EP3324115A1

EP3324115A1 - Heat gun with self-cooling system

Info

Publication number: EP3324115A1
Application number: EP17190313.1A
Authority: EP
Inventors: Wei-Long Chen
Original assignee: Pro Iroda Industries Inc
Current assignee: Pro Iroda Industries Inc
Priority date: 2016-11-21
Filing date: 2017-09-11
Publication date: 2018-05-23
Also published as: US20180142920A1

Abstract

A heat gun (10, 10a) includes a head portion (20, 20a) defining a flow passage (21, 21a) and including a windshield (30, 30a) disposed at an outlet end (212, 212a) of the flow passage. The windshield includes a first partition (31, 31a) and a shield (33, 33a). The first partition has opposing first and second sides (311, 311a, 312, 312a). The first side aligns a first phantom line (P1). The shield includes a first, second, and third through hole (331, 331a, 332, 332a, 333, 333a). The first through hole is located on a right side of the first phantom line. The second through hole is located on a left side of the first phantom line. The third hole includes a portion located on the right side of the first phantom line and a portion located on the left side of the first phantom line.

Description

Background of the Invention

1. Field of the Invention

The present invention relates to a heat gun and, particularly, to a heat gun with a self-cooling system.

2. Description of the Related Art

EP 1795803 A2 shows a modular gas burning hand tool including an main body (3), an ignite gas conduit (7) extending longitudinally in the main body (3) for circulating gas, a grip handle (5), a burner part (9) including a hollow body extending from the main body (3) and communicating with the ignite gas conduit (7) and including a gas-powered unit (11) disposed at an end of the hollow body. The burner part (9) has a junction part (13) opposite the gas powered unit (11). The main body (3) also has a junction part (15). The junction parts (13, 15) are adapted to releasably connect to one another.
It is known for conventional gas heat guns to use high pressure gas and to incorporate venturi tubes to mix the gas. The high pressure gas is spewed at a high velocity out of a gas nozzle in the venturi tube. The gas causes outside air to flow to the venturi tube and a chamber from which a flame exits to achieve an appropriate ratio of gas mixture and to increase the amount of the gas mixture. The venturi tube includes a hollow recifying mixing chamber at another end. The mixing chamber is shrouded by a flow-rectifying cover that is configured to control the flow speed and distributability of the gas mixture as well as preventing the backward propagation of flame. Moreover, the greater width of a flame exit end of the gas heat gun, the easier the user can operate the gas heat gun to heat the target precisely and to heat large areas quickly.
However, conventional high power gas heat guns suffer problems, including:

1. Flame flowing out of the flame exit end is not evenly distributed and therefore doesn't apply heat to a surface evenly.
2. Mixing and dispensing gas unevenly result in a poor combustion, which not only reduces efficiency and wastes gas, but also produce too much noxious carbon monoxide (CO) and nitrogen oxide (NOx).
3. The temperature of the flame exit end is very high and a large amount of heat is concentrated. Furthermore, heat radiates and conducts, and therefore the chamber, which includes the flame exit end, is hot and often reaches a temperature above 100 degrees Centigrade. Therefore, there is a high risk that the user gets burned inadvertently.
4. The flow-rectifying cover has an exit being too small, which results in substantial pressure losses, a flow capacity decrease overall, and a difficulty to increase heat power.
5. High pressure gas and the gas mixture create much turbulence in the mixing chamber and the flow-rectifying cover and induce noise.
6. Rectifying flows unduly causes the flame at the flame exit end to flow at a low speed. Since the flame spreads linearly mostly, if the flame flows at a speed which is too low, the flame is susceptible to distortion under thermal buoyant effects. Thus, it is difficult to aim the gas heat gun at the target precisely. The flame is also easily affected by air currents when the gas heat gun is used in an outside environment. Thus, it is difficult to operate and aim the gas heat gun at the target precisely in a wind environment and especially if the wind varies directions. Furthermore, when the flame moves against the wind, the flame, which flows too slow, may burn backward toward the user.
7. If gas is mixed and dispensed unsteadily, a suitable pressure range for supplying gas becomes limited, and the chance to ignite the gas is substantially reduced.

