JPH0277270A - Microwave remedying device - Google Patents

Abstract

PURPOSE:To effectively cool a magnetron and to prevent an outer surface from being made into a high temperature by housing the shield case of the magnetron and a radiator in a housing, forming a wind route for cooling to communicate outside the housing around the shield case and causing a wind to flow to the wind route for cooling outside the shield case. CONSTITUTION:Since a shield case 12 of a magnetron 1 and a radiating plate 2 are housed in a housing 4, the shield case 12 and radiating plate 2 to be easily made into the high temperature are not exposed outside a remedying device, and the fact is safe to a parient and a worker. Since, in the housing 4, a wind route 6 for cooling a magnetron and a wind route 7 for cooling a radiator are provided and a cooling fan 5 to feed the winds to the wind routes 6 and 7 for cooling is provided, by feeding the wind around the shield case 12 and radiating plate 2 through the wind routes 6 and 7 by the cooling fan 5, the magnetron 1 and radiating plate 2 can be effectively cooled.

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a microwave therapy device used for medical purposes.

<Conventional technology and problems to be solved by the invention> Conventionally, microwaves are irradiated to the human body to generate heat inside the tissue.
There are microwave therapy devices that use their thermal effects to recover from muscle fatigue and treat neuralgia. Microwave irradiation by this microwave treatment device is also used for beauty treatments and the like.

Some of the above-mentioned microwave treatment devices have a magnetron that generates microwaves and a radiator that emits the microwaves, which are configured separately, and the magnetron and the radiator are connected by a cable, but the device is complicated. Along with this, there was a problem in that the operating efficiency decreased due to the difficulty of converting the output from the magnetron to the cable.

On the other hand, magnetrons generate heat during operation, resulting in high temperatures, which shortens the life of a cathode made of a filament or the like.

Therefore, in order to solve the above problems, a magnetron and a radiator are constructed integrally, and a fan for cooling the magnetron is provided inside the shield case of the magnetron. (See Publication No. 8464).

However, in the integrated type, the shield case of the high-temperature magnetron and the radiator that receives heat conduction from the magnetron are exposed to the outside, which is dangerous for patients, workers, etc. Furthermore, since the fan is disposed inside the shield case, there is a risk that the power supply line of the motor for driving the fan may be burned out due to the influence of leaked microwaves.

An object of the present invention is to provide a highly safe microwave treatment device that can effectively cool the magnetron and prevent the outer surface from becoming hot.

Means for Solving the Problems> The microwave therapy device of the present invention for achieving the above object is a microwave therapy device that integrally connects a magnetron and a radiator that emits microwaves generated by the magnetron. In the device, the shield case of the magnetron and the radiator are housed in the housing, and
A cooling air passage communicating with the outside of the housing is formed at least around the shield case, and a ventilation means for flowing air into the cooling air passage is provided outside the shield case.

According to the microwave treatment device having the above configuration, the shield case of the magnetron and the radiator are housed in the housing, so the high temperature shield case and the radiator are not exposed to the outside, and furthermore, at least A cooling air passage communicating with the outside of the housing is formed around the shield case, and a ventilation means is provided to flow air into the cooling air passage. By blowing air through the magnetron, the magnetron can be effectively cooled. Further, since the ventilation means is provided outside the shield case, it is possible to prevent leakage microwaves from leaking into the power supply line of the motor for driving the ventilation means.

<Example> Embodiments will be described in detail below with reference to the accompanying drawings showing embodiments.

FIG. 1 is a sectional view showing one embodiment of the microwave treatment device of the present invention, in which a magnetron (1) and a radiation plate opening as a radiator are integrally connected, and the magnetron (
1) is housed in the duct G), and the duct (
3) and a radiation plate (2) are housed in a housing (4), and a magnetron (
1), a magnetron cooling air path (6) for cooling the radiator plate (2), and a radiator cooling air path (7) for cooling the radiation plate (2).
).

