical by forming a large arching shape on one side and small arching shape on the other side. The circumference of upper wall 108 is encompassed by peripheral wall 110, and the inner side of peripheral wall 110 becomes a cavity. Within peripheral wall 110, plate 8a is disposed to project to the side direction, and one side of plate 8a, specifically toward the half-body 2b side, L-shaped mating hook (hook component) 8b is formed to extend with upward inclination. At the leading edge of mating hook 8b, protrusion 112 is formed facing inward.
Plate 8a contacts against the lower edge of one side of opening 32 of body 2 with operating button 8 under the opening. In this way, operating button 8 does not dislodge outward from opening 32. In addition, at the other side of peripheral wall 110, the pair of cylindrical shafts 8c used for axle support from axle socket 50 are disposed projecting to a position corresponding to axle socket 50. Moreover, as shown in FIG. 8, arm 8e is integrally fixed downward from the other side of upper wall 108. At the lower side of this arm 8e, curved protrusion 116 is formed to face sliding component 102a.
When operating button 8 is axially supported by axle socket 50, previously described mating hook 8b is positioned at swing-mount 6. In addition, curved protrusion 116 of arm 8e is positioned to contact sliding component 102a or the vicinity thereof, with sliding component 102a in a condition being projected by outward biasing of a spring. Moreover, shaft 8c is axially supported with play in elliptically shaped axle socket 50, and it is in a condition enabling movement in a horizontal direction to the opposite side. It is clear that at swing-mount 6, circular axle sockets 30a and 30b of half-bodies 2a and 2b are inserted for free swinging within arching inner wall 70 of swingarm 4.
In FIGS. 8 and 9, there is clearly shown the condition in which swingarm 4 is axially supported by body 2. Specifically, arching inner wall 70 of swingarm 4 is axially supported for free swinging by axle sockets 30a and 30b of half-bodies 2a and 2b. Furthermore, axle socket 30b appears in FIG. 8, and axle socket 30a appears in FIG. 9. In addition, sleeve 146 is inserted and fixed at the inner side of unified axle sockets 30a and 30b. Sleeve 146 possesses annular recess 147 at both sides (FIGS. 1 and 2). Additionally, annular step 148 is formed at the outer peripheral edge of respective openings 24a and 24b of half-bodies 2a and 2b, as shown in FIG. 3(a) and FIG. 13. When sleeve 146 is inserted into axle sockets 30a and 30b, annular recess 147 of sleeve 146 is mated to annular step 148, and along with fixing of sleeve 146 within axle sockets 30a and 30b, it supports half-bodies 2a and 2b in a manner that half-bodies 2a and 2b will not be separated.
This section describes the positional relationship between mating hook 8b and protrusion 74 of swingarm 4 within swing-mount 6. FIG. 12 is a cross-sectional perspective drawing showing swing-mount 6 and related vicinity at time when swingarm 4 is in closed condition. Mating hook 8b is positioned in the edge vicinity of annular wall 26c, and protrusion 112 of mating hook 8b is positioned in the edge vicinity of the inner side of annular wall 26c of swingarm 4. Therefore, protrusion 74 formed below the edge of annular wall 26c is positioned as separated downwards from mating hook 8b.
As shown in FIGS. 8 and 9, previously described pipe assembly 20 is disposed within protective cover 60 of swingarm 4, and extension 86 is positioned at swing-mount 6 after passage through opening 66 of swingarm 4. Therefore, protrusion 88 of extension 86 is positioned at one end of stopping sections 40a and 40b, and is mated to stopping sections 40a and 40b, specifically mating section 40. At the time of this condition, even at attempt to pull tip tube 20a outward, it cannot be withdrawn due to protrusion 88 being mated to mating section 40, and it maintains a compact condition. Moreover, only stopping section 40b is visible with FIG. 8, but stopping section 40a is positioned identically at the forward side. At this time, protrusion 88 is positioned between stopping sections 40a and 40b. In this condition, pipe assembly 20 is not protruding to the outside from protective cover 60 at the opposite end but is in a condition withdrawn into protective cover 60.
This section further describes lighter 1 by referencing FIG. 9. At housing 104 in which is installed fuel tank 106, connector 118 is installed and connected to gas pipe 96 for supplying fuel to gas pipe 96. Gas pipe 96 passes through swing-mount 6 and reaches pipe assembly 20. Lever (swing preventer) 120 is disposed in a position corresponding to notch 8d of operating button 8. The following describes this lever 120 by additionally referencing FIGS. 11 and 13. FIG. 11(a) is a perspective drawing, FIG. 11(b) is a top view drawing, FIG. 11(c) is a right side view drawing, FIG. 11(d) is a front view drawing, and FIG. 11(e) is a bottom view drawing. In addition, FIG. 13 is a cross-sectional perspective drawing showing swing-mount 6 and the related vicinity.
