JPH0233365Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a fixed attenuator equipped with a flat resistor plate having a resistor section and an electrode section on one side of an insulating substrate. The present invention relates to a fixed attenuator for high power that can withstand high power by efficiently dissipating Joule heat generated in the resistor without disturbing the characteristic impedance of the planar resistor.

[Conventional technology] The first conventional technique will be explained.

Conventionally, there are fixed attenuators of this type, particularly those for high frequencies, as shown in FIGS. 2A and 2B.

What is shown in these figures is an inner shaft 1 and an outer conductor 2.
A stripline section is provided in the center of the coaxial line, a planar resistor plate 3 is attached thereto, and a center conductor 4 is connected to the stripline section.

The planar resistance plate 3 is shown in FIGS. 3A and 3B.
As shown in the figure, a resistor section 11, an inner conductor electrode 12, and an outer conductor electrode 13 are formed on an insulating substrate 10. A matching conductor portion 5 is provided facing the resistor portion 11 side of the flat resistor plate 3 at a predetermined interval.

A second conventional technique is the technique described in Japanese Utility Model Publication No. 56-36162.

This technology creates a resistor unit that is completely grounded and has a good heat sink by fixing the resistor board to a metal carrier in advance, and uses it as a mounting structure for an attenuator for microwave integrated circuits. .

A third conventional technique is the technique described in Japanese Utility Model Publication No. 59-805.

This technology can be used as a high-frequency pseudo load for high power.
This uses a resistive film formed around the outer periphery of a heat pipe made of an electrical insulator.

However, this conventional fixed attenuator has the following problems, and its use is limited.

[Problems to be Solved by the Invention] By the way, as the applied power increases in the resistor section of the fixed attenuator, the Joule heat naturally increases and its temperature rises. One possible solution to this problem is to increase the rated power by enlarging the shape of the resistor section.

However, if the shape of the resistor section is made large, it becomes capacitive, and as a result, impedance matching cannot be achieved beyond a certain frequency. On the other hand,
If an attempt is made to cope with this problem by increasing the thickness t of the insulating substrate, the thermal resistance will increase and the temperature of the resistor portion will rise, returning the problem to the beginning.

As described above, in the case of the fixed attenuator of the first prior art, if the rated power is to be increased, the shape and dimensions of the resistor must be increased in an accelerated manner.
As a result, the frequency limit for use has to be lowered.
In other words, in conventional fixed attenuators, when the operating frequency limit is set high, the shape of the resistor becomes smaller,
The drawback was that the rated power was limited.

Further, in the second conventional technique, since a metal carrier is used, there is a problem in that it affects the impedance characteristics of the resistor, and the effect on the impedance characteristics is particularly large in a high frequency range.

Furthermore, in the third prior art, the resistive film is formed directly on the outer periphery of the heat pipe, so the structure requires the heat pipe to pass directly into the waveguide. Therefore, this third prior art discloses only a fixed attenuator provided with a tubular resistor, and cannot be applied to a fixed attenuator provided with a planar resistor.

This invention was made to solve the above problems, and by improving the heat dissipation characteristics of the resistor part, it is possible to obtain a large rated power even with a resistor with a small shape and size, and to set a high operating frequency limit. It is an object of the present invention to provide a fixed attenuator for high power that can handle high power.

[Means for Solving the Problems] The present invention is a fixing method consisting of a flat resistor plate, which has a resistor section and an electrode section on one side of an insulating substrate, and is surrounded by an outer conductor. In the attenuator, as a means for solving the above problem, a space portion where no conductor exists is provided at a position corresponding to the resistor portion of the outer conductor disposed on the other side of the insulating substrate, Further, a heat pipe is provided in this space, and the heat pipe is characterized in that the open end of the heat receiving portion is disposed on the other surface of the insulating substrate without intervening metal.

In the above configuration, the heat pipe is configured by enclosing a working fluid in a closed container having an arbitrary shape (usually a tube shape). In the present invention, the heat receiving side end of the heat pipe is provided with an open end, and the open end is attached to the surface of the insulating substrate on which the resistor part and the electrode part are not provided, either directly or through a non-metallic lid. It's stuck. Thereby, the heat pipe is sealed by the insulating substrate and the lid.

