JP2018119711A - Hot air heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a surface processing technique (a hot air heater) which can secure safety for workers or processed portions in a more sufficient manner while maintaining the same level of processing effect as surface processing using flame.SOLUTION: A handy type hot air heater 1 jets hot air to perform surface processing to processed portions and has: a heating mechanism 3 which can jet hot air generated by heating air along a processed portion; a grip mechanism 2 which is connected with the heating mechanism and can be held by a worker; an air introduction mechanism 4 which can introduce air into the heating mechanism; and a cooling structure (a gate opening/closing mechanism 5) which is provided at the grip mechanism, and diffuses air to make the air into cool air to cool heat conducted from the heating mechanism to the grip mechanism.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a hot air heater used when performing surface processing (for example, deburring and finishing) on a resin molded product for a vehicle body such as a bumper or a grill of an automobile.

  In recent years, for example, bumpers and grills provided on the front and rear of an automobile are molded of a resin material in response to a request for reducing the weight of the vehicle body. And the finished product is manufactured by performing surface processing (for example, deburring and finishing) on such a resin molded product.

Japanese Patent No. 4780613

  By the way, in the conventional surface processing, the flame treatment using the burner is performed (for example, refer patent document 1). In the flame treatment, a flame is sprayed from a burner along a part to be processed (for example, a burr). The work site (burr) is melted and smoothed by a flame. Thus, the flame treatment for the part to be processed (burr) is completed.

  An object of the present invention is to provide a surface processing technique (hot air heater) capable of sufficiently ensuring safety for a worker or a part to be processed while maintaining the same processing effect as surface processing using a flame. is there.

  In order to achieve such an object, the present invention is a handy type hot air heater that performs surface processing on a processed part by injecting hot air, and injects hot air heated by air along the processed part. Possible heating mechanism, a grip mechanism that is connected to the heating mechanism, an air introduction mechanism that can introduce air into the heating mechanism, and a grip mechanism that diffuses air and cools it down And a cooling structure for cooling the heat conducted from the heating mechanism to the grip mechanism.

  In the present invention, the cooling structure includes a gate capable of sending air to a heating mechanism when performing surface processing with hot air, and the air passes through the gate after being squeezed by the gate when passing through the gate. After being released, it diffuses radially toward the outside, thereby cooling the air.

  The present invention further includes a gate opening / closing mechanism including a cooling structure, the gate opening / closing mechanism including an operation lever for opening or closing the gate, and heating the air in a state where the gate is opened by the operation lever. In the state where the mechanism can be sent out and the gate is closed by the operation lever, air cannot be sent out to the heating mechanism, and the operation of the heating mechanism is controlled to stop.

  In the present invention, the air introduction mechanism is arranged and configured over a region opposite to the heating mechanism, and the air introduction mechanism and the heating mechanism are arranged to face both sides of the grip mechanism. Thus, the balance center of the hot air heater is positioned at or near the center of the grip mechanism.

  According to the present invention, it is possible to realize a surface processing technique (hot air heater) that can sufficiently secure safety for a worker or a part to be processed while maintaining the same processing effect as the surface processing using a flame. it can.

The perspective view which shows the external appearance of the hot air heater which concerns on one Embodiment of this invention. The perspective view which shows an example of the to-be-processed part (a front bumper, a grill) in which surface processing is performed by the hot air heater of FIG. The fragmentary sectional view which shows the internal structure of a heating mechanism. The block diagram which shows the structure for controlling a hot air heater. It is sectional drawing which shows the structure of a gate opening / closing mechanism (namely, cooling structure), Comprising: The figure which shows a gate closed state. The figure which shows the state by which the cooling effect was exhibited by opening the gate of FIG.

"One embodiment"
"Overview of hot air heater"
FIG. 1 shows a handy hot air heater 1 as an example of a surface processing technique using hot air. The hot air heater 1 according to this embodiment is configured to be able to perform surface processing (for example, deburring and finishing) on a resin molded product (for example, a bumper Bp and a grill Gr (see FIG. 2)) for an automobile body. Has been.