Lever 120 is of a roughly flat and long shape, and cylindrical spindle 120a is disposed projecting in a sideways direction at side edge 124a in the vicinity of one end. As shown in FIG. 11(a), the section extending toward the side of operating button 8 from spindle 120a is named first arm 121, and the section extending toward swing-mount 6 is named second arm 123. In addition, at upper surface 126 and lower surface 128 of lever 120, curved protrusion 120c is formed having joint position with spindle 120a. Moreover, at second arm 123, rectangular flange 120b is disposed projecting toward the side on the opposite side of spindle 120a and at the lower surface 128 of side edge 124b. On first arm 121 is formed rectangular plate 120d which is larger than rectangular flange 120b. Lever 120 is axially supported by spindle 120a in axle socket 122 (FIG. 3(b)), having rectangular plate 120d at the side toward operating button 8. It is then supported by compression coil spring (hereafter, simply referred to as spring) 130 disposed at the half-body 2a side. In the lighter 1 assembled condition, notch 8d of operating button 8 is mated to rectangular plate 120d of first arm 121. Leading edge 120e of second arm 123 incorporating rectangular flange 120b is mated to slot 78 of arching inner wall 70 of swingarm 4.
This section describes the condition at utilization of lighter 1 structured in this way by reference to FIGS. 14 and 15. FIG. 14 is a vertical cross-section drawing similar to FIG. 6 and showing a condition in which swingarm 4 of lighter 1 is partially opened. FIG. 15 is a main component enlarged cross section drawing showing swing-mount 6, operating button 8 and the related vicinity. Referencing FIG. 15, when swingarm 4 is swung for opening, protrusion 88 of pipe assembly 20 separates from mating section 40 and swings clockwise per FIG. 14. This swingarm 4 position is a condition at which swingarm 4 has been opened from the closed position. When in this condition, if there is by such as application of external force inadvertent swinging of swingarm 4 in the direction for closing while a foreign object 134 such as a finger is positioned between operating button 8 and swingarm 4, it will result in pressing of operating button 8 downward as shown by arrow 136.
At this time, lever 120 mated with operating button 8 swings counterclockwise per FIG. 14. As shown in detail in FIG. 15, leading edge 120e of lever 120 is mated to slot 78 of arching inner wall 70 of swingarm 4. Then, at pressing of operating button 8 downward by further action of swingarm 4, operating button 8 presses further downward rectangular plate 120d of lever 120. The result is that leading edge 120e of lever 120 biases upward rib 76 formed with adjacent contact above slot 78. In this way, protective cover 60 of swingarm 4 is prevented from shifting further downward. At this time, operating button 8 enters a condition in which it is hard to press due to resistance of lever 120. In this condition, arm 8e of operating button 8 is pressing sliding component 102a of piezoelectric unit 102 to an extent but not reaching the ignition point.
The following describes the positional relationship between mating hook 8b of operating button 8 disposed at the opposite side of lever 120 and protrusion 74 formed on annular wall 26c of swingarm 4 by referencing FIG. 16. FIG. 16 is a cross-section drawing similar to FIG. 8 and showing a lighter 1 cross-section for a position differing from that of FIG. 14, with FIG. 16(a) being a cross-section of lighter 1 in a condition identical to that of FIG. 14, and FIG. 16(b) being a main component cross-section showing the condition when operating button 8 is further pressed. As shown in FIG. 16(a), protrusion 74 is positioned in the vicinity of mating hook 8b, but it has not reached the point of mating with mating hook 8b. By pressing operating button 8, arm 8e of operating button 8 slightly presses sliding component 102a.
In this condition, when swingarm 4 is pressed further downward, along with swingarm 4 opening in the counterclockwise direction per FIG. 16(b), as previously described, mating hook 8b of operating button 8 mates to protrusion 74. Specifically, protrusion 74 is inserted between protrusion 112 of mating hook 8b and annular wall 26c. At this time, arm 8e of operating button 8 presses further on sliding component 102a, but not to the point of ignition. In order to ignite, shaft 8c of operating button 8 must shift within axle socket 50 to the right per FIG. 16(c), and sliding component 102a must be further pressed by the shifting of operating button 8. However, protrusion 112 of mating hook 8b will not allow shifting because it is mated to protrusion 74. In this way, a locking structure is formed by mating hook 8b and protrusion 74. Accordingly, when swingarm 4 is slightly opened, there is prevention of inadvertent ignition from pressing of operating button 8 by interposition by swingarm 4 of foreign object 134 such as a finger between swingarm 4 and body 2.
