KR100565225B1 - Plasma Lamp System and Projection Television Using the System - Google Patents

Abstract

The present invention provides a plasma lamp system and a projection television having the plasma lamp system. The magnetron is coupled to one side of the resonator, and the output of the coupled magnetron is formed inside the resonator so as to be inserted into a transfer path through which electromagnetic waves can be transferred. And, the electromagnetic wave guide member for guiding the electromagnetic wave to the bulb side is disposed inside the conveying passage, the plasma is formed by the electromagnetic wave on the outlet side of the conveying passage to install a light emitting light, and the other connected with the electromagnetic wave guide member By installing a shock absorbing member between the parts or by manufacturing the electromagnetic wave guide member in the form of a spring, it is possible to reduce the overall size of the system and to easily assemble other components connected to the electromagnetic wave guide member. Distortion or impulse on the connection Since this buffer may maintain the connection parts stable.

Description

Plasma lamp system and projection television using the system {PLASMA LAMP SYSTEM AND PROJECTION TV HAVING THE SYSTEM}

1 is a perspective view showing a lighting device using a conventional plasma.

2 is a longitudinal cross-sectional view of FIG.

3 is a perspective view partially cut away of the plasma lamp system according to the first embodiment of the present invention;

4 is a longitudinal cross-sectional view of FIG.

5 is a cross-sectional view taken along the line AA ′ of FIG. 4.

FIG. 6 is a cross-sectional view taken along the line BB ′ of FIG. 4. FIG.

Figure 7 is an enlarged perspective view of the buffer member is installed in the present invention.

Figure 8 is a perspective view showing a modification of the state in which the shock absorbing member is installed in the present invention.

Figure 9 is a front view showing another variant of the shock absorbing member is installed in the present invention.

10 is a longitudinal sectional view showing a plasma lamp system according to a second embodiment of the present invention;

Explanation of symbols on the main parts of the drawings

101: magnetron 102: resonator

103: electromagnetic wave guide member 104: light bulb

105: reflector 106: window

107: buffer member 108: ceramic bond

110: resonance space 111: vertical space portion

112: horizontal space part 122: first conductor part

123: second conductor portion 200: electromagnetic wave guide coil

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma lamp system and a projection television having the system. More particularly, the present invention relates to a plasma lamp system and a projection television having the system. And a plasma lamp system capable of maintaining a stable state and a projection television having the system.

Plasma lamp system transmits the electromagnetic energy generated from the electromagnetic wave generator to the resonator through the waveguide, which is applied to the bulb installed inside the resonator, and the encapsulated material encapsulated in the bulb becomes plasma to emit visible light or ultraviolet rays. As a light emitting device that emits light, it has a long life and a superior lighting effect as compared with generally used incandescent and fluorescent lamps.

1 is a perspective view showing the structure of a conventional plasma lamp system, Figure 2 is a longitudinal cross-sectional view of FIG.

As shown in the drawing, in the conventional plasma lamp system, a high voltage generating unit 2 is provided on one side of a case 1 to boost a commercial AC power to a high pressure, and on the other side thereof. A magnetron 3 is provided in which electromagnetic waves are generated by the high voltage supplied from the high voltage generator 2.

In addition, a wave guide 4 for guiding microwaves generated from the magnetron 3 is provided at the inner center of the case 1 between the magnetron 3 and the high voltage generator 2. The upper end is fixed to the opening 1a formed in the upper end portion.

In addition, the shaft shaft 4a is rotatably coupled to the shaft hole 4a formed in the center of the waveguide 4 in the vertical direction, and is thus moved upwardly outward through the opening 1a formed in the case 1. A spherical bulb 6 is formed in the upper end part of which a substance emitting light emitted by electromagnetic energy is enclosed, and the light emitting part 6 can be cooled by rotating the rotating shaft 5 at the lower end part. The electric bulb rotation motor 8 to which the motor shaft 8a is connected by the connecting pipe 7 is coupled.

The upper end of the waveguide 4 located outside the case 1 blocks the leakage of electromagnetic waves flowing through the waveguide 4 and allows the light emitted from the light bulb 6 to pass. (resonator) (9) is coupled to surround the light bulb (6), in the vicinity of the combined resonator (9) to reflect the light generated by the light bulb (6) and passed through the resonator (9) The semi-circular reflection shade 10 which is provided to surround the outer side of the resonator 9 is fixed.