  In the surface processing, the hot air heater 1 injects hot air along a processed part (for example, a burr). The part to be processed (burr) is melted and smoothed by hot air. Thus, the surface processing for the processed part (burr) is completed.

  In order to enable such surface processing, the hot air heater 1 includes a grip mechanism 2, a heating mechanism 3, an air introduction mechanism 4, and a gate opening / closing mechanism 5 (that is, a cooling structure). The grip mechanism 2 is configured so that an operator can grip it. The heating mechanism 3 is supported by the grip mechanism 2. The heating mechanism 3 and the grip mechanism 2 are connected to each other. An air introduction mechanism 4 is connected to the heating mechanism 3. The gate opening / closing mechanism 5 (cooling structure) is provided in the grip mechanism 2.

  Here, for example, when a worker operates the gate opening / closing mechanism, the gate opening / closing mechanism 5 (gate 26) described later is opened. In synchronism with this, the heating mechanism 3 operates. Air is introduced into the heating mechanism 3 through the air introduction mechanism 4. The air is heated by the heating mechanism 3. Hot air (for example, about 800 ° C.) is jetted from the heating mechanism 3.

  At this time, for example, hot air is sprayed along the part to be processed (burr) while maintaining a distance of about 20 mm to 30 mm from the part to be processed (for example, burr). The part to be processed (burrs) is melted and smoothed by the hot air. Thus, the surface processing (for example, deburring and finishing) for the processing site is completed. Hereinafter, the configuration of the hot air heater 1 will be specifically described.

"Grip mechanism 2"
As shown in FIGS. 1, 4, 5, and 6, the grip mechanism 2 includes a grip body 2a and an air supply passage 2b. The grip body 2a is made of a metal material having excellent durability and corrosion resistance, such as stainless steel. The grip body 2a has a contour (shape) that an operator can grip with fingers. The air supply passage 2b is configured along the inside of the grip body 2a. One end of the air supply passage 2b is connected to a gate opening / closing mechanism 5 (gate 26) described later. An air supply pipe 6 is connected to the other end of the air supply passage 2b. The air supply pipe 6 is connected to an air source 8 via a flow rate controller 7.

  In such a configuration, for example, room temperature air is sent from the air source 8 to the air supply pipe 6. The flow rate of the air is controlled by the flow rate controller 7. Thus, air of optimum pressure is supplied from the air supply pipe 6 toward the grip mechanism 2 (grip body 2a), that is, one end of the air supply passage 2b, in other words, the gate opening / closing mechanism 5 (gate 26) described later. The

"Heating mechanism 3"
As shown in FIGS. 1, 3 and 4, the heating mechanism 3 includes a hot air jet part 3 a at the tip thereof and a connector part 3 b at the base end thereof. The hot air injection unit 3a is configured to be able to inject hot air at an optimum temperature (for example, about 800 ° C.) toward the target during surface processing (for example, deburring and finishing). The connector portion 3b is configured to be connectable to an air introduction mechanism 4 described later.

  In the drawing, as an example, the silica cloth 9 is wound over the entire front end to the base end of the heating mechanism 3 and the entire grip mechanism 2 (grip body 2a). Furthermore, a guard coil 10 is provided along the outer periphery of the silica cloth 9 on the distal end side of the heating mechanism 3. The silica cloth 9 has a function as a heat insulating material (heat insulating material). The silica cloth 9 is, for example, a fabric using fibers containing 95% or more of silica. Thereby, the safety of the worker is achieved.

Further, the heating mechanism 3 includes a temperature sensor 11 and a base 12.
The temperature sensor 11 is disposed at the tip of the heating mechanism 3 (hot air injection unit 3a). As an example of the temperature sensor 11, a thermocouple is shown in the drawing. The temperature sensor (thermocouple) 11 is electrically connected to the temperature controller 14 via a sensor lead wire 13. The temperature controller 14 and the above-described flow rate controller 7 are both mounted on one control panel 31.