This section describes the condition when swingarm 4 is further opened by referencing FIG. 17. FIG. 17 is a partial cross-section drawing showing the condition in which swingarm 4 is opened at an approximate right angle. In this condition, swelled previously described protrusions 73 of protrusion sections 72a and 72b are respectively mated to notches 30d and 30e, the position of swingarm 4 is maintained in the condition, and protrusion 74 is separated from mating hook 8b. Accordingly, it is possible to consider attempting ignition by pressing operating button 8, but ignition is not normally performed in this position. Even in the event of inadvertent ignition, the flame emitted from flame port 82 of swingarm 4 will not blow near the hand holding body 2 and cause a burn. The important factor is that, with swingarm 4 in this position, previously described protrusion 88 of pipe assembly 20 is at a point contacting stopper 41 of body 2. Accordingly, if further opening is caused by swinging swingarm 4 in the counterclockwise direction, pipe assembly 20 within protective cover 60 will start sliding to cause protruding of pipe assembly 20 from protective cover 60 because protrusion 88 is mated against stopper 41.
With such established, this section describes the condition in which swingarm 4 is further opened by referencing FIGS. 18 and 19. FIG. 18 is a vertical cross-section drawing of lighter 1 showing the condition in which swingarm 4 has been opened approximately 150 degrees, and FIG. 19 is a vertical cross-section drawing of lighter 1 showing a cross-section of a position that differs from that of FIG. 18. As shown in FIGS. 18 and 19, with protrusion 88 of pipe assembly 20 in contact with stopper 41, because swingarm 4 will be swung, tip tube 20a which will become the nozzle tip 94a edge of pipe assembly 20 enters a condition in which it has protruded from exposure port 60b of protective cover 60 (FIG. 6(a)). In this condition, at time of ignition, even if tip tube 20a contacts an external foreign object such as gas equipment not shown in the drawing, because protrusion 88 of pipe assembly 20 is in contact against stopper 41, tip tube 20a will not be forced into protective cover 60. Accordingly, there is little danger that the flame emitted from flame port 82 will be applied to protective cover 60. As shown in FIG. 18, the lower edge of notch 8d of operating button 8 contacts against protrusion 46a of body 2 and prevents swinging beyond this point. In FIG. 19, the shift amount of sliding component 102a does not attain the sliding amount required to generate voltage.
When horizontally shifting operating button 8 to the right from this condition as shown by arrow 138 in FIG. 20, there can be obtained the prescribed sliding component 102a sliding amount required for ignition. FIG. 20 is a component enlarged cross-section drawing showing the condition when operating button 8 has been caused to slide. As shown in FIG. 20, by sliding operation of operating button 8, arm 8e presses sliding component 102a of piezoelectric unit 102 for a prescribed distance d, and piezoelectric unit 102 generates electricity. This enables causing of an electric discharge in the vicinity of nozzle tip 94a. If there is an attempt to close body 2 by swinging clockwise per FIG. 20 swingarm 4 that is emitting a flame, protrusion 74 of swingarm 4 will mate with protrusion 112 of mating hook 8b and generate resistance, preventing closing to less than a prescribed angle. Accordingly, it is possible to prevent such as burns to the hand holding body 2 and scorching of clothing.
In addition, operation of the fuel supply valve is linked to shifting of sliding component 102a. This fuel supply valve operation is described by referencing FIG. 21. FIG. 21 is a cross-section drawing along line 21-21 of FIG. 8 and shows the operating condition of the fuel supply valve, with FIG. 21(a) showing the condition prior to ignition operation, and with FIG. 21(b) being a component cross-section drawing showing the condition after ignition operation. Sliding component 102a is positioned at the side of the fuel supply valve, and it possesses lever depressor 102b integrally formed with sliding component 102a along the sliding direction of sliding component 102a. This lever depressor 102b shifts with the shifting of sliding component 102a. Additionally, fuel supply valve 142 is disposed at housing 104. Mated to this fuel supply valve 142 is approximately L-shaped lever 144 axially supported for free oscillation to shaft 145 within the space shown. Lever 144 possesses mating arm 144a mated to fuel supply valve 142 and drive arm 144b positioned in the vicinity of lever depressor 102b.