In addition, a fan motor 11, a cooling fan 12, and a discharge port 13a may be disposed below the case 1 to cool the magnetron 3 and the high voltage generator 2. Cooling fan assembly 14 composed of a fan housing 13 is formed.

In addition, the fan housing 13 is formed with a suction port 13b for suctioning external air by the rotation of the cooling fan 12, and the upper surface edge of the case 1 is sucked through the suction port 13b. Several outlets 1b are formed so that the compressed air can be discharged to the outside via the high voltage generator 2 and the magnetron 3.

In the conventional electrodeless lighting device configured as described above, when a power is applied, a high voltage is generated in the high voltage generator 2, and the high voltage generated as described above is supplied to the magnetron 3, and is applied to the magnetron 3. The high voltage generates electromagnetic waves.

The electromagnetic wave generated as described above is radiated into the resonator 9 through the waveguide 4, and discharges a material encapsulated in the light bulb 6 by the emitted electromagnetic wave to generate light by plasma. The light generated as is reflected by the reflector 10 and is illuminated forward.

When the light is generated from the bulb 6 as described above, the bulb rotation motor 8 rotates at a constant speed and rotates the rotation shaft 5 through the connection pipe 7 to fix the bulb fixed to the end of the rotation shaft 5. By rotating (6), the bulb 6 is cooled so as not to be heated above a predetermined temperature.

In addition, the fan motor 11 installed in the inner lower part of the case 1 also rotates to rotate the cooling fan 12, and the external air sucked through the suction port 13b by the rotation of the cooling fan 12 After flowing through the discharge port 13a and cooling the high voltage generator 2 and the magnetron 3, they are discharged to the outside of the case 1 through the discharge port 1b formed on the upper surface of the case 1.

However, in the conventional plasma lamp system as described above, the waveguide 4 is provided so that the waveguide 4 for guiding the electromagnetic waves generated from the magnetron 3 is positioned between the high voltage generator 2 and the magnetron 3. As the overall size of the system is increased by the volume of, it is difficult to miniaturize the size of the system, and accordingly, there is a problem that it is used only for high power lighting.

The main object of the present invention devised in view of the above problems is to provide a projection lamp having a plasma lamp system and a system suitable for miniaturizing the overall size of the lamp system so that it can be used not only for lighting but also for low power light sources of electronic devices. In providing.

Another object of the present invention is to provide a plasma lamp system and a system suitable for assembling each of the components located in the resonance space formed inside the resonator and maintaining the assembled state of the assembled components stably. Is in providing projection television.

In order to achieve the object of the present invention as described above

An electromagnetic wave generator that generates electromagnetic waves when power is input,

A resonator installed in communication with the output of the electromagnetic wave generator, the resonator having a resonance space formed therein to be a conveying passage for electromagnetic waves outputted from the output of the electromagnetic wave generator, and having electromagnetic waves;

An electromagnetic wave guide member disposed in the resonance space and installed at one end of the magnetron to guide an electromagnetic wave of a specific band excited in the resonance space to an exit side of the resonance space;

A light bulb which is installed to be connected to the other end of the electromagnetic wave guide member and emits light as the encapsulation material is plasma discharged by electromagnetic waves guided through the electromagnetic wave guide member;

A plurality of shock absorbing members coupled to an end of the electromagnetic wave guide member to connect the electromagnetic wave guide member and simultaneously absorb external shock;

Provided is a plasma lamp system comprising a.

In addition, an electromagnetic wave generator that generates electromagnetic waves when power is input,

A resonator installed in communication with the output of the electromagnetic wave generator, the resonator having a resonance space formed therein to be a conveying passage for electromagnetic waves outputted from the output of the electromagnetic wave generator, and having electromagnetic waves;

A light bulb which is installed at an exit side of the resonance space and emits light as the encapsulation material is plasma discharged by electromagnetic waves moving to the resonance space;

The electromagnetic wave guide coil is disposed inside the resonance space and one end is connected to the output of the magnetron and the other end is connected to the bulb to guide the electromagnetic wave of a specific band excited in the resonance space to the bulb side.

Provided is a plasma lamp system comprising a.

