JP6513531B2 - Portable heat treatment tool - Google Patents

Description

  The present invention relates to a portable heat treatment tool which emits heat at high temperature to perform heat treatment.

  A portable heat treatment tool generally referred to as a heat gun is known (see, for example, Patent Document 1). This portable heat treatment tool has a heat generating device and an air blower, and blows out the air heated to about 600 ° C. at high temperature. This portable heat treatment tool is used in various applications such as bending a resin product, peeling off a coating, and heat shrinking a heat shrink film. For this reason, in the case of a portable heat treatment tool, a plurality of types of nozzle attachments are prepared as a nozzle attachment so as to be detachable from the main body so that the blowout of hot air can be changed according to the application. In addition, in such a portable heat treatment tool, the main body is provided with a removal mechanism for removing the nozzle attachment so that the nozzle attachment can be easily removed without direct contact after the operation. It is done.

International Publication No. 2007/071127

  By the way, in the case of the above-mentioned portable heat treatment tool, there are cases where it is desired to blow the hot air into a narrow space to perform the heat treatment. In such a case, if a long nozzle attachment is attached to blow out the hot air, the temperature of the blown-out hot air drops and it is impossible to perform a sufficient heat treatment. In addition, even if the nozzle attachment is removed and reduced in size to enter into a narrow space, there is also a narrow space in which the nozzle attachment can not be entered with the removed size.

  The present invention has been made in view of such circumstances, and the problem to be solved by the present invention is to remove the nozzle attachment only in the portable heat treatment tool for performing heat treatment by blowing hot air of high temperature. In the above, it is possible to blow out hot air efficiently and perform sufficient heat treatment even for heat treatment in a narrow space where sufficient heat treatment can not be performed.

  In order to solve the above-mentioned subject, the portable heat processing tool concerning the present invention takes the following means. That is, the portable heat treatment tool according to the first aspect of the present invention is a portable heat treatment tool that performs heat treatment by emitting high temperature heat, and includes a main body having a heat generating portion generating heat by electricity and a delivery portion A distal end nozzle portion which is detachable from the main body, and the main body is detachably attached with a detaching mechanism for detaching the distal end nozzle portion from the main body. , Is a configuration. According to the portable heat treatment tool according to the first aspect of the present invention, it is possible to realize slimming of the main body by removing both the tip nozzle portion and the removing mechanism from the main body. By this, the slim main body can be made to enter into a narrow space, high temperature heat can be emitted to a place where the heat treatment is desired, and desired heat treatment can be performed.

  A portable heat treatment tool according to a second aspect of the present invention is the portable heat treatment tool according to the first aspect, wherein the removal mechanism is formed to also serve as a cover covering the periphery of the heat generating portion. , Is a configuration. According to the portable heat treatment tool according to the second aspect of the invention, the removal mechanism is formed to also serve as a cover covering the periphery of the heat generating portion, so that the function as a cover of the heat generating portion is also exhibited while the removal mechanism is attached it can. As a result, the size of the outer shape of the front portion provided with the heat generating portion can be reduced while facilitating the removal of the tip nozzle portion by the removal mechanism, and a portable heat treatment tool easy to handle can be provided.

  A portable heat treatment tool according to a third invention of the present invention is the portable heat treatment tool according to the first or second invention, wherein the dismounting mechanism takes out the dismounting operation when removing the tip nozzle portion. The operation unit is configured to be provided with a finger hook portion extended in a direction intersecting the removal operation direction. According to the portable heat treatment tool according to the third aspect of the present invention, the operation unit for performing the detaching operation at the time of detaching the tip nozzle unit is provided with the finger hook portion projected in the direction intersecting the detaching operation direction ing. As a result, when operating the operation unit, it becomes easy for the finger to be caught by the finger holding unit, which facilitates the removal operation.

It is a perspective view of a heat gun. It is sectional drawing which shows (II)-(II) cross-section arrow in FIG. It is sectional drawing which shows the (III)-(III) cross-section arrow in FIG. It is a perspective view of the heat gun from which the removal mechanism was removed from the tool main body. It is a perspective view of the heat gun which isolate | separated the extrusion cylinder member of the removal mechanism of FIG. It is a perspective view of the heat gun which isolate | separated the operation member of the removal mechanism of FIG.