  The base 12 is disposed at the proximal end (connector portion 3b) of the heating mechanism 3. The base 12 is configured to be able to support a heat generating unit 15 and an insulating tube 16 described later. The base 12 is made of a non-metallic inorganic material having high mechanical strength, such as steatite ceramics.

Furthermore, the heating mechanism 3 includes a heat generating unit 15, an insulating tube 16, and a metal case 17.
The heat generating unit 15 is configured continuously from the proximal end (connector portion 3b) of the heating mechanism 3 to the distal end (hot air injection portion 3a). The heat generating unit 15 has both ends (one end and the other end). One end of the heat generating unit 15 is supported by the base 12. The other end of the heat generating unit 15 is positioned in the hot air injection unit 3a.

  The heat generating unit 15 includes an insulator 18 and a heating wire 19. The insulator 18 has both ends (one end and the other end). One end of the insulator 18 is supported by the base 12. The other end of the insulator 18 is positioned in the hot air injection unit 3a. As an example of the shape of the insulator 18, a cylindrical insulator 18 is shown in the drawing. The insulator 18 is made of a nonmetallic inorganic material having excellent heat resistance, such as alumina (alumina) ceramics.

  The heating wire 19 is spirally wound from the other end of the insulator 18 toward one end. The heating wire 19 is made of, for example, an iron-chromium-aluminum alloy. A power supply lead wire 20 is connected to the heating wire 19. The power supply lead wire 20 is electrically connected to the power supply 21 via the temperature controller 14.

  The insulating tube 16 is disposed along the outside of the heat generating unit 15. The insulating tube 16 is configured continuously from the proximal end (connector portion 3b) to the distal end (hot air injection portion 3a) of the heating mechanism 3 so as to cover the heat generating unit 15. The insulating tube 16 has both ends (one end and the other end). One end of the insulating tube 16 is supported by the base 12. The other end of the insulating tube 16 is positioned in the hot air injection unit 3a.

  As an example of the shape of the insulating tube 16, a hollow cylindrical insulating tube 16 is shown in the drawing. The insulating tube 16 is made of a material having excellent heat resistance such as quartz glass. Quartz glass is 100% silicon dioxide.

  The metal case 17 is disposed along the outer surface of the insulating tube 16. The metal case 17 is configured continuously from the proximal end (connector portion 3b) to the distal end (hot air injection portion 3a) of the heating mechanism 3 so as to cover the insulating tube 16. As an example of the shape of the metal case, a hollow cylindrical metal case is shown in the drawing. The metal case is made of a metal material having excellent durability and corrosion resistance, such as stainless steel.

  The metal case 17 has both ends (one end and the other end). One end of the metal case 17 is configured with the connector portion 3b (which can be connected to an air introduction mechanism 4 described later). The other end of the metal case 17 is positioned in the hot air injection part 3a. In the hot air injection part 3 a (the tip of the heating mechanism 3), the metal case 17 is configured beyond the insulating tube 16. The temperature sensor (thermocouple) 11 described above is positioned inside the metal case 17 and beyond the insulating tube 16.

  Here, an example of the hot air injection process will be described. That is, the temperature of the hot air ejected from the hot air heater 1 (the hot air ejecting unit 3 a of the heating mechanism 3) is measured by the temperature sensor (thermocouple) 11. The measurement result (temperature) is sent to the temperature controller 14 via the sensor lead wire 13. Based on the measurement result, the temperature controller 14 determines whether or not the current hot air temperature is maintained at a preset appropriate temperature (for example, about 800 ° C.).

  At this time, if the current hot air temperature is lower than the appropriate temperature, the temperature controller 14 increases the power (current) applied to the heat generating unit 15 (heating wire 19) via the power supply lead wire 20. On the other hand, when the current temperature of the hot air is higher than the appropriate temperature, the temperature controller 14 reduces the power (current) applied to the heat generating unit 15 (the heating wire 19) via the power supply lead wire 20.