In the condition in which sliding component 102a of piezoelectric unit 102 is not being pressed to the right per FIG. 21, drive arm 144b protrudes within the pathway of level depressor 102b. When sliding component 102a is pressed by arm 8e of operating button 8, drive arm 144b is pressed by level depressor 102b and moves clockwise per FIG. 21. This swings mating arm 144a clockwise, shifts fuel supply valve 142 to the right, and enables emitting of gas. Gas emitted from fuel supply valve 142 is conducted through gas pipe 96 to nozzle 94. In addition, power line 140 (FIG. 8) is routed from piezoelectric unit 102 to nozzle 94 and the vicinity of nozzle tip 94a of tip tube 20a, and it releases an electric discharge to ignite the gas emitted from nozzle tip 94a. These structural components are widely known and therefore a detailed description is omitted.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective drawing showing the folded condition of the folding lighter being one example of this invention.
FIG. 2 is a perspective drawing showing the folding lighter of FIG. 1 is a condition opened and capable of utilization.
FIG. 3 is a perspective drawing showing the forward side half-body of FIGS. 1 and 2, with (a) showing the half-body as seen from the outer side and (b) showing the half-body as seen from the inner side.
FIG. 4 shows the opposite side half-body from that of FIG. 3, with (a) being a front view drawing as seen from the inner side and (b) being a perspective as seen from the inner side.
FIG. 5 shows the full-body cover, with (a) being a perspective drawing and (b) being a perspective drawing showing the cross-section along line 5b-5b of FIG. 5(a).
FIG. 6 shows the swingarm, with (a) being a perspective drawing and (b) being a front view drawing.
FIG. 7 shows the pipe assembly, with (a) being a perspective drawing and (b) being a component cross-section drawing of the region shown by circle 7b in FIG. 7(a) and showing the nozzle and gas pipe within the pipe assembly for the folded condition.
FIG. 8 is a cross-section along line 8-8 of the folding lighter shown in FIG. 1.
FIG. 9 is a cross-section along line 9-9 of the folding lighter shown in FIG. 1.
FIG. 10 shows the operating button, with (a) being a perspective drawing, (b) a top view drawing, (c) a side view drawing, and (d) a front view drawing.
FIG. 11 shows the lever, with (a) being a perspective drawing, (b) top view drawing, (c) a right side view drawing, (d) a front view drawing, and (e) a bottom view drawing.
FIG. 12 is a component cross-sectional perspective drawing showing the swing-mount and related vicinity in condition when the swingarm is closed.
FIG. 13 is a component cross-sectional perspective drawing showing the swing-mount and related vicinity.
FIG. 14 is a vertical cross-section drawing similar to FIG. 6 and showing the condition in which the swingarm of the folding lighter is slightly opened.
FIG. 15 is a main component enlarged cross-section drawing showing the swing-mount, operating button and the related vicinity.
FIG. 16 is a cross-section drawing similar to FIG. 8 and showing a cross-section of the folding lighter for a position differing from that of FIG. 14, with (a) being a cross-section of the folding lighter in a condition identical to that of FIG. 14 and (b) being a main component cross-section drawing showing the condition when the operating button is being further pressed.
FIG. 17 is a component cross-section drawing showing the condition in which the swingarm has been opened to approximately a right angle.
FIG. 18 is a vertical cross-section drawing of the folding lighter showing the condition in which the swingarm has been opened to approximately 150 degrees.
FIG. 19 is a vertical cross-section drawing of the folding lighter showing a cross-section for a position differing from that of FIG. 18.
FIG. 20 is a main component enlarged cross-section drawing showing the condition at time when the operating button has been caused to slide.
FIG. 21 is a cross-section drawing along line 21-21 of FIG. 8 and showing the operating condition of the fuel supply valve, with (a) showing the condition prior to the ignition operation and (b) being a component cross-section drawing showing the condition after the ignition operation.
LEGEND
1 Folding Lighter
2 Body
4 Swingarm
8 Operating Button (Operating Component)
20 Pipe Assembly
26
a,
26
b,
26
c Annular Wall (Cylindrical Wall)
30
a,
30
b Axle Socket (Inner Cylinder)
40 Mating Section
41 Stopper
60
b Exposure Port
70 Arching Inner Wall (Outer Cylinder)
88 Protrusion
94 Nozzle (Flame Emitting Nozzle)
96 Gas Pipe (Flexible Fuel Conduit)
102 Lever (Swing Preventer)
122 Axle Socket
134 Foreign Body
142 Fuel Supply Valve