TWI740152B - High frequency oscillation transmission and derivative device - Google Patents

Abstract

The present invention provides a high-frequency oscillation transmission and derivative device, which integrates at least one set of high-frequency oscillation transmitters into a box. The high-frequency oscillation transmitter has several metal meshes and several binding posts. Several binding posts are combined with several pieces of metal mesh. The metal mesh and the metal mesh are not in contact with each other. An electronic control device feeds power into one of the binding columns. The current flows through the binding column to the metal mesh, and then the other Combining the column to guide the current to the electronic control device, in the box body as a parallel or series more than one set of high-frequency oscillation transmitters, or with a box with high-frequency oscillation transmitters, in parallel or series multiple boxes , In order to produce extremely high frequency transmission and derivation.

Description

High frequency oscillation transmission and derivative device

The present invention relates to a high-frequency oscillation transmission and derivative device. In more detail, it especially refers to a transmitter with more than one set of high-frequency oscillation in parallel or series in a box, or a transmitter with high-frequency oscillation The number of boxes is connected in parallel or in series with extremely high frequency transmission to repel birds and insects in a wide range, and the frequency can be adjusted by the electronic control device, which is suitable for repelling different species of birds and insects. Used in water, it can be used as a high-frequency oscillation transmission and derivation device for a wide range of uses such as water refinement, water molecular hydrogenation, water mist Fendo essence anionization, water mist separation and hydrogenation.

According to the prior knowledge, the electronic mosquito repellents currently on the market are electronic mosquito repellents made using the principle of bionic electronics. Usually there are ultrasonic electronic mosquito repellents that imitate the ultrasonic signals emitted by male mosquitoes to drive away female mosquitoes. Or a bat-type electronic mosquito repellent that imitates the radio signal sent by a bat to drive away mosquitoes. The electronic mosquito repellent is a powerful mosquito repellent for home travel, fishing, camping, barbecue, mountain climbing, agricultural work, and home life. The electronic mosquito repellent is safe and non-toxic. Radiation is harmless to humans and animals, has no chemical residues, and guarantees environmental safety; the sound frequency of the electronic mosquito repellent imitates the sound of various male mosquitoes when they fly and chase female mosquitoes. Once the female mosquitoes mate After that, if you hear the high-frequency sound waves from the mosquito repellent again, you will think it is a male mosquito courtship, and use the characteristic of leaving the male mosquito naturally to create a sounding area for the mosquito repellent. The sound of the mosquito repellent is higher than that of humans. The range that the ear can sense will not interfere with ordinary people; the main circuit of the mosquito repellent is nothing but the use of NPN (NPN type is low potential output) and PNP (PNP type is high potential output) transistors to form a complementary oscillator In order to generate extremely high frequencies above 200 kilohertz (KHZ), mosquitoes cannot tolerate it to achieve the function of repelling mosquitoes. This is the current electronic mosquito repellent device and its function.

However, the frequency of the high-frequency sound waves emitted by electronic mosquito repellents is a certain value and cannot be applied to mosquitoes in every area. Therefore, electronic mosquito repellents often have ineffective responses. Furthermore, the range of high-frequency sound emitted by electronic mosquito repellents is limited. There is only a 3 meter area, beyond which mosquitoes cannot feel it, so most people who use it think that electronic mosquito repellents are ineffective.

In addition, at present, there are often birds flying over airports. Aircraft are most afraid of bird interference. Bird strikes often occur when aircraft take off or land. If birds are inhaled into aircraft engines, serious flight safety events will occur (the strong airflow from jet aircraft intakes will often fly. Birds that have been inhaled into the engine cause bird strikes). According to statistics, more than 90% of bird strikes occur in the airspace near airports and airports, 50% occur in airspace below 30 meters, and only 1% occur in airspace above 760 meters. There are many reasons for bird strikes at high altitude. Airports are generally far away from the city center, and there are few human constructions and activities around them. There are often places for birds to inhabit and breed. Secondly, there are large areas of lawns in the airport, causing the airport. Insects, rodents, and valuables in the area grow vigorously, with high biomass, and provide sufficient food for birds in different ecological niches. Therefore, open and open airports often become gathering places for migratory birds before migrating or landing points during migration. The combination of factors caused bird strikes to occur in the near-ground airspace near the airport.

Most of the general airport repelling methods for birds are driven by shooting, but they are only short-lived. After the repelling is completed, a group of birds gather for a period of time. It is difficult to prevent and the airport personnel are time-consuming and labor-intensive. For drones, the flight direction and altitude of the drones are operated by personnel, and then they are chased for expulsion, or the development of drones can automatically detect the flight direction of birds, and then chase for expelling. However, drones are often malfunctioning or unmanned. If the aircraft is hit by a bird and its cost is high, the drone needs to coordinate with the flight time of the aircraft, otherwise there will be a problem of delaying the flight of the aircraft, which is not a completely ideal method.

Therefore, how to distinguish the electronic mosquito repellent and change it into a high-frequency oscillating device, which can use the high-frequency oscillating device to repel birds and insects in a large area, and maintain the safety of the airport. The negative ionization of water mist and Fendol, and the separation of hydroxide by water mist are major efforts of the industry.