  In any case, the air introduced into the heating mechanism 3 from the connector part 3b described above is sent to the hot air jet part 3a while being in direct contact with the heat generating unit 15 (the heating wire 19). During this time, the air is heated to a constant temperature (for example, about 800 ° C.).

  Thereby, the hot air of constant temperature can always be injected along a to-be-processed site | part (for example, burr | flash). As a result, the part to be processed (burr) can be uniformly melted and smoothed without unevenness. Thus, high-precision surface processing can be performed on the processing site (burr).

  As an example of a method for connecting the heating mechanism 3 (metal case 17) and the grip mechanism 2 (grip body 2a) to each other, in the drawings (FIGS. 1, 5, and 6), connection by a fixing jig 22 is used. The method is shown. In such a connection method, a portion near the base end (connector portion 3 b) of the heating mechanism 3 (metal case 17) is connected to the grip mechanism 2 (grip body 2 a) via the fixing jig 22.

  The fixing jig 22 has a pair of fixing plates 22a and 22b and a plurality of fixing screws 22c. The pair of fixing plates 22a and 22b is configured to be able to sandwich the heating mechanism 3 (metal case 17) from both outer sides. One fixing plate 22a is welded (fixed) to the grip mechanism 2 (grip body 2a). The other fixed plate 22b is configured to be disposed so as to face the one fixed plate 22a in parallel.

  Further, screw holes (not shown) are formed in the pair of fixing plates 22a and 22b at positions avoiding the heating mechanism 3 (metal case 17). Here, in a state where the two fixing plates 22a and 22b are opposed to each other in parallel, both screw holes are positioned to face each other so that the fixing screw 22c can be inserted. At this time, the fixing screw 22c is screwed into the opposing screw holes. Thereby, the heating mechanism 3 (metal case 17) is clamped by a pair of fixing plates 22a and 22b. Thus, the heating mechanism 3 (metal case 17) is supported by the grip mechanism 2 (grip body 2a) at a portion near the base end.

  In this configuration, the sensor lead wire 13 and the power supply lead wire 20 are wired to the temperature controller 14 from the air introduction mechanism 4 described later via the grip mechanism 2 (grip body 2a).

"Air introduction mechanism 4"
As shown in FIG. 1, the air introduction mechanism 4 is arranged and configured over the region opposite to the tip (hot air injection unit 3 a) side of the heating mechanism 3 together with the sensor lead wire 13 and the power supply lead wire 20 described above. Yes. The diametrically opposite region is defined along the same plane including the grip mechanism 2 (grip body 2a) from the tip of the heating mechanism 3 (hot air injection part 3a). Thus, the air introduction mechanism 4 and the tip (hot air injection part 3a) side of the heating mechanism 3 are arranged to face both sides of the grip mechanism 2 (grip body 2a).

  The air introduction mechanism 4 includes a hollow air pipe 4a. The air supply pipe 4a is configured to allow air to pass along the inside thereof. The air supply pipe 4a has flexibility. The air supply pipe 4a has both ends (one end and the other end). One end of the air supply pipe 4 a is connected to the base end (connector portion 3 b) of the heating mechanism 3.

  The other end of the air supply pipe 4a is connected to the grip mechanism 2 (grip body 2a). The other end of the air supply pipe 4a is connected to a gate opening / closing mechanism 5 (gate 26) described later. The other end of the air supply pipe 4a is connected to one end of the air supply passage 2b of the grip mechanism 2 (grip body 2a) described above via a gate opening / closing mechanism 5 (gate 26) described later.

  In such a configuration, when a gate opening / closing mechanism 5 (gate 26), which will be described later, is opened, the air supplied from the air source 8 to one end of the air supply passage 2b passes through the gate 26 and passes through the air introduction mechanism 4 (feed). Sent to the trachea 4a). The fed air is introduced into the heating mechanism 3 from the connector portion 3b. Thus, the air heated by the heating mechanism 3 can be jetted from the hot air jet section 3a.