The magnetron (1) is a bipolar vacuum tube that generates microwaves from an antenna rod (11) by controlling the flow of electrons using a magnetic field. ) is housed within. This shield case (12) is for preventing leakage of electrons, and the screw (35) connects the duct (
3) (see Figure 2). A plurality of heat radiation fins (13) are attached to the inner surface of the shield case (12).

The radiation plate (2) is a cone-shaped plate that spreads forward and is attached by screws (21) around the antenna rod (11) on the front of the shield case (12). This system radiates microwaves forward in the form of a beam. An outwardly extending portion (22) is formed on the front edge of the radiation plate (2), and the peripheral edge of the extending portion (22) is in contact with the inner periphery of the housing (4). The inside of the housing (4) is partitioned into front and rear parts by this radiation plate (2). Also, this radiation plate■
A plurality of air circulation holes (23) are bored in the radiator plate (23), and air can flow between the front and rear of the radiation plate (2) through the air circulation holes (23).

The housing (4) is a cylindrical body made of synthetic resin, and the front surface (41) of the housing (4) is made of a material with excellent high frequency characteristics such as polypropylene. Further, an intake hole (not shown) is provided at the rear of the housing (4),
A plurality of exhaust holes (42) are provided in the lower part of the housing (4). Furthermore, horizontal partition pieces (43) (44) are provided on the inner surface of both sides of the housing (4), and the tips of the partition pieces (43) (44) are attached to air seals (made of urethane foam, etc.). With 24) attached,
It is pressed against the back surface of the radiation plate (2). Moreover, a rib (45) that forms the same plane as the partition piece (43) is provided on the inner surface of the side portion of the housing (4).

As shown in Fig. 3, the duct (3) consists of a box with one side and the bottom open on the side of the radiation plate (2), and the top side has a
A ventilation hole (31) is provided. Also, duct (3)
Along the periphery of the front side, three partition plates (32) (
3() (34) is erected. Partition plate (82)
extends upward, and the partition plates (33) and (34) extend to both sides.

Further, at the lower part of the rear surface of the duct (3), there is a bush (15) that holds and holds the power supply line (14) of the magnetron (1).
A notch (35) is provided for holding the. The power supply line (14) is connected to the power supply device (A) (
4th diagram).

The negative side of the duct (3) is attached to the housing (4) with the duct mounting screw (3B), and the other side is pressed against the cushioning material (46) attached to the rib (45). There is. Also, the partition plate (32) of the duct (3)
(33) and (34) are in contact with the inner surface of the housing (4).

On the top surface of the duct (3), there is a connection between the ventilation hole (31) and the duct (
3) Cooling fan (5) as a means of ventilation to blow air inside
are attached by screws (51).

The magnetron cooling air passage (6) is connected to the shield case (12) of the magnetron (1) by the duct (3).
The wind that is sent into the magnetron cooling air passage (6) by the cooling fan 6) flows from above to below around the shield case (12) and absorbs the heat of the shield case (12). After removing the air, it passes through the exhaust hole (42) of the housing (4) and reaches the outside of the housing (4).

The radiator cooling air passage (7) includes an upper space (71) on the back side of the radiating plate (2), a front side space (72) surrounded by the radiating plate (2) and the front surface of the housing (4), and the radiating plate (2). ) consists of a lower space (73) on the back side. Cooling fan (5)
The air sent from the front upper part of the duct (3) into the radiator cooling air passage (7) passes through the air circulation hole (23) at the upper part of the radiator plate (2) from the rear upper space (71). , flows from above to below in the front side space (72) of the radiating plate ■, and after removing heat from the radiating plate ■ and the antenna rod (11), the radiating plate (2
It passes through the lower air circulation hole (23) and enters the lower space on the back side (
73) and passes through the exhaust hole (42) of the housing (4) to reach the outside of the treatment device. In addition, the partition piece (43)
(44) and the air seal (24) allow the air from the cooling fan 6) to bypass the radiator cooling air path (7), pass through the back side of the radiator plate (2), and be discharged to the outside of the housing (4). is prevented.