  Hereinafter, an embodiment for carrying out a portable heat treatment tool according to the present invention will be described with reference to FIGS. 1 to 6. The code | symbol 10 shown to FIGS. 1-6 is a heat gun as a portable heat processing tool which concerns on this invention. FIG. 1 is a perspective view of the heat gun 10 with the nozzle attachment 80 removed from the tool body 11. FIG. 2 shows a (II)-(II) cross-sectional view in FIG. 1, and FIG. 3 shows a (III)-(III) cross-sectional view in FIG. The tool body 11 corresponds to a body according to the present invention. The heat gun 10 will be described with reference to the directions specified in the drawings. The heat gun 10 is an electric power tool for heat treatment used for various applications such as bending of resin products, peeling of coating, and thermal contraction of a thermal shrink film. This heat treatment is performed by blowing out hot air at a high temperature of about 600.degree.

  The heat gun 10 is a hand-held type that is used by holding by hand, and has a pistol shape that is easy to use. The heat gun 10 has a tool body 11 and a nozzle attachment 80. The nozzle attachment 80 corresponds to the tip nozzle portion according to the present invention. The nozzle attachment 80 is detachably attached to the tip of the tool body 11. The tool body 11 is also provided with a removal mechanism 50. The removal mechanism 50 is used to easily remove the nozzle attachment 80 from the tool body 11, as will be described in detail later.

  As shown in FIGS. 1 to 3, the tool body 11 has a pistol-shaped lower portion formed as a grip 20. Above the grip portion 20, a blower unit 30 as a delivery unit is provided. A heat generating unit 40 is provided on the front side of the blower unit 30. In addition, since the removal mechanism 50 is attached to the outer periphery of the heat generating part 40, the heat generating part 40 is hidden and can not be seen in the figure. That is, the removing mechanism 50 is formed to also serve as a cover that covers the periphery of the heat generating portion 40. Further, from the lower end of the grip portion 20, a power cord 28 for supplying power is drawn out. The power cord 28 is connected to a home power supply to supply power to the heat gun 10. In addition, the code | symbol 29 shown in figure is a rubber member for protecting the power supply cord 28 drawn out from the lower end of the grip part 20. As shown in FIG.

  As shown in FIG. 1, the grip portion 20 is formed in a substantially cylindrical shape extending in the vertical direction. The grip 20 is formed by the grip housing 21. The grip housing portion 21 is integrally formed with the air blowing housing portion 31 which houses the air blowing mechanism 35. That is, the grip housing portion 21 and the blower housing portion 31 form an integral main body housing 15. By the way, the main body housing 15 is made of a resin as a material, and has a substantially left and right half housing shape. As shown in FIG. 2, the grip housing portion 21 extends straight while being inclined forward as it goes from the lower portion 201 to the upper portion 202. A grip end 22 is provided on the lower portion 201 of the grip 20.

  The grip end portion 22 has an outer peripheral diameter that is slightly larger than that of a grip end of a baseball bat. The grip end portion 22 has a shape in which the rear side and the front side are appropriately extended. When the heat gun 10 is turned upside down and the grip portion 20 is gripped, the grip end portion 22 prevents the hand gripped from the grip portion 20 from falling off. An operation switch 23 is provided on the rear surface of the grip portion 20. The operation switch 23 is a switch for operating the "strong", "weak" and "power off" of the air volume of the heat gun 10. The operation switch 23 slides in three steps in the vertical direction to perform operations of "strong", "weak" and "power off" of the air volume. Incidentally, in this type of product, the air volume can be switched to 250 (l / min) and air volume 550 (l / min) by switching from the operation switch 23. Inside the grip housing portion 21, a switch substrate 24 is provided. The switch substrate 24 is connected to a controller substrate 37 described later. The power cord 28 is pulled out from the lower end of the grip end portion 22.

  At the upper portion 202 of the grip portion 20, a blower portion 30 is provided in a connected manner. The blower housing portion 31 is connected on the upper side of the grip housing portion 21. The blower housing portion 31 is formed in a substantially cylindrical shape extending in the front-rear direction intersecting the vertical direction in which the grip housing portion 21 extends. A large number of intake holes 33 are provided at the rear of the blower housing portion 31 to allow intake of outside air. The intake hole 33 has an opening shape that communicates the inside and the outside of the blower housing portion 31. A blower mechanism 35 is internally provided in a portion of the blower housing portion 31 connected to the grip housing portion 21.