In addition, an electromagnetic wave generator that generates electromagnetic waves when power is input,

A resonator installed in communication with the output of the electromagnetic wave generator, the resonator having a resonance space formed therein to be a conveying passage for electromagnetic waves outputted from the output of the electromagnetic wave generator, and having electromagnetic waves;

A light bulb which is coupled to one side of the resonator and emits light as the encapsulation material is plasma discharged by electromagnetic waves moving to the resonance space;

An electromagnetic wave guide member disposed in the resonance space of the resonator and connected at one end to an output of the magnetron and connected to the light bulb at another end to guide the electromagnetic wave of a specific band excited in the resonance space to the bulb side;

A plurality of shock absorbing members coupled to an end of the electromagnetic wave guide member to connect the electromagnetic wave guide member and simultaneously absorb external shocks.

Provided is a projection television comprising a plasma lamp system configured to include.

Hereinafter, with reference to the embodiment of the accompanying drawings the plasma lamp system of the present invention configured as described above in more detail as follows.

3 is a perspective view partially cutaway of the plasma lamp system of the present invention, FIG. 4 is a longitudinal cross-sectional view of FIG. 3, FIG. 5 is a cross-sectional view taken along line AA ′ of FIG. 4, and FIG. 6 is a B-B ′ of FIG. 4. Line cross section.

As shown therein, the plasma lamp system of the present invention includes a magnetron 101, a resonator 102, a microwave guide member 103, a bulb 104, and a reflector. (reflector) 105, window (106) is provided.

The magnetron 101 is an electromagnetic wave generator for generating electromagnetic waves. When the power is input, the magnetron 101 converts electrical energy into high frequency energy such as electromagnetic waves, and the converted high frequency energy is output through the antenna 101a which is an output unit.

The resonator 102 is a box body made of metal, and has a resonance space 110 formed therein to which the electromagnetic waves are moved and resonate therein, and the magnetron 101 of the resonance space 110 is formed at the inlet 103a of the resonance space 110. The magnetron 101 is coupled to an upper side of the resonator 102 so that the antenna 101a is inserted.

The resonance space 110 includes a vertical space portion 111 having an opening 110a formed at an upper end thereof so that the antenna 101 of the magnetron 101 can be inserted therein, and a lower end portion of the vertical space portion 111. The horizontal space portion 112 formed so that one end is in communication with each other and the other end is opened to form an outlet 110b is formed to have a substantially "b" shape, and electromagnetic waves generated from the antenna 101a of the magnetron 101 are formed. Is intended to form a passageway through which

The electromagnetic wave guide member 103 is made of a metal rod, is disposed in the resonance space 110, one end is connected to the antenna 101a of the magnetron 101, the other end is coupled to the bulb 104 The electromagnetic wave generated from the antenna 101a of the magnetron 101 is directed to the light bulb 104.

The electromagnetic wave guide member 103 is preferably in the form of a circular rod as a whole, and the resonance space 110 formed outside along the electromagnetic wave guide member 103 is formed in a circular cross section and coaxial with the electromagnetic wave guide member 103. The coaxial structure is advantageous in that the coaxial structure is advantageous for impedance matching and resonant frequency control.

The electromagnetic wave guide member 103 is disposed inside the vertical space portion 111 of the resonance space 110 and has a coupling portion formed with an antenna insertion groove 110a into which an antenna 101a of the magnetron 101 is inserted at an upper end thereof. The first conductor portion 122, on which the 121 is formed, and the second conductor portion 123 connected to the lower end of the first conductor portion 122 and disposed inside the horizontal space portion 112 are approximately It is supposed to form a "┴" character.

The light bulb 104 has a spherical light emitting part 131 having a predetermined internal volume in which an encapsulation material is encapsulated, a support part 132 integrally formed in the light emitting part 131, and the light emitting part 131. It consists of a pair of electrodes 133 disposed to face each other inside.

The light emitting unit 131 is preferably made of a material having high light transmittance and extremely low dielectric loss, such as quartz, and the encapsulating material enclosed in the light emitting unit 131 forms plasma to emit light. Light emitting materials such as metals, halogenated compounds, sulfur or selenium, which lead the light, inert gases such as argon gas and krypton gas to form plasma inside the light emitting unit 131 at the initial stage of light emission, and initial discharge such as mercury. It is composed of a discharge catalyst material for facilitating lighting or controlling the spectrum of light generated.