The conventional mixing chamber is fan-shaped and varies regularly in cross section along a center axis of the venturi tube. In order to speed up operations, it is necessary to increase areas that can be heated instantaneously as well as heat power. Thus, an exit of the mixing chamber which has a narrow width is not desired. Increasing the width of the exit of the mixing chamber, however, makes it more difficult to control flows at the exit at the same speed. In fact, flows at two sides of the exit flow faster and flows in the middle of the exit flow slower (see Fig. 17). If reducing the width of the exit of the mixing chamber, areas that can be heated is smaller. If increasing heat power, heat concentrates in a small region and results in local overheating. If increasing a distance between the gas heat gun and the target, thermal buoyant force and air flow disturbance make it difficult for the user to aim the gas heat gun at areas to be heated. Therefore, a high power gas heat gun that allows a user heat a target precisely and evenly includes a wide flame exit and flame exits at high speed.
In addition to flow noise and the phenomenon that the temperature at the two sides are higher, the flame is nearly transparent, and therefore it is hard to perceive the direction of heat transfer. This causes the user to have a poor aim of the target and where the gas heat gun aims is not exactly where the user wants to heat. Furthermore, since the flows are not at the same speed, an increase of heat capacity results in incomplete combustions at the two sides, and trying to use flow guides to control flows, however, imposes frictional forces on the flows and reduces overall flow capacity and efficiency.
Since large amount of heat is concentrated at the flame exit end, the temperature is very high, due to heat radiation and conduction, and is often above 100 degrees Centigrade. Therefore, there is a high risk that the user gets burned inadvertently. After the flame stops, it also takes quite a while to dissipate heat and cool the temperature down with respect to the ambient temperature and, since the user doesn't know when the gas heat gun has cooled, it is easy that he or she can get burned inadvertently.
Fig. 16 is a partial, cross-sectional view of a conventional gas heat gun. As set forth, the gas heat gun includes a device 11' from which gas burns. The device 11' includes a net and a main body defining a tube in circular cross-section. When gas flows in the tube, it flows faster at the center than at the edges. The gas will flow pass the main body and into a burner part 9'. Likewise, the gas flows faster at the center of the burner part 9' than at the edges of the burner part 9'. The gas in the burner part 9' will contact the device 11'. The device 11' will obstruct and deflect the gas. Fig. 16 shows that after the gas is obstructed by the device 11', it is partially deflected and flows toward two sides of the burner part 9' in opposing directions, and consequently flow capacity at the two sides of the burner part 9' is more and flow capacity in the middle of the burner part 9' is lesser. As a result, the temperature at the two sides is higher than the temperature in the middle, and the gas heat gun does not give out even heat and uniform temperature. Furthermore, the burner part 9' is very hot, but the user can't tell by appearance, and therefore it is easy that he or she can get burned inadvertently.
The present invention is, therefore, intended to obviate or at least alleviate the problems encountered in the prior art.

Summary of the Invention

According to the present invention, a heat gun with a self-cooling system includes a head portion defining a flow passage and including a windshield. The flow passage extends longitudinally along an axis and has an inlet end at one end and an outlet end at another end opposing the inlet end. The windshield is disposed at the outlet end of the flow passage and includes a first partition and a shield. The first partition has opposing first and second sides extending parallel to the axis. The first side aligns a first phantom line. The shield extends transversely to the axis and is disposed adjacent to an end of the first partition which is opposite to the flow passage. The shield includes a first, second, and third through hole. The first through hole is located on a right side of the first phantom line. The second through hole is located on a left side of the first phantom line. The third hole including a portion located on the right side of the first phantom line and a portion located on the left side of the first phantom line.
Other objectives, advantages, and new features of the present invention will become apparent from the following detailed description of the invention when considered in conjunction with the accompanied drawings.