"Gate opening and closing mechanism 5"
As shown in FIGS. 1, 5, and 6, the gate opening / closing mechanism 5 performs surface processing (for example, deburring and finishing) on a resin molded product (for example, bumper Bp, grill Gr (see FIG. 2)). The air supplied from the air source 8 (see FIG. 4) to one end of the air supply passage 2b can be sent to the air introduction mechanism 4 (air supply pipe 4a) via a gate 26 described later. Therefore, the gate opening / closing mechanism 5 includes an operation lever 23, a movable shaft 24, a valve body 25, a gate 26, a valve seat 27, and an urging jig 28.

  The operation lever 23 is configured to be operable with a finger (for example, index finger or middle finger) of the worker in a state where the worker grips the grip mechanism 2 (grip body 2a). The operation lever 23 has both ends (a tip end and a base end). The base end of the operation lever 23 is supported rotatably with respect to the grip mechanism 2 (grip body 2a). The tip of the operation lever 23 is configured to be able to hook an operator's finger.

  In such a configuration, the finger hooked on the operation lever 23 is pulled toward the front, that is, toward the grip body 2a. Thereby, the operation lever 23 can be operated (turned) with the above-mentioned base end as the rotation center. The operation (turning) motion of the operation lever 23 is transmitted to the movable shaft 24.

  The movable shaft 24 is configured to reciprocate (linearly) in a certain direction (for example, the directions of arrows S1 and S2 (see FIGS. 5 and 6)) following the operation (turning) motion of the operation lever 23. The movable shaft 24 has both ends (one end and the other end). One end of the movable shaft 24 is configured to be always in contact with the operation lever 23. A valve body 25 is connected to the other end of the movable shaft 24. As an example of the shape of the valve body 25, a spherical valve body 25 is shown in the drawing.

  The valve body 25 is disposed in the air guide passage 29. The air guide passage 29 is configured in the grip mechanism 2 (grip body 2a). The air guide passage 29 is connected to the air introduction mechanism 4 (the air supply pipe 4a). The air guide passage 29 is configured so as to be separated from one end of the air supply passage 2 b described above via the partition wall 30. That is, the partition wall 30 is interposed between the air guide passage 29 and one end of the air supply passage 2b.

  The gate 26 is configured to penetrate one place of the partition wall 30. The gate 26 has a hollow cylindrical shape (circular cross section). The air guide passage 29 and one end of the air supply passage 2 b are connected to each other via the gate 26. The spherical valve body 25 described above is configured to be larger than the gate 26.

  According to this configuration, the gate 26 is closed with the valve body 25 in contact with the gate 26. On the other hand, the gate 26 is opened in a state where the valve body 25 is separated from the gate 26. Here, in a state where the gate 26 is opened, the air supplied to one end of the air supply passage 2b can be sent to the air introduction mechanism 4 (air supply pipe 4a) via the gate 26. Thus, the gate 26 is configured to be able to send air to the heating mechanism 3 (the air guide passage 29, the air introduction mechanism 4 (air supply pipe 4a)) when performing surface processing with hot air.

  The valve seat 27 is provided on the partition wall 30 along the outer periphery of the circular gate 26 described above. The valve seat 27 is configured such that the spherical valve body 25 can be contacted without a gap. The valve seat 27 has a hollow annular shape. As an example of the shape of the valve seat 27, the valve seat 27 having a contour shape along a spherical surface is shown in the drawing.

  According to such a configuration, the valve body 25 contacts the valve seat 27 without a gap in a state where the valve body 25 is brought into contact with the gate 26 by an urging jig 28 described later. In other words, the valve body 25 is tightly (closely) tightly (liquid tight) to the valve seat 27. Thus, the gate 26 is closed in an airtight (liquid-tight) manner by the valve body 25.

  The biasing jig 28 includes a compression spring. The compression spring 28 has both ends (one end and the other end). One end of the compression spring 28 is connected to the valve body 25. The other end of the compression spring 28 is connected to the grip mechanism 2 (grip body 2a).