The support part 132 is formed to extend in the same material as the light emitting part 131 so as to be positioned on the same axis as the first conductor part 123 of the electromagnetic wave guide member 103. One electrode 133 of the electrode 133 is installed to protrude outward from a predetermined portion, and the end of the electrode 133 protruding as described above is the second conductor portion 123 of the electromagnetic wave guide member 103. It is coupled to be inserted into the electrode coupling groove (123a) formed to be recessed at the end.

Between the electromagnetic wave guide member 103 and the light bulb 104 is easily assembled when connecting the light bulb 104 to the electromagnetic wave guide member 103, and after assembling the electromagnetic wave guide member 103 and the light bulb 103 Coil spring-type shock absorbing member 107 is coupled to prevent distortion or breakage and electrical short-circuit caused by external force.

FIG. 7 is an enlarged perspective view illustrating a state in which the shock absorbing member 107 is installed between the electromagnetic wave guide member 103 and the light bulb 104, and as shown therein, an end portion of the support part 132 of the light bulb 104. One end of the shock absorbing member 107 is joined to the electrode 133 protruding from the second end, and the other end is connected to the coupling step portion 123a formed so that the diameter of the second conductor part 123 of the electromagnetic wave guide member 103 is reduced in diameter. It is inserted and coupled.

The shock absorbing member 107 installed as described above is not necessarily installed between the electromagnetic wave guide member 103 and the light bulb 104, and the electromagnetic wave guide member 103 and the magnetron 101 as in the modification of FIG. 8. ) May be installed between the one end of the electromagnetic wave guide member 103 and the magnetron 101, as shown in another modified example of FIG. 9, and the electromagnetic wave guide member 103 and the bulb ( Another one may be provided between 104).

As shown in FIG. 8, when the shock absorbing member 107 is installed between the electromagnetic wave guide member 103 and the magnetron 101, the second conductor part 123 of the electromagnetic wave guide member 103 and the light bulb 104 are supported. The connection portions 132 may be bonded to the ceramic bonds 108 so that the connection portions of the electrodes 133 may not be distorted by external forces.

The reflector 105 has an ellipse or similar shape having a predetermined curvature, and is installed between the second conductor portion 123 and the bulb 104 so as to surround one side of the bulb 104. The generated light is reflected to the front of the bulb 104.

The window 109 is provided in the opening of the reflector 105 to form a lattice-shaped tube so that light generated from the light bulb 104 passes and electromagnetic waves are cut off to block leakage.

On the other hand, the window 109 may be made of a transparent plate, such that when the transparent plate is made of light is passed through the harmful substances enclosed in the interior of the bulb 104 when the bulb 104 is broken leaks to the outside. It is very advantageous in that it can block, and in addition, any structure or material of any type can be applied as long as the structure of the window 109 can pass light and block electromagnetic waves such as a mesh.

The plasma lamp system according to the present invention configured as described above generates electromagnetic waves having high frequency energy from the magnetron 101 when power is supplied to the magnetron 101, and the electromagnetic waves generated as described above are transmitted through the antenna 101a. The output is guided into the resonance space 110 by the first conductor portion 122 and the second conductor portion 123 of the electromagnetic wave guide member 103 installed inside the resonance space 110 of the resonator 102. In addition, the appropriate resonant frequency is selected.

Electromagnetic waves of the resonant frequency band as described above generate a strong electric field between the electrodes 133 installed in the light emitting portion 141 of the light bulb 104 while resonating inside the resonant space of the resonator 102, The inert gas enclosed inside the light emitting unit 141 is discharged, and the heat generated during the discharge vaporizes the light emitting material to form a plasma, and the plasma continuously maintains the discharge by electromagnetic waves. Luminance light is emitted. This light is reflected toward the front side by the reflector 105 to be used as a necessary light source.

Plasma lamp system of the present invention operated as described above is coupled so that the output portion of the magnetron 101 is located in the resonator space 110 formed inside the resonator 102, the coupling of the resonant space 110 to be connected to the output portion The electromagnetic wave guide member 103 is installed inside, and electromagnetic waves generated from the magnetron 101 are guided to the bulb 104 along the electromagnetic wave guide member 103 to emit light, thereby making the plasma lamp system very small. It can produce and can use it as a light source of home appliances, such as a projection TV, for example.