Brief Description of the Drawings

Fig. 1 is a perspective view of a heat gun with a self-cooling system in accordance with a first embodiment of the present invention.
Fig. 2 is an exploded perspective view of a head portion of the heat gun of the first embodiment of the present invention.
Fig. 3 is a cross-sectional view of the head portion of the heat gun of the first embodiment of the present invention.
Fig. 4 is another cross-sectional view of the head portion of the first embodiment of the heat gun of the present invention.
Fig. 5 is a partial, enlarged view of Fig. 4.
Fig. 6 is a cross-sectional view of the heat gun of the first embodiment of the present invention, taken from a line extending transversely to an axis L that is shown in Fig. 3.
Fig. 7 is a cross-sectional view of the heat gun of the first embodiment of the present invention, taken from another line extending transversely to the axis L that is shown in Fig. 3.
Fig. 8 is a cross-sectional view illustrating the heat gun of the first embodiment of the present invention in operation, with arrows indicating flows.
Fig. 9 is another cross-sectional view illustrating the heat gun of the first embodiment of the present invention in operation, with solid lines illustrating heat.
Fig. 10 is another cross-sectional view illustrating the heat gun of the first embodiment of the present invention, with arrows indicating flows, and with solid lines illustrating heat.
Fig. 11 is a perspective view of a heat gun with a self-cooling system in accordance with a second embodiment of the present invention.
Fig. 12 is an exploded perspective view of a head portion of the heat gun of the second embodiment of the present invention.
Fig. 13 is a cross-sectional view of the head portion of the heat gun of the second embodiment of the present invention.
Fig. 14 is a cross-sectional view illustrating the heat gun of the second embodiment of the present invention in operation, with arrows indicating flows.
Fig. 15 is a partial, enlarged view of Fig. 14.
Fig. 16 is a cross-sectional view of a conventional heat gun.
Fig. 17 is a thermal image of conventional heat gun in operation.