  The blower mechanism 35 has a motor 351 and a centrifugal fan 353. The motor 351 is a widely used motor and is supplied with power via the controller board 37. The centrifugal fan 353 is attached to a drive shaft 352 of the motor 351. For this reason, the centrifugal fan 353 rotates in response to the rotational drive of the motor 351, and generates a wind as indicated by the reference symbol F. An appropriate air flow guide wall 355 is provided around the centrifugal fan 353. In addition, a controller board 37 is provided on the upper side of the air blowing mechanism 35. The controller board 37 supplies the electric power from the household power supply supplied through the power supply cord 28 to the motor 351 and the heater mechanism 45.

  The controller board 37 receives control signals from the operation switch 23 and the temperature control dial 38, and supplies power to the motor 351 and the heating element 46 based on the received signals. A temperature control dial 38 is provided on the upper side of the controller board 37. The temperature control dial 38 sets an operation surface 39 on the upper surface of the blower housing portion 31 so that the temperature of the hot air blown out to the user can be adjusted. The temperature set by the temperature control dial 38 is transmitted to the controller board 37. The main housing 15 is screw-fastened so that the left and right halves are integrated by four screw portions 34.

  A heat generating unit 40 is provided on the front side of the blower unit 30. As shown in FIGS. 4 to 6, the front end of the main body housing 15 is set as an opening peripheral portion 16. The opening peripheral edge portion 16 is formed in a shape that is projected forward so as to partially cover the rear end portion of the heat generating portion 40. The opening peripheral portion 16 is provided with an engagement recessed groove portion 57 to which a removal mechanism 50 described in detail later can be attached and detached. The engagement concave groove portion 57 is formed such that a concave groove is provided on the circumferential surface. The engagement concave groove portion 57 has a first concave groove portion 571 and a second concave groove portion 572 connected at the rear end of the first concave groove portion 571. The first recessed groove 571 extends in the front-rear direction from the open end edge of the main body housing 15. The second recessed groove portion 572 intersects with the first recessed groove portion 571 in the orthogonal direction, and extends in the circumferential direction.

  In the heat generating portion 40, a heater mechanism 45 is internally provided in the heater housing 41. The heater housing 41 is formed in a metal cylindrical shape. The heater housing 41 is a member separate from the main body housing 15 described above, and is integrally connected to the main body housing 15 at the opening peripheral portion 16 of the main body housing 15. The heater housing 41 is supported by the main housing 15 by sandwiching the substantially left and right halves of the opening peripheral portion 16 of the main housing 15 together. The heater mechanism 45 is internally provided in the heater housing 41. In addition, an outer peripheral surface 42 to which the removal mechanism 50 can be attached is formed outside. The outer circumferential surface 42 has a smooth cylindrical circumferential surface. Further, the front end of the heater housing 41 is opened as a blowout port 43 capable of blowing out high-temperature hot air.

  The heater mechanism 45 has a heating element 46 and a ceramic member 47. Electric power is supplied to the heating element 46 through the controller board 37. The heating element 46 to which power is supplied generates heat to a high temperature. The high temperature is, for example, a temperature of 600.degree. The ceramic member 47 is formed in a shape that covers the outer periphery of the heating element 46. A heating element 46 is attached to the ceramic member 47. For this reason, the wind sent by the blowing mechanism 35 passes through the inside of the heater housing 41 and is heated to a high temperature by the heater mechanism 45 and is blown out to the front side from the outlet 43 at the front end. By the way, the air blown out from the outlet 43 is heated by the heater mechanism 45 and becomes a hot air of 100 ° C. to 550 ° C.

  A mounting portion 44 is provided on the outer peripheral surface 42 of the heater housing 41 near the outlet 43. The mounting portion 81 of the nozzle attachment 80 is externally fitted to the mounting portion 44. The outer fitting of the mounting portion 81 with respect to the mounting portion 44 is to be press-fitted with an appropriate external fitting pressure. For this reason, a frictional force due to the externally fitting pressure is generated between the mounting portion 44 and the mounting portion 81. The frictional force due to the outer fitting of the mounting portion 81 suppresses the detachment of the mounting portion 81 of the nozzle attachment 80 from the mounting portion 44. That is, the mounting state of the nozzle attachment 80 with respect to the tool main body 11 is held by this frictional force. Incidentally, the removing mechanism 50 described later slides the nozzle attachment 80 to the front against the frictional force, and acts to remove the nozzle attachment 80 from the mounting portion 44.