  According to this configuration, the valve body 25 is always kept in close contact (close contact) with the valve seat 27 by the urging force of the compression spring 28. At this time, the gate 26 is closed. In this state, the air supplied to one end of the air supply passage 2b cannot be sent to the air introduction mechanism 4 (air supply pipe 4a) via the gate 26.

  Further, in this state, the movable shaft 24 to which the valve body 25 is connected is maintained in a state of moving in the arrow S1 direction in FIG. At this time, the operation lever 23 is pressed by one end of the movable shaft 24 and is positioned away from the grip mechanism 2 (grip body 2a) (hereinafter referred to as “initial position” of the operation lever 23).

  Here, the operator pulls the operation lever 23 at the “initial position” toward the front and turns the operation lever 23 (ON operation of the operation lever 23). A pressing force against the urging force of the compression spring 28 acts on one end of the movable shaft 24 from the operation lever 23. The movable shaft 24 is maintained in a state of moving in the direction of the arrow S2 in FIG. 6 (that is, the direction opposite to the arrow S1).

  In this state, the valve body 25 follows the other end of the movable shaft 24 and is separated from the valve seat 27. At this time, the gate 26 is opened. Thus, the air supplied to one end of the air supply passage 2b can be sent to the heating mechanism 3 via the air introduction mechanism 4 (air supply pipe 4a).

  On the other hand, the worker releases the operation lever 23 (OFF operation of the operation lever 23). The biasing force of the compression spring 28 acts on the movable shaft 24. The movable shaft 24 is maintained in a state of moving in the direction of arrow S1 in FIG. The operation lever 23 returns to the “initial position” by turning following the one end of the movable shaft 24.

  In this state, the valve body 25 follows the other end of the movable shaft 24 and contacts the valve seat 27 without a gap. At this time, the gate 26 is closed in an airtight (liquid-tight) manner by the valve body 25. Thus, the air supplied to one end of the air supply passage 2b cannot be sent to the heating mechanism 3 via the air introduction mechanism 4 (air supply pipe 4a).

"ON / OFF control of hot air heater 1"
In the state where the operation lever 23 is in the initial position (see FIG. 5) (OFF state of the operation lever 23), that is, in the state where the gate 26 is closed, the flow of the air sent from the air source 8 is the valve body 25. Will be dammed up. For this reason, the pressure level of air at one end of the air supply passage 2b increases.

  The increase in the pressure level is reflected in the flow rate controller 7 through the air supply pipe 6. The flow controller 7 controls the pressure level within a certain allowable range. At this time, a control signal is output from the flow rate controller 7 to the temperature controller 14.

  With this control signal, the temperature controller 14 controls the power (current) applied to the heat generating unit 15 (heating wire 19) to zero. Thus, the operation of the heating mechanism 3 is controlled to stop. That is, the heating of the heating wire 19 is controlled to stop. In other words, the hot air injection from the hot air injection unit 3a is controlled to stop.

  In this state, the operation lever 23 is turned on. The gate 26 is opened. Air (that is, compressed air) supplied to one end of the air supply passage 2b diffuses into the air guide passage 29 through the gate 26 (specifically, the gap between the gate 26 and the valve body 25). The diffused air is introduced into the heating mechanism 4 through the air introduction mechanism 4 (air supply pipe 4a).

  Here, when the air is diffused, the pressure level of the air at one end of the air supply passage 2b is lowered. The flow controller 7 controls the pressure level within a certain allowable range. For example, control is performed to send air from the air source 8 to the air supply pipe 6. Thereby, a certain amount (pressure) of air is introduced into the heating mechanism 3. At this time, a control signal is output from the flow rate controller 7 to the temperature controller 14.