In addition, the electromagnetic waves generated in the magnetron 101 are smoothly transmitted through the interior of the resonant space 110 having a coaxial structure, and the electromagnetic waves thus transmitted are guided to the inner diameter of the resonant space 110 and the electromagnetic wave guide. By appropriately adjusting the diameter ratio of the diameter of the member 103, the electromagnetic wave power transmission transmitted to the bulb 104 side is maintained in an optimum state.

In addition, the electromagnetic wave guide member disposed inside the resonance space 110 of the resonator 102 by connecting the light bulb 104 and the magnetron 101 connected to the electromagnetic wave guide member 103 using the buffer member 107. It is easy to couple the magnetron 101 or the light bulb 104 to the 103, and after the magnetron 101 or the light bulb 104 is coupled to the connection portion of the electromagnetic wave guide member 103 and the corresponding component through the magnetron 101 or the light bulb 104. Even if an external force is applied, the shock absorbing member 107 is cushioned at the connection part, so that the connection part is not broken.

In particular, in the small plasma lamp system used for the light source of the projection TV, since the total volume of the system is made small, the resonance space 110 formed inside the resonator 102 becomes relatively small. Since the components are assembled to the electromagnetic wave guide member 103 inside the resonant space 110 of the coil spring, the coil spring-type buffer member 107 as described above is very suitable for shock absorption against the external force after assembling and assembling each component. It has an advantageous effect. The buffer member 107 can be applied in the form of a leaf spring.

10 is a longitudinal sectional view showing a plasma lamp system according to a second embodiment of the present invention. Since the plasma lamp system of the second embodiment has substantially the same configuration as the plasma lamp system of the first embodiment, the same reference numerals are given to the common members, and detailed description thereof will be omitted.

As shown, the plasma lamp system according to the second embodiment of the present invention is a member for guiding electromagnetic waves inside the resonance space 110, unlike the first embodiment, the entire electromagnetic wave guide coil 200 in the form of a coil ) Is installed.

The electromagnetic wave guide member 200 induces electromagnetic waves toward an exit side so that a plasma can be generated by inducing electromagnetic waves of a specific band excited inside the resonance space like the electromagnetic wave guide coil 103 in the first embodiment. .

In addition, one end of the coil-shaped electromagnetic wave guide coil 200 of the elastic body as described above is connected to the antenna 101a of the magnetron 101, the other end is assembled to the support 132 of the bulb 104, The antenna 101a of the magnetron 101 and the support 132 of the bulb 104 are easily assembled in the form of being inserted into both openings of the electromagnetic wave guide coil 200. In addition, after the magnetron 101 and the light bulb 104 are assembled to the electromagnetic wave guide coil 200, even if an external force is applied to the electromagnetic wave guide coil 200, the electromagnetic wave guide coil 200 is fully cushioned, so as to separate coil springs as in the first embodiment. It is possible to maintain a stable state without damaging the connecting portion without installing 107.

As described in detail above, the plasma lamp system of the present invention and the projection television having the system are provided so that the transfer passage of electromagnetic waves for guiding the electromagnetic waves generated in the magnetron of the plasma lamp system is provided inside the resonator, so that the whole of the plasma lamp system can be provided. It is possible to miniaturize the size and accordingly there is an effect that can be easily used as a small light source installed inside the electronic device such as a projection TV.

In addition, the electromagnetic wave generated in the magnetron is to be conveyed through the coaxial feed passage has the effect that it is easy to adjust the impedance matching and resonant frequency that has the greatest effect on the efficiency of the device.

In addition, there is an effect that the power transmission of the electromagnetic wave can be maintained in an optimal state by having a constant diameter ratio of the conveying passage of the coaxial structure to which electromagnetic waves are conveyed.

      In addition, the coil spring, which is a cushioning member, is installed between the components installed in the resonant space, or manufactured in a spring form to easily assemble each of the components. After assembly, each component is installed in the resonant space. Even if an external force is applied to the connection part of these, the buffer is made in the cushioning member, so that there is an effect of maintaining a stable state in which the connection part is not broken and short-circuited.