Detailed Description of the Invention

Figs. 1 through 10 show a heat gun 10 with a self-cooling system in accordance with a first embodiment of the present invention.
The heat gun 10 includes a head portion 20. The head portion 20 defines a flow passage 21. The flow passage 21 extends longitudinally along an axis L. The flow passage 21 has an inlet end 211 at one end and an outlet end 212 at another opposite end. The flow passage 21 includes an inlet portion 213, an outlet portion 214 and a flow guiding portion 215 disposed between the inlet and outlet ends 211 and 212.
The inlet portion 213 has a radial cross-sectional area about the axis L. The outlet portion 214 has a radial cross-sectional area about the axis L and which is greater than 0.8 times and smaller than 1.2 times of the radial cross-sectional area of the inlet portion 213. The radial cross-sectional area of the inlet portion 213 is circular in shape. The radial cross-sectional area of the outlet portion 214 is quadrilateral in shape.
The outlet portion 214 is formed with two long sides 216 and two short sides 217. The two long sides 216 are opposite one another. The long side 216 extends lengthwise of the outlet portion 214 and in a direction transverse to the axis L a length D. The two short sides 217 are opposite one another. The two short sides 217 extend between the two long sides 216. The short side 217 extends widthwise of the outlet portion 214 and in a direction transverse to the axis L a width W. The length D is greater than a maximum width of the inlet end 211. The maximum width of the inlet end 211 extends in the lengthwise direction of the outlet portion 214. The width W is smaller than the maximum width of the inlet end 211. In addition, the two surfaces 221 are spaced at a distance greater than or equal to the width W.
The flow passage 21 includes two flow guiding protrusions 22 disposed at the flow guiding portion 215. The flow guiding protrusions 22 include two outer peripheries facing oppositely and converging toward one another in a direction from outlet portion 214 to the inlet portion 213. Each of the two outer peripheries of the two flow guiding protrusions 22 has a nonplanar contour. The two flow guiding protrusions 22 are disposed oppositely.
The head portion 20 includes two surfaces 221 disposed oppositely, and the two flow guiding protrusions 22 protrude between the two surfaces 221. The two surfaces 221 are disposed parallel to one another, or otherwise, incline from each other such that an included angle formed therebetween is greater than 0 degrees and less than 10 degrees. When the two surfaces 221 are inclined, a distance between ends of the two surfaces 221 which are adjacent to the inlet portion 213 is greater than a distance between ends of the two surfaces 221 which are adjacent to the outlet portion 214.
The flow guiding portion 215 is disposed between the inlet and outlet portions 213 and 214. The flow guiding portion 215 is partitioned by the two flow guiding protrusions 22 and defines a first flow region 23 which extends along a first extension axis C1, a second flow region 24 which extends along a second extension axis C2 and a third flow region 25. The first and second extension axes C1 and C2 are symmetrical about the axis L. The first extension axis C1 intersects the second extension axis C2 at an included angle A greater than 60 degrees and smaller than 160 degrees. The third flow region 25 is disposed between the two flow guiding protrusions 22. The first and third flow region 23 and 25 are disposed on opposite sides of one of the two flow guiding protrusions 22. The second and third flow regions 24 and 25 are disposed on opposite sides of another of the two flow guiding protrusions 22. The third flow region 25 includes a side connected to the first flow region 23 and an opposite side connected to the second flow region 24. The first flow region 23 extends from a first end which is adjacent to the inlet portion 213 to a second end which is adjacent to the outlet portion 214 and has a gradually reduced cross-section from the first end to the second end.
The first flow region 23 has a middle portion which is in the middle between the inlet portion 213 and the outlet portion 214 and which has a radial cross-section about the first extension axis C1 greater than 0.25 times and smaller than 0.4 times of a radial cross-section of the inlet portion 213 about the axis L. The second flow region 24 extends from a first end which is adjacent to the inlet portion 213 to a second end which is adjacent to the outlet portion 214 and has a gradually reduced cross-section from the first end to the second end. The second flow region 24 has a middle portion which is in the middle between the inlet portion 213 and the outlet portion 214 and which has a radial cross-section about the second extension axis C2 greater than 0.25 times and smaller than 0.4 times of the radial cross-section of the inlet portion 213.
Furthermore, the first flow region 23 has a maximum radial cross-sectional area about the first extension axis C1 which is 1/3 of a maximum radial cross-sectional area of the inlet portion 213 about the axis L. The second flow region 24 has a maximum radial cross-sectional area about the second extension axis C2 which is 1/3 of the maximum radial cross-sectional area of the inlet portion 213 about the axis L. The first flow region 23 has a minimum radial width about the first extension axis C1 greater than a minimum radial cross-section of the third flow region 25 about the axis L. The second flow region 24 has a minimum radial width about the second extension axis C2 greater than the minimum radial width of the third flow region 25 about the axis L.