Note that the heat pipe may be sealed with a lid before being fixed. Further, the heat pipe itself may be formed of a non-metallic material. In this case,
Since the lid body is provided integrally with the heat pipe body, fixing via the non-metallic lid body in the above problem solving means means that the heat receiving end of the sealed heat pipe is placed on the surface of the insulating substrate. means to stick. Therefore, in the present invention, either an open heat pipe or a closed heat pipe can be used as the heat pipe.

When using the former heat pipe, the seal is
For example, by bonding the open end of the heat pipe and the insulating substrate surface with an adhesive, or by using an O-ring,
This is done by contacting and sealing the open end of the heat pipe and the surface of the insulating substrate.

Although the present invention relates to a fixed attenuator, it also includes a terminator. The reason is,
This is because the high-frequency terminator can be regarded as a device in which the output terminal of the high-frequency fixed attenuator is grounded, and can be easily manufactured with a similar structure.

[Function] In the above configuration, when the heat receiving side of the heat pipe is heated, the working fluid sealed inside evaporates due to this heat, creating a local pressure difference, and the heat dissipating side of the other end evaporates. This creates a flow of steam towards. Then, when the steam condenses on the heat radiating part side, heat is radiated. In this way, heat pipes rapidly transfer heat in the form of latent heat.

Therefore, by bringing the end of the heat pipe closer to the heat receiving section into close contact with the insulating substrate, the heat generated in the resistor section can be rapidly removed. Therefore, temperature rise due to Joule heat in the resistor portion is suppressed.

As a result, it becomes possible to withstand high power.
Furthermore, since the shape and dimensions of the resistor portion are not increased, the usable frequency limit will not be lowered.

Furthermore, in the present invention, the end portion of the heat pipe on the side of the heat receiving portion is sealed with an insulating substrate or a non-metallic lid, and there is less metal material in parallel with the resistor portion. Therefore, the characteristic impedance of the planar resistor is not disturbed, and the influence on the characteristics in the high frequency range is small.

[Example] An example of the present invention will be described with reference to the drawings.

<Configuration of Embodiment> FIG. 1 shows an embodiment of the high power fixed attenuator of the present invention.

The fixed attenuator shown in the figure consists of an inner shaft 1 and an outer conductor 2.
A triplate line part 2a is provided at an appropriate location of the coaxial line consisting of the above, and a planar resistance plate 3 is attached thereto.A center conductor 4 is connected to this, and a heat pipe is installed on the back side of the planar resistance plate 3. It is constructed by fixing 6.

The planar resistance plate 3 used is the same as that shown in FIGS. 3A and 3B described above. A matching conductor portion 5 is provided facing the resistor portion 11 side of the flat resistor plate 3 at a predetermined interval. This is for impedance matching.

In this embodiment, the heat pipe 6 is made of the same metal as the triplate line portion 2a and is provided integrally therewith, and is formed by protruding the pipe portion 6a outside the triplate line portion 2a. The heat receiving portion 6b of the heat pipe 6 is provided in an open manner. On the other hand, the heat radiation section 6c is provided in a closed manner,
Furthermore, on the outside of the heat radiation part 6c of the pipe part 6a,
Cooling fins 9 are provided. heat pipe 6
Inside, a wick 7 is provided along the inner periphery of the pipe portion 6a.

The heat receiving portion 6b of the heat pipe 6 is hermetically sealed with an insulating substrate 10. Insulating substrate 10
is adhered to the end of the heat receiving part 6b with an adhesive (not shown). That is, the open end of the heat receiving portion of the heat pipe is fixed to the surface of the insulating substrate without intervening metal.

The heat pipe 6 is provided with a working fluid 8 before being sealed.
Inject. For example, water can be used as the working fluid. In addition, in order to reduce the pressure inside, for example, the working fluid may be boiled and injected, and then sealed before the temperature drops.