  With this control signal, the temperature controller 14 applies power (current) to the heat generating unit 15 (heating wire 19). The heat generating unit 15 (heating wire 19) generates heat. The air introduced into the heating mechanism 3 is sent to the hot air jet unit 3a while being in direct contact with the heat generating unit 15 (the heating wire 19). Thus, after the air is heated to a constant temperature, it is injected from the hot air injection unit 3a toward the target.

  Subsequently, the operation lever 23 is turned off. The gate 26 is closed. The flow of the air sent from the air source 8 is blocked by the valve body 25. The air pressure level at one end of the air supply passage 2b increases.

  Here, when the air pressure level rises, the flow controller 7 controls the pressure level within a certain allowable range. For example, the air supply from the air source 8 to the air supply pipe 6 is controlled to stop. At this time, a control signal is output from the flow rate controller 7 to the temperature controller 14.

  With this control signal, the temperature controller 14 controls the power (current) applied to the heat generating unit 15 (heating wire 19) to zero. Thereby, the operation of the heating mechanism 3 is controlled to stop. Thus, hot air injection from the hot air injection section 3a is controlled to stop.

  By the way, in the above-described ON / OFF control of the hot air heater 1, it is preferable to perform uncontrollable automatic return during hot air injection stop control. For example, during the stop control of the heating mechanism 3, even if the operation lever 23 is turned on again, control that does not activate the heating mechanism 3 (that is, automatic return impossible control) is performed. Thereby, inadvertent injection of hot air can be avoided beforehand. Thus, it is possible to ensure safety for the worker or the part to be processed.

"Gate open / close mechanism 5 including cooling structure"
In the gate opening / closing mechanism 5 described above, when the operation lever 23 is turned ON, the air supplied to one end of the air supply passage 2b (that is, compressed air) is supplied to the gate 26 (specifically, the gap between the gate 26 and the valve element 25). ) To the air guide passage 29. Here, when compressed air diffuses, the air pushes away air (atmosphere) that is pushed from the outside (ambient).

  More specifically, the air passage composed of one end of the air supply passage 2b, the gate 26, and the air guide passage 29 is a relatively wide passage after the passage width is narrowed by the gate 26 from a relatively wide passage. It is comprised so that.

  According to such a passage configuration, the compressed air diffuses radially toward the outside (periphery) when flowing from the narrow gate 26 to the wide passage. That is, the compressed air is squeezed (compressed) by the gate 26 when passing through the gate 26 and then released by passing through the gate 26. Thereby, the air diffuses radially toward the outside (surrounding).

  At this time, the air has consumed energy with respect to the outside world (ambient). As a result, the temperature of the air decreases by the amount of energy consumed. In other words, according to the energy conservation law, air diffuses as cold air. That is, the air is cooled. Thus, the grip mechanism 2 (grip body 2a) is cooled by the diffused cold air.

  As a result, the gate opening / closing mechanism 5 includes a so-called cooling structure and is configured to exhibit a cooling function. That is, during the ON operation of the operation lever 23, the grip mechanism 2 (grip body 2 a) is continuously cooled by the cold air that diffuses toward the air guide passage 29.

  By the way, when the heat generating unit 15 (the heating wire 19) generates heat in synchronization with the ON operation of the operation lever 23, the heat is transferred from the heating mechanism 3 (metal case 17) via the fixing jig 22 to the grip mechanism 2 ( Conducted to the grip body 2a). In this case, depending on the temperature of the conducted heat, the grip mechanism 2 (grip body 2a) may be heated to a high temperature.

  However, according to the cooling structure described above, the heat conducted from the heating mechanism 3 (metal case 17) to the grip mechanism 2 (grip body 2a) is sequentially cooled by the cold air that continues to diffuse from the gate 26. As a result, the grip mechanism 2 (grip body 2a) is not heated to a high temperature.

“Operation and Effect of One Embodiment”
According to the present embodiment, in synchronization with the ON operation of the operation lever 23, when the heat generating unit 15 (heating wire 19) generates heat, the heating mechanism 3 (metal case 17) changes to the grip mechanism 2 (grip body 2a). The conducted heat is sequentially cooled by a cooling structure using air supplied to the heating mechanism 3 (that is, cold air diffusing from the gate 26). Thereby, the grip mechanism 2 (grip body 2a) is not heated to a high temperature during surface processing with hot air. As a result, it is possible to realize the hot air heater 1 that can sufficiently ensure safety for workers.