The head portion 20 cooperates with a windshield 30 to improve flow effects. The windshield 30 is disposed at the outlet end 212 of the flow passage 21. The windshield 30 includes a first partition 31, a second partition 32, and a shield 33. The first and second partitions 31 and 32 each extend parallel to the axis L from an end adjacent to the outlet portion 214 to another end. The first partition 31 has opposing first and second sides 311 and 312 extending parallel to the axis L. The first side 311 aligns a first phantom line P1. The first side of the first and second partitions 31 and 32 are planar. The second partition 32 has opposing first and second sides 321 and 322 extending parallel to the axis L. The second side 322 aligns a second phantom line P2. The second side of the first and second partitions 31 and 32 are planar. The first sides 311 and 321 of the first and second partitions 31 and 32 face oppositely. The second partition 32 is disposed at the outlet end 212 of the flow passage 21 and in a spaced relationship with the first partition 31. The first and second partitions 31 and 32 are spaced at a distance greater than the width W. The shield 33 includes a fourth and fifth through hole 334 and 335. The fourth through hole 334 is located on a right side of the second phantom line P2. The fifth through hole 335 includes a portion located on the right side of the second phantom line P2 and a portion located on a left side of the first phantom line P1.
The shield 33 extends transversely to the axis L and is disposed adjacent to another ends of the first and second partitions 31 and 32. The shield 33 includes a first, second, third, fourth, and fifth through hole 331, 332, 333, 334, and 335. The first through hole 331 is located on a right side of the first phantom line P1. The first through hole 331 of the shield 33 is located between first and second phantom lines P1 and P2. The second through hole 332 is located on a left side of the first phantom line P1. The third through hole 333 includes a portion located on the right side of the first phantom line P1 and a portion located on the left side of the first phantom line P1.
Figs. 13 through 15 show a heat gun 10a with a self-cooling system in accordance with a second embodiment of the present invention, and the same numbers are used to correlate similar components of the first embodiment, but bearing a letter a. The heat gun 10a includes a head portion 20a. The head portion 20a defines a flow passage 21a. The flow passage 21a extends longitudinally along an axis L. The flow passage 21a has an inlet end 211a at one end and an outlet end 212a at another opposite end. The flow passage 21 includes an inlet portion, an outlet portion and a flow guiding portion disposed between the inlet and outlet ends. The radial cross-sectional area of the inlet portion is circular in shape. The radial cross-sectional area of the outlet portion is annular in shape.
The head portion 20a cooperates with a windshield 30a to improve flow effects. The windshield 30a is disposed at the outlet end 212a of the flow passage 21a. The windshield 30a includes a first partition 31, a second partition 32, and a shield 33a. The first partition 31a has opposing first and second sides 311 a and 312a extending parallel to the axis L. The first and second sides 311 a and 312a of the first partition 31 a are arcuate. The windshield 30a includes a second partition 32a cooperating with the first partition 31a. The second partition 32a has opposing first and second sides 321a and 322a extending parallel to the axis L. The first side 321a aligns a second phantom line P2. The first sides 311a and 321a of the first and second partitions 31a and 32a face oppositely. The second partition 32a is disposed at the outlet end 212a of the flow passage 21a and in a spaced relationship with the first partition 31a. The shield 33a includes a first, second, third, fourth, and fifth through hole 331a, 332a, 333a, 334a, and 335a. The first through hole 331a of the shield 33a is located between first and second phantom lines P1 and P2. The first through hole 331a is located on a right side of the first phantom line P1. The second through hole 332a is located on a left side of the first phantom line P1. The third hole 333a includes a portion located on the right side of the first phantom line P1 and a portion located on the left side of the first phantom line P1. The fourth through hole 334a is located on a right side of the second phantom line P2. The fifth through hole 335 includes a portion located on the right side of the second phantom line P2 and a portion located on a left side of the second phantom line P2.
The head portion 20a includes an air amplifier 22a for inducing external air flow. The inlet end 211 a is formed at an end of the air amplifier 22a. Further, a tube defines the flow passage 21a. The tube is circular in shape. The air amplifier 22a defines a channel having a first opening and a second opening opposite the first opening. The first opening has a first radial cross-sectional area about the axis L. The second opening has a second radial cross-sectional area about the axis L smaller than the first radial cross-sectional area.
In view of the forgoing, hot air flows mainly between the first and second partitions 31, 31a, 32, 32a and out of the head portions 20 and 20a through the first through holes 331 and 331a. Hot air also flows out of the head portion 20 and 20a through the portion of the third through holes 333 and 333a that is located on the right side of the first phantom line P1 and the portion of the fifth through hole 335 and 335 that is located on the left side of the second phantom line P2. When hot air flows through the set forth portions of the third through holes 333 and 333a, it creates a strong negative pressure, thereby inducing external air flow into the head portions 20 and 20a through the portion of the portion of the third through holes 333 and 333a that is located on the left side of the first phantom line P1 and the portion of the fifth through hole 335 and 335a that is located on the right side of the second phantom line P2. External air circulates in a region that is located on the left side of the first phantom line P1 and in another region that is located on the right side of the second phantom line P2, thereby cooling the head portions 20 and 20a and keeping the its temperature less than 40 degree Celsius to preventing burning a user of the heat gun.
Furthermore, the head portions 20 and 20a greatly reduce the likelihood that flows flowing backward and turbulence, thereby improving combustion efficiency, as well as lowering noise and preventing pressure drops. Furthermore, the head portions 20 and 20a allow higher flow capacity when compared with conventional head portion designs as well as heat to distribute evenly and greater pressure range. Consequently, heating conditions can be easily controlled. Even if the pressure varies, the chance to ignite the gas is not affected.