<Operation of the embodiment> In the above configuration, when a terminator is connected to one end of the inner shaft 1 and high frequency power is applied to the other end, Joule heat is generated in the resistor part 11 (see Fig. 3A). and the temperature rises. This heat reaches the opposite surface of the insulating substrate 10 according to the temperature gradient,
Here, the working fluid 8 in the heat pipe 6 is heated.

The heated working fluid 8 vaporizes and removes this heat as latent heat, while locally creating a pressure difference within the heat pipe 6. This pressure difference causes
The working fluid vapor moves toward the heat radiation section 6c at high speed.

In the heat dissipation section 6c, the working fluid vapor touches the low temperature pipe wall of the pipe section 6a, condenses, and releases latent heat. The released heat is exchanged with external air via the fins 9. On the other hand, the condensed working fluid becomes droplets and passes through the wick 7 to the heat receiving part 6.
Reflux to b.

In addition, when the condensed working fluid flows down or drips due to gravity and circulates, the wick 7 is not necessary.

The refluxed working fluid 8 is heated again, vaporized, and acts in the same manner as described above. This series of circulation consisting of ``vaporization, movement, condensation, and reflux'' of the working fluid achieves a high thermal conductivity approximately 1,000 times that of copper, rapidly removing the heat generated in the resistor. It can be cooled efficiently.

Here, a heat pipe 6 is fixed to the ground side of the flat resistance plate 3, and a heat receiving part 6b of the heat pipe 6 is provided in an open manner and is sealed with an insulating substrate. . Therefore, the planar resistance plate 3
Since only the working fluid and its vapor exist on the back side of the resistor part, the impedance of this part is relatively high, and if the size and facing distance of the matching conductor part 5 are set appropriately, the desired value can be achieved. The impedance can be maintained at

<Modification of Embodiment> In the above embodiment, the heat pipe 6 is made of the same metal as the triplate line portion 2a and is provided integrally therewith, but it may also be provided separately. In this case, the heat pipe is attached by fitting or screwing into a hole provided in the triplate line portion.

Further, in the above embodiment, the end portion of the heat pipe on the side of the heat receiving portion is sealed with an insulating substrate, but it may be sealed with a lid made of ceramic such as beryllia or plastic.

Furthermore, in the above embodiment, the heat pipe is made of metal, but ceramic such as beryllia, etc.
Alternatively, it may be formed of heat-resistant plastic or the like. In this case, the end of the heat pipe on the heat receiving part side is integrally sealed, so the structure is similar to that of the lid, and when fixed to the insulating substrate,
There is no need to seal it again.

[Effects of the invention] As explained above, the present invention improves the heat dissipation characteristics of the resistor part, allows a large rated power even with a resistor with a small shape, and allows the operating frequency limit to be set high. In addition, it is possible to realize a fixed attenuator that can handle high power.

[Brief explanation of the drawing]

Fig. 1 is a sectional view showing an embodiment of the fixed attenuator of the present invention, Fig. 2A is a sectional view showing a conventional fixed attenuator, Fig. 2B is a sectional view taken along line AA, and Fig. 3A is a fixed attenuation. FIG. 3B is a plan view showing an example of a flat resistance plate used in the device, and FIG. 3B is a side view thereof. DESCRIPTION OF SYMBOLS 1... Inner shaft, 2... Outer conductor, 3... Planar resistance plate, 4... Center conductor, 5... Matching conductor portion, 6...
...heat pipe, 6a...pipe part, 6b...heat receiving part, 6c...heat radiation part, 7...wick, 8...
Hydraulic fluid, 9...Fin, 10...Insulating substrate, 1
1...Resistor body part.

Claims (1)

[Claims for Utility Model Registration] In a fixed attenuator constructed by surrounding an outer conductor with a planar resistance plate having a resistor part and an electrode part provided on one surface of an insulating substrate, the above-mentioned insulating A space portion where no conductor exists is provided at a position corresponding to the resistor portion of the outer conductor disposed on the other side of the conductive substrate, and a heat pipe is provided in this space portion, and the heat pipe is connected to the heat receiving portion. A fixed attenuator for high power, characterized in that the open end is arranged on the other surface of the insulating substrate without intervening metal.