  According to the present embodiment, a cooling structure using the existing gate opening / closing mechanism 5 as it is is realized without providing an existing cooling device separately. Thereby, while the number of parts of the hot air heater 1 can be reduced significantly, the structure can be simplified. As a result, the hot air heater 1 that is lightweight, compact, and low-cost can be realized.

  According to the present embodiment, in synchronism with the OFF operation of the operation lever 23, the air supply from the air source 8 is stopped and the operation of the heating mechanism 3 (the heat generating unit 15 (the heating wire 19)) is stopped. To do. Thereby, while being able to aim at reduction of electric power consumption, the safety | security with respect to an operator or a to-be-processed site | part can be ensured.

  According to the present embodiment, the silica cloth 9 is wound around the entire base end and the entire base end of the heating mechanism 3 and the entire grip mechanism 2 (grip body 2a), and the front end side of the heating mechanism 3 is also provided. A guard coil 10 is provided along the outer periphery of the silica cloth 9. Thereby, the safety | security with respect to a worker or a to-be-processed site | part can be ensured more fully.

  According to this embodiment, the air introduced into the heating mechanism 3 is sent to the hot air jet unit 3a while being in direct contact with the heat generating unit 15 (the heating wire 19). Thereby, highly accurate surface processing can be performed, maintaining the processing effect comparable as the surface processing using a flame (burner).

  According to the present embodiment, the air introduction mechanism 4 is arranged and configured along with the sensor lead wire 13 and the power supply lead wire 20 in a region opposite to the front end (hot air injection unit 3a) side of the heating mechanism 3. Thereby, the balance center (for example, center of gravity) of the hot air heater 1 can be positioned at or near the center of the grip mechanism 2 (grip body 2a). As a result, the operability and handleability of the hot air heater 1 can be dramatically improved. Thus, high-precision surface processing can be performed on the processing site (burr).

DESCRIPTION OF SYMBOLS 1 ... Hot air heater, 2 ... Grip mechanism, 3 ... Heating mechanism, 4 ... Air introduction mechanism,
5 ... Gate opening / closing mechanism (cooling structure), 6 ... Air supply pipe, 9 ... Silica cloth,
10 ... guard coil, 22 ... fixing jig, 23 ... operating lever.

Claims (4)

It is a handy type hot air heater that performs surface processing on the workpiece by injecting hot air,
A heating mechanism capable of injecting hot air heated from the air along the part to be processed;
A grip mechanism that is connected to the heating mechanism and can be gripped by an operator;
An air introduction mechanism capable of introducing air into the heating mechanism;
A hot air heater provided in the grip mechanism and having a cooling structure that cools heat conducted from the heating mechanism to the grip mechanism by diffusing air to cool the air. The cooling structure includes a gate capable of sending air to the heating mechanism when performing surface processing with hot air,
The air is squeezed by the gate when passing through the gate, and then released after passing through the gate, so that the air diffuses radially toward the outside, thereby cooling the air. The hot air heater described. A gate opening / closing mechanism including the cooling structure;
The gate opening / closing mechanism includes an operation lever for opening or closing the gate,
In a state where the gate is opened by the operation lever, air can be sent to the heating mechanism,
3. The hot air heater according to claim 2, wherein air cannot be sent to the heating mechanism and the operation of the heating mechanism is controlled to stop while the gate is closed by the operation lever.   The air introduction mechanism is arranged and configured over a region opposite to the heating mechanism, and the air introduction mechanism and the heating mechanism are arranged to face both sides of the grip mechanism, Thereby, the balance center of a hot air heater is located in the center of the said grip mechanism thru | or its vicinity, The hot air heater of Claim 1.

Images