Claims

A heat gun (10, 10a) with a self-cooling system comprising:
a head portion (20, 20a) defining a flow passage (21, 21a) which extends longitudinally along an axis (L) and has an inlet end (211, 211a) at one end and an outlet end (212, 212a) at another end opposing the inlet end (211, 211a) and;

a windshield (30, 30a) disposed at the outlet end (212, 212a) of the flow passage (21, 21a) and including a first partition (31, 31a) and a shield (33, 33a), wherein the first partition (31, 31a) has opposing first and second sides (311, 311a, 312, 312a) extending parallel to the axis (L), wherein the first side (311, 311a) aligns a first phantom line (P1), wherein the shield (33, 33a) extends transversely to the axis (L) and is disposed adjacent to an end of the first partition (31) which is opposite to the flow passage (21, 21a), and wherein the shield (33, 33a) includes a first, second, and third through hole (331, 331a, 332, 332a, 333, 333a), with the first through hole (331, 331a) located on a right side of the first phantom line (P1), with the second through hole (332, 332a) located on a left side of the first phantom line (P1), and with the third through hole (333, 333a) including a portion located on the right side of the first phantom line (P1) and a portion located on the left side of the first phantom line (P1).
The heat gun (10) as claimed in claim 1, wherein the flow passage (21) includes an outlet portion (214) disposed between the inlet and outlet ends (211, 212), wherein the outlet portion (214) is formed with two long sides (216) and two short sides (217), with the two long sides (216) opposite one another, and with the two short sides (217) opposite one another, wherein the short side (217) has a width (W) extending in a direction transverse to the axis (L), wherein the windshield (30) includes a second partition (32) cooperating with the first partition (31), wherein the second partition (32) has opposing first and second sides (321, 322) extending parallel to the axis (L), wherein the first side (321) aligns a second phantom line (P2), wherein the first sides (311, 321) of the first and second partitions (31, 32) face oppositely, wherein the second partition (32) is disposed at the outlet end (212) of the flow passage (21) and in a spaced relationship with the first partition (31), wherein the first and second partitions (31, 32) are spaced at a distance greater than the width (W), wherein the first through hole (331) of the shield (33) is located between first and second phantom lines (P1, P2), and wherein the shield (33) includes a fourth and fifth through hole (334, 335), with the fourth through hole (334) located on a right side of the second phantom line (P2), and with the fifth through hole (335) including a portion located on the right side of the second phantom line (P2) and a portion located on a left side of the second phantom line (P2).
The heat gun (10) as claimed in claim 2, wherein the long side (216) has a length (D) extending in a direction transverse to the axis (L), wherein the length (D) is greater than a maximum width of the inlet end (211), and wherein the width (W) is smaller than the maximum width of the inlet end (211).
The heat gun (10) as claimed in claim 2, wherein the flow passage (21, 21a) includes an inlet portion (213) disposed between the inlet and outlet ends (211, 211a, 212, 212a), wherein the outlet portion (214) has a first radial cross-sectional area about the axis (L) and the inlet portion (213) has a second radial cross-sectional area about the axis (L) respectively, and wherein the first radial cross-sectional area is greater than 0.8 times and smaller than 1.2 times of the second radial cross-sectional area.
The heat gun (10) as claimed in claim 4, wherein the first radial cross-sectional area is circular in shape, and wherein the second radial cross-sectional area is quadrilateral in shape.
The heat gun (10) as claimed in claim 5, wherein the flow passage (21, 21a) includes a flow guiding portion (215) disposed between the inlet and outlet ends (211, 211a, 212, 212a), wherein the flow guiding portion (215) includes two flow guiding protrusions (22) disposed oppositely, wherein the flow guiding portion (215) is partitioned by the two flow guiding protrusions (22) and defines a first flow region (23) which extends along a first extension axis (C1), a second flow region (24) which extends along a second extension axis (C2) and a third flow region (25), wherein the third flow region (25) is disposed between the two flow guiding protrusions (22), wherein the first and third flow regions (23, 25) are disposed on opposite sides of one of the two flow guiding protrusions (22), wherein the second and third flow regions (24, 25) are disposed on opposite sides of another of the two flow guiding protrusions (22), wherein the third flow region (25) includes a side connected to the first flow region (23) and an opposite side connected to the second flow region (24), wherein the first flow region (23) extends from a first end which is adjacent to the inlet portion (213) to a