According to this embodiment, since the shield case (12) and the radiation plate (1) of the magnetron (1) are housed in the housing (4), the shield case (12) becomes hot and the shield case (12) becomes hot.
) and radiation plate ('2J) are not exposed to the outside of the treatment device, making it safe for patients and workers.
) are provided with a magnetron cooling air passage (6) and a radiator cooling air passage (6).
Since a cooling fan 6) is provided to send air to 7), the cooling fan (5) sends air around the shield case (12) and the radiation plate (1) through the cooling air channels (6) and (7). As a result, the magnetron (1) and the radiation plate (2) can be effectively cooled.

Furthermore, the shield case (12) of the magnetron (1)
A duct opening) is disposed between the duct G) and the housing (4), and an air layer is formed on both sides of the duct (3), and the duct G) and the housing (4) are in contact with each other. Since the area is reduced, the temperature increase on the outer surface of the treatment device is further suppressed, resulting in higher safety. Also, as mentioned above, since the housing (4) does not reach high temperatures, the housing (4)
Even if you do not use a material with particularly excellent heat resistance as the material for
It is possible to use common materials and is advantageous in terms of cost.

Furthermore, since the cooling fan 6) is placed outside the shield case (12), there is a risk that the power supply line of the motor (not shown) for driving the cooling fan 6) may be burnt out due to the influence of leaked microwaves. It is highly safe.

In addition, a duct (3) with a magnetron (1) attached.
is the housing (4) via the cushion material (4B).
Since it is elastically supported, the magnetron (1) can be protected from shocks and vibrations, and the life of the cathode filament can be extended.

FIG. 5 and FIG. 6 are a longitudinal cross-sectional view and a cross-sectional view showing another embodiment. The structure of the microwave treatment device of this embodiment differs from that of the embodiment shown in FIG. (see figure), the radiation plate (2') does not have an air circulation hole, and the nozzle housing (4') does not have a partition piece (see figure 5). Since the rest is the same as the embodiment shown in FIG. 1, the same reference numerals are given to the drawings and the explanation thereof will be omitted.

According to this embodiment, a magnetron (1
), the entire structure can be effectively cooled, and the same effect as the embodiment shown in FIG. 1 can be achieved.

Note that the microwave treatment device of the present invention is not limited to the above-mentioned embodiments. For example, the duct and partition plate may be configured with other shapes, or the magnetron (1) may be configured without providing a duct. Various design changes can be made without changing the gist of the invention, such as forming an air passage between the housing and the nozzle housing (4).

<Effects of the Invention> As described above, according to the microwave treatment device of the present invention,
7) Since the shield case and radiator are housed in the housing, the high temperature shield case and radiator are not exposed to the outside, ensuring safety for patients and workers, and furthermore,
At least around the shield case, a cooling air passage communicating with the outside of the housing is formed, and a ventilation means for flowing air into the cooling air passage is provided. The magnetron can be effectively cooled by blowing air around it, and since the ventilation means is provided outside the shield case, the power supply line of the drive motor of the ventilation means, etc. can be prevented from leaking microwaves. It has the unique effect of being highly safe, as it can prevent burnout due to the effects of

[Brief explanation of the drawing]

Fig. 1 is a longitudinal cross-sectional view showing one embodiment of the microwave treatment device of the present invention, Fig. 2 is a cross-sectional view along the line ■-■, Fig. 3 is a perspective view of the duct, and Fig. 4 is the entire treatment device. FIG. 5 is a longitudinal sectional view showing another embodiment, FIG. 6 is a Vl-Vl sectional view thereof, and FIG. 7 is a perspective view of the duct. (1)...Magnetron, (12)...Shield case, (2)(2')...Radiation plate as a radiator, +4)(
4')...Housing, (5)...Cooling fan as ventilation means, (6) (
7)...Cooling air path.

Claims (1)

[Claims] 1. By the magnetron and the magnetron A radiator that emits microwaves generated by A microwave treatment device that is integrally connected with In this case, the magnetron shield case the base and the radiator are housed in the housing. With at least a shield case cooling that communicates with the outside of the housing. Forms a ventilation path and protects the outside of the shield case. A ventilation means is installed to flow air through the cooling air path. Microwave treatment characterized by Medical equipment.