  The nozzle attachment 80 is a member prepared in a plurality of types according to the application of the heat treatment by the heat gun 10. The nozzle attachment 80 is a member that can be attached to and detached from the mounting portion 44, and is a member that changes how hot air is blown out. For this reason, the nozzle attachment 80 has a mounting portion 81 attached to and detached from the mounting portion 44, an air flow guide wall portion 82 for guiding the hot air to be sent, and a blowout opening 83 for blowing the hot air. In the illustrated nozzle attachment 80, the hot air is blown flat. For this reason, the air flow guide wall 82 and the blowout opening 83 are set so that the air flow passage of the nozzle attachment 80 changes from the circular shape of the blowout port 43 to an elongated rectangular shape. Reference numeral 84 denotes a rear end edge of the nozzle attachment 80.

  Next, the removal mechanism 50 for removing the nozzle attachment 80 will be described. The removal mechanism 50 is detachably mounted on the outer periphery of the heater housing 41. The perspective views of FIGS. 4 to 6 illustrate the configuration of the removal mechanism 50 in an easy-to-understand manner. 4 shows that the removal mechanism 50 is removed from the tool main body 11, and FIG. 5 shows that the push-out cylinder portion of FIG. 4 is separated, and FIG. 6 shows the operation portion of FIG. It shows that it is separated. The removing mechanism 50 generally has a holder portion 51 and an operating mechanism 60. The removal mechanism 50 is formed to also serve as a cover that covers the periphery of the heat generating portion 40.

  The holder portion 51 is provided with a configuration that is attachable to and detachable from the tool main body 11, and is provided with a configuration that holds the operation mechanism 60 so as to be capable of relative displacement. The holder portion 51 is molded using resin as a material. The holder portion 51 generally has an annular main body 52 and a guide portion 53. The annular main body 52 is formed in a substantially annular shape having an outer circumferential surface 521 of a circular arc. The outer peripheral surface 521 is provided with a cut portion 522 extending in the front-rear direction. The cut portion 522 is formed so that a cut in the outer peripheral surface 521 is generated. The cut portion 522 makes it easy for the outer circumferential surface 521 to catch a finger in the circumferential direction.

  The guide portion 53 extends from the inner circumferential surface near the front end of the annular main body 52 to the front side. The guide portions 53 are disposed in a pair at the 180 degree opposing position of the annular main body 52. The guide portion 53 is set at each of the left and right positions in FIG. The connection circumferential surface portion 75 of the operation member 71 is in sliding contact with the guide portion 53. By the sliding contact of the connection circumferential surface portion 75 with the guide portion 53, the operation mechanism 60 is smoothly moved in the front-rear direction. In addition, the accommodating part 54 which accommodates the compression spring 58 is provided in the inner side of the guide part 53. As shown in FIG. The front end of the compression spring 58 abuts on the inside front wall shape of the housing portion 54.

  As shown in FIGS. 4 to 6, the holder portion 51 is provided with an engagement convex portion 56. The engagement convex portion 56 is provided on an inner circumferential surface near the rear end of the annular main body 52. The engagement convex portion 56 has a circular shaft shape and a shape slightly projecting to the annular center. The engagement convex portion 56 engages with the engagement concave groove portion 57. Specifically, the engagement convex portion 56 is fitted in the first concave groove portion 571 extending in the front-rear direction, and the holder portion 51 is moved to the rear side. Thereafter, the engagement convex portion 56 is fitted in the second recessed groove portion 572 extending in the circumferential direction, and the holder portion 51 is rotated in the circumferential direction. Thus, the holder portion 51 is in an attached state integrated with the tool main body 11.