Claims (17)

An electromagnetic wave generator that generates electromagnetic waves when power is input, A resonator installed in communication with the output of the electromagnetic wave generator, the resonator having a resonance space formed therein to be a conveying passage for electromagnetic waves outputted from the output of the electromagnetic wave generator, and having electromagnetic waves; A light bulb which is coupled to one side of the resonator and emits light as the encapsulation material is plasma discharged by electromagnetic waves moving to the resonance space; An electromagnetic wave guide member disposed inside the resonance space of the resonator and connected at one end to the output of the magnetron and connected to the bulb at the other end to induce electromagnetic waves of a specific band excited in the resonance space to the bulb side; And a plurality of buffer members coupled to an end of the electromagnetic wave guide member to connect the electromagnetic wave guide member to absorb external shocks. The method of claim 1, The buffer member is installed so as to be connected between the electromagnetic wave guide member and the bulb plasma lamp system. The method of claim 1, The buffer member is a spring, the electrode of the bulb is joined to one end of the spring, the other end of the plasma lamp system, characterized in that the end of the electromagnetic wave guide member is inserted and fixed. The method of claim 1, The buffer member is installed to be connected between the electromagnetic wave guide member and the antenna of the magnetron plasma lamp system. The method of claim 1, The buffer member is a plasma lamp system, characterized in that installed in each of the connection portion of the electromagnetic wave guide member and the bulb, and the portion of the electromagnetic wave guide member and the magnetron connected. The method of claim 1, The resonance space of the resonator is formed in a circular cross section, the electromagnetic wave guide member is disposed to pass through the center of the resonant space plasma lamp system, characterized in that the coaxial structure. The method according to claim 1 or 6,  The resonance space is a plasma lamp system, characterized in that consisting of a vertical space portion formed vertically inside the resonator, and a horizontal space portion formed in the horizontal direction in communication with the vertical space portion. The method according to claim 1 or 6, The electromagnetic wave guide member includes a first conductor portion disposed in a vertical direction of the resonance space, and a second conductor portion connected to a lower end of the first conductor portion and disposed in a horizontal direction. The method of claim 1, Plasma lamp system further comprises a reflector installed around the bulb for reflecting light generated from the bulb in a specific direction. The method of claim 9, And a window coupled to the opening of the reflector and configured to pass light generated from the bulb and block electromagnetic waves. The method of claim 10, Wherein the window is a plasma lamp system, characterized in that the lattice-shaped tube through which the light generated from the bulb passes and the electromagnetic wave is blocked. The method of claim 10, The window is a plasma lamp system, characterized in that the transparent plate so that the light generated from the light bulb passes, electromagnetic waves are blocked and the leakage of harmful substances in the breakage of the bulb. The method of claim 10, The window is a plasma lamp system, characterized in that the mesh form. An electromagnetic wave generator that generates electromagnetic waves when power is input, A resonator installed in communication with the output of the electromagnetic wave generator, the resonator having a resonance space formed therein to be a conveying passage for electromagnetic waves outputted from the output of the electromagnetic wave generator, and having electromagnetic waves; A light bulb which is installed at an exit side of the resonance space and emits light while the encapsulating material is plasma discharged by electromagnetic waves moved to the resonance space; It is disposed inside the resonance space and one end is connected to the output of the magnetron and the other end is connected to the bulb to absorb external shocks and at the same time to guide the electromagnetic wave of a specific band excited in the resonance space to the bulb side Plasma lamp system comprising a guide coil. The method of claim 14, Plasma lamp system, characterized in that further provided with a reflector for reflecting the light generated in the bulb in a specific direction installed around the bulb, The method of claim 15, Plasma lamp system further comprises a window coupled to the opening of the reflector to pass the light generated from the bulb and block the electromagnetic waves, An electromagnetic wave generator that generates electromagnetic waves when power is input, A resonator installed in communication with the output of the electromagnetic wave generator, the resonator having a resonance space formed therein to be a conveying passage for electromagnetic waves outputted from the output of the electromagnetic wave generator, and having electromagnetic waves; A light bulb which is coupled to one side of the resonator and emits light as the encapsulation material is plasma discharged by electromagnetic waves moving to the resonance space; An electromagnetic wave guide member disposed inside the resonance space of the resonator and connected at one end to the output of the magnetron and connected to the bulb at the other end to induce electromagnetic waves of a specific band excited in the resonance space to the bulb side; And a plurality of buffer members coupled to an end of the electromagnetic wave guide member to connect the electromagnetic wave guide member to absorb external shocks at the same time.

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