second end which is adjacent to the outlet portion (214) and has a gradually reduced cross-section from the first end to the second end, wherein the first flow region (23) has a middle portion which is in the middle between the inlet portion (213) and the outlet portion (214) and which has a radial cross-section about the first extension axis (C1) greater than 0.25 times and smaller than 0.4 times of a radial cross-section of the inlet portion (213) about the axis (L), wherein the second flow region (24) extends from a first end which is adjacent to the inlet portion (213) to a second end which is adjacent to the outlet portion (214) and has a gradually reduced cross-section from the first end to the second end, wherein the second flow region (24) has a middle portion which is in the middle between the inlet portion (213) and the outlet portion (214) and which has a radial cross-section about the second extension axis (C2) greater than 0.25 times and smaller than 0.4 times of the radial cross-section of the inlet portion (213).
The heat gun (10) as claimed in claim 6, wherein the first flow region (23) has a maximum radial cross-sectional area about the first extension axis (C1) which is 1/3 of a maximum radial cross-sectional area of the inlet portion (213) about the axis (L), and wherein the second flow region (24) has a maximum radial cross-sectional area about the second extension axis (C2) which is 1/3 of the maximum radial cross-sectional area of the inlet portion (213) about the axis (L).
The heat gun (10) as claimed in claim 7, wherein the first flow region (23) has a minimum radial width about the first extension axis (C1) greater than a minimum radial cross-section of the third flow region (25) about the axis (L), and wherein the second flow region (24) has a minimum radial width about the second extension axis (C2) greater than the minimum radial width of the third flow region (25) about the axis (L).
The heat gun (10) as claimed in claim 8, wherein the first and second extension axes (C1, C2) are symmetrical about the axis (L), and wherein the first extension axis (C1) intersects the second extension axis (C2) at an included angle (A) greater than 60 degrees and smaller than 160 degrees.
The heat gun (10) as claimed in claim 6, wherein the two flow guiding protrusions (22) include two outer peripheries converging toward one another in a direction from outlet portion (214) to the inlet portion (213).
The heat gun (10) as claimed in claim 6, wherein the head portion (20) includes two surfaces (221) disposed oppositely, wherein the two flow guiding protrusions (22) protrude between the two surfaces (221), and wherein the two surfaces (221) are spaced at a distance greater than or equal to the width (W).
The heat gun (10) as claimed in claim 11, wherein the two surfaces (221) are inclined from each other such that an included angle formed therebetween is greater than 0 degrees and less than 10 degrees, and wherein a distance between ends of the two surfaces (221) which are adjacent to the inlet portion (213) is greater than a distance between ends of the two surfaces (221) which are adjacent to the outlet portion (214).
The heat gun (10a) as claimed in claim 1, wherein the first and second sides (311a, 312a) of the first partition (31a) are arcuate, wherein the flow passage (21, 21a) includes an annular outlet portion disposed between the inlet and outlet ends (211a, 212a), wherein the windshield (30a) includes a second partition (32a) cooperating with the first partition (31a), wherein the second partition (32a) has opposing first and second sides (321a, 322a) extending parallel to the axis (L), wherein the first side (321a) aligns a second phantom line (P2), wherein the first sides (311a, 321a) of the first and second partitions (31a, 32a) face oppositely, wherein the second partition (32a) is disposed at the outlet end (212a) of the flow passage (21a) and in a spaced relationship with the first partition (31a), wherein the first through hole (331a) of the shield (33a) is located between first and second phantom lines (P1, P2), and wherein the shield (33a) includes a fourth and fifth through hole (334a, 335a), with the fourth through hole (334a) located on a right side of the second phantom line (P2), and with the fifth through hole (335) including a portion located on the right side of the second phantom line (P2) and a portion located on a left side of the second phantom line (P2).
The heat gun (10a) as claimed in claim 13 further comprising an air amplifier (22a) for inducing external air flow, wherein the inlet end (211a) is formed at an end of the air amplifier (22a).
The heat gun (10a) as claimed in claim 14 further comprising a tube defining the flow passage (21a), wherein the air amplifier (22a) defines a channel having a first opening and a second opening opposite the first opening, with the first opening having a first radial cross-sectional area about the axis (L), and with the second opening having a second radial cross-sectional area about the axis (L) smaller than the first radial cross-sectional area.