  The operation mechanism 60 is supported by the holder 51 so as to be relatively movable in the front-rear direction. The operating mechanism 60 generally includes an extruded cylindrical member 61, an operating member 71, and two compression springs 58. The push-out cylinder member 61 is formed in a substantially cylindrical shape extending in the front-rear direction. The extruded cylindrical member 61 has an outer circumferential surface 62 with a diameter slightly larger than the outer circumferential surface 42 of the heater housing 41. At the rear end of the extruded cylindrical member 61, a flange portion 65 projecting outward in the radial direction is provided. The flange portion 65 is provided with a rear end contact portion 66 with which the rear end of the compression spring 58 abuts. The rear end contact portion 66 corresponds to the above-described guide portion 53 (housing portion 54), and is disposed in a pair at the 180 degree opposite position of the flange portion 65.

  Further, the flange portion 65 is provided with two screw holes 67 for inserting and passing the fastening screw 68. The two screw holes 67 are disposed between the two rear end contact portions 66, and are disposed in a pair at the 180 degree opposite position of the flange portion 65. The fastening screw 68 inserted through the screw hole 67 is fastened to the female screw portion 76 of the operation member 71 described below. At this time, the compression spring 58 is accommodated in the accommodation portion 54 described above in a compressed state. For this reason, the operating mechanism 60 including the metal extrusion cylinder member 61 is biased rearward by the elastic restoring force of the compression spring 58. The front end edge 69 of the push-out cylinder member 61 is set as a portion corresponding to the rear end edge 84 of the nozzle attachment 80 when the nozzle attachment 80 is removed.

  The operation member 71 corresponds to the operation unit according to the present invention. The operation member 71 has an annular portion 72 and a connection circumferential surface portion 75 provided on the rear side of the annular portion 72. The connection circumferential surface portion 75 is a surface in sliding contact with the guide portion 53. The connection circumferential surface portion 75 is provided with a female screw portion 76 to which the fastening screw 68 is screwed. Further, at the front end of the operation member 71 made of synthetic resin, an opening 77 is provided so as to be able to project the extrusion cylinder member 61. The annular portion 72 is provided with an operation recess 73 in which the outer peripheral surface is appropriately recessed. By providing the operation recess 73 as described above, the front end edge of the operation member 71 is set as the finger hooking portion 74 on which the user's finger is hooked. The finger hook portion 74 is protruded in the radial direction of the push-out cylinder member 61. The extension direction of the finger hook portion 74 is a direction that intersects with the front direction which is the removal operation direction.

  The operating member 71 set in this way forms the operating mechanism 60 by assembling the two compression springs 58 and the push-out cylinder member 61 as described above. Further, by this assembly, the operation mechanism 60 is also assembled to the holder portion 51 described above to form the removal mechanism 50. The dismounting mechanism 50 is integrally attached to the tool main body 11 in such a manner that the engagement convex portion 56 of the holder portion 51 is engaged with the engagement concave groove portion 57. In a state in which the removal mechanism 50 is attached to the tool main body 11, when the operation member 71 is moved to the front side against the bias of the compression spring 58 by putting a finger on the finger holding portion 74, an integral cylindrical member 61 is also moved forward.

  Here, the front end edge 69 of the extruded cylindrical member 61 abuts on the rear end edge 84 of the nozzle attachment 80, and pushes the nozzle attachment 80 forward. Then, the mounting portion 81 of the nozzle attachment 80 is gradually shifted to the front side from the mounted portion 44 which has been externally fitted, and the nozzle attachment 80 is eventually removed from the mounted portion 44. After the nozzle attachment 80 is removed from the mounting portion 44, when the finger hooked on the finger hook portion 74 is removed, the operating member 71 returns to the initial position before the removal operation by the biasing force of the compression spring 58. It will be.

  According to the heat gun 10 configured as described above, the following effects can be achieved. According to the above-described heat gun 10, both the nozzle attachment 80 and the removal mechanism 50 can be removed from the tool main body 11, and the heater housing 41 can be exposed to the outside. That is, the outer peripheral surface 42 of the heater housing 41 can be used as the nozzle of the heat gun 10 having the outermost diameter. Thus, if slimming of the nozzle can be realized, the slimmed nozzle can penetrate into a narrow space. In addition, since the hot air is blown out directly from the blowout port 43 without passing through the nozzle attachment, the temperature of the blown hot air does not decrease. As a result, high-temperature hot air can be blown to a portion to be heat-treated to perform desired heat treatment.

  Further, according to the heat gun 10 described above, since the removing mechanism 50 is formed to also serve as a cover covering the periphery of the heat generating portion 40, the function as a cover of the heat generating portion 40 can also be exhibited while the removing mechanism 50 is attached. As a result, the size of the outer shape of the front portion provided with the heat generating portion 40 can be reduced while facilitating the removal of the nozzle attachment 80 by the removal mechanism 50, and the heat gun 10 can be made easy to handle. Further, according to the heat gun 10 described above, the operating member 71 for removing the nozzle attachment 80 is provided with the finger hook portion 74 which is projected in the radial direction orthogonal to the front direction which is the removing operation direction. Since it is easy to hold a finger on the finger hook portion 74 when operating the operation member 71, the removal operation becomes easy.

  A hole 32 is provided in front of the lower end of the grip housing 21, and a hole 36 is provided in the upper end near the center of the blower housing 31 in the front-rear direction. The holes 32 and 36 are for hanging the tool body 11 from above using hooks or the like. When the grip housing portion 21 interferes with the operation, the tool main body 11 is used upside down by using the hole portion 32. In this case, the air outlet 43 is inclined downward and the air blowing direction is also inclined downward. When it is desired to make the blowing direction horizontal, the blowing housing 31 can be made to be in the horizontal posture by using the hole 36 located near the upper side of the center of gravity of the tool body 11.

  In addition, in the portable heat processing tool which concerns on this invention, it is not limited to above-mentioned embodiment, A various change can be added suitably. For example, the configuration for attaching and detaching the removing mechanism to and from the main body is not limited to the configuration of the engagement convex portion 56 and the engagement concave groove portion 57 described above, and is configured using a known engagement configuration. It may be one. That is, the removal mechanism according to the present invention is only required to be removably attachable to the main body.

10 heat gun (portable heat treatment tool)
11 Tool body (body)
DESCRIPTION OF SYMBOLS 15 Main body housing 16 Opening peripheral part 20 Grip part 201 Lower part 202 Upper part 21 Grip housing part 22 Grip end part 23 Operation switch 24 Switch board 28 Power cord 29 Rubber member 30 Blower part (sending part)
Reference Signs List 31 air blower housing 33 air intake hole 34 screw 35 air blower 351 motor 352 drive shaft 353 centrifugal fan 355 air flow guide wall 37 controller board 38 temperature control dial 39 operation surface 40 heat generator 41 heater housing 42 outer peripheral surface 43 air outlet 44 Mounting portion 45 Heater mechanism 46 Heating element 47 Ceramic member 50 Removal mechanism 51 Holder portion 52 Annular main body 521 Outer peripheral surface 522 Notched portion 53 Guide portion 54 Housing portion 56 Engaging convex portion 57 Engaging concave groove portion 571 First concave groove portion 572 Second Recess groove portion 60 Operation mechanism 61 Extruded cylindrical member 62 Outer peripheral surface 65 Flange portion 66 Rear end contact portion 67 Screw hole 68 Fastening screw 69 Front end edge 71 Operation member 72 Annular portion 73 Operation concave portion 74 Finger hook portion 75 Connection circumferential surface portion 76 Female screw Section 77 Opening 80 Nozzle attachment (tip nozzle)
81 mounting portion 82 air flow guide wall portion 83 blowout opening portion 84 rear end edge

Claims (3)

A portable heat treatment tool that emits heat at high temperature and performs heat treatment,
It has a main body having a heat generating part and a delivery part which generate heat by electricity, and a tip nozzle part which is made detachable with respect to the main body,
The body is detached mechanism is Ri attached taken for removal from the body of the tip nozzle portion,
The removal mechanism includes an operation mechanism and a holder portion that can move relative to each other.
The tip nozzle portion can be removed from the main body by pushing the tip nozzle portion with the operation mechanism.
The portable heat treatment tool , wherein the removal mechanism is removably attached to the main body by the holder portion . In the portable heat treatment tool according to claim 1,
The portable heat treatment tool, wherein the removal mechanism is formed to also serve as a cover that covers the periphery of the heat generating portion. In the portable heat treatment tool according to claim 1 or 2,
The removal mechanism has an operation unit that performs a removal operation when removing the tip nozzle portion,
The portable heat processing tool, wherein the operation unit is provided with a finger hook portion extended in a direction intersecting the dismounting operation direction.

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