In view of this, the inventor of this case is based on the above-mentioned drawbacks, actively working hard to develop, research and improve, and continue to experiment and assemble, accumulate experience, and finally an invention that can solve the above-mentioned drawbacks is produced.

The reason is that a high-frequency oscillation transmission and derivative device includes: a box body with at least one storage space; at least one set of high-frequency oscillation transmitters integrated in the box body with several metal meshes Pieces and several binding posts, several binding posts combine several pieces of metal mesh, and the metal mesh does not touch the metal mesh; at least one protective frame is sheathed around the high-frequency oscillating transmitter; an electronic The control device feeds power into one of the binding columns, the current flows through the binding column to the metal mesh, and then the other binding columns lead the current out, and then the current flows to the electronic control device, which is connected in parallel or in series in the box. Groups of high-frequency oscillating transmitters above, or boxes with high-frequency oscillating transmitters can be connected in parallel or in series with multiple boxes to generate extremely high-frequency transmission and derivation.

The present invention is a transmission and derivative device for high-frequency oscillations. Its main purpose is to provide high-frequency oscillations that can be connected in series and parallel for infinite extension, repelling birds and insects in a wide range, and the electronic control device can adjust its frequency, which is suitable for Repel different species of birds and insects.

Another purpose of the present invention is to provide a device for transmitting and deriving high-frequency oscillations. Another purpose of the invention is to provide a device that can be used in water, which can be used for water refining, water molecular hydrogenation, water mist and phenodine anionization, and water mist separation and hydrogenation. And so on a wide range of uses.

〔this invention〕

10: Box body

20: Transmitter of high frequency oscillation

30: electric bridge

40: Electronic control device

11: Placement space

21: right oscillator

22: Left Oscillator

210: Right front shock group

2100: right rear shock group

220: Left front shock group

2200: Left rear shock group

23: Metal mesh

240: binding column

24: The first binding column

25: The second binding column

26: The third binding column

27: Insulating spacer

241: Nut

242: Clip

243: Elastic gasket

244: inner gasket

251: Long Stud

252: Short Top Stud

253: Nut

254: inner gasket

261: solenoid

262: Nut

263: inner gasket

270: Medium insulation partition

2701: raised surface

2702: Blocking Groove

2703: Piercing

28: Protective frame

50: Box body

60: Transmitter of high frequency oscillation

70: electric bridge

80: Electronic control device

51: Placement space

61: Right Oscillator

62: Left Oscillator

610: right front shock group

6100: right rear shock group

620: Left front shock group

6200: left rear shock group

63: Metal mesh

640: Combination column

64: The first binding column

65: second binding column

66: The third binding column

67: Insulating spacer

631: Cooling Space

641: Nut

642: Clip

643: Elastic gasket

651: front long stud

652: Rear Short Stud

653: Clip

654: Elastic gasket

661: solenoid

662: Nut

671: Convex Ring

672: perforation

673: Convex Column

90: box body

100: Transmitter of high frequency oscillation

110: electric bridge

120: Electronic control device

91: Placement Space

1010: right oscillator

1020: Left Oscillator

101: Metal mesh

10200: binding column

102: The first binding column

103: The second binding column

104: The third binding column

105: insulating spacer

1021: long stud

1022: short top stud

1023: Nut

1024: Gasket

1031: Nut

1032: Clip

1033: Elastic gasket

1034: inner gasket

1041: solenoid

1042: Nut

1043: Gasket

106: Protective frame

130: metal mesh

131: Hole

140: Insulating spacer

141: Hole

150: metal mesh

151: Combination column

152: Metal mesh

153: Combining column

154: Protective frame

1541: Embedded Groove

1542: recessed hole

1521: Tab

155: Metal mesh

158: Insulating spacer

156: Combining column

157: protection frame

1571: Embedded Groove

1572: recessed hole

1551: Tab

159: Metal mesh

1591: Tab

160: Combination column

161: Metal mesh

1611: Tab

162: Combination column

163: Protective frame

1631: embedded groove

1632: recessed hole

The first figure is a three-dimensional assembly diagram of the first embodiment of the present invention.

The second figure is a three-dimensional exploded schematic diagram of the box body and the high-frequency oscillation transmitter of the first embodiment of the present invention.

The third figure is a three-dimensional exploded schematic diagram of the right front shock group and the left front shock group in the first embodiment of the present invention.

The fourth figure is a three-dimensional exploded schematic diagram of the right rear shock group and the left rear shock group of the first embodiment of the present invention.

The fifth figure is a schematic cross-sectional view of the second figure 5-5.

The sixth figure is a three-dimensional assembly diagram of the second embodiment of the present invention.

The seventh figure is a schematic cross-sectional view of the second embodiment of the present invention.

The eighth figure is a three-dimensional assembly diagram of the third embodiment of the present invention.

Figure 9 is a schematic cross-sectional view of the third embodiment of the present invention.

The tenth figure is a perspective view of the third embodiment of the present invention where part of the electric bridge is formed at an angle.

The eleventh figure is a three-dimensional schematic diagram of the metal mesh and insulating spacers of the fourth embodiment of the present invention.

Figure 12 is a three-dimensional schematic diagram of the metal mesh and the coupling column of the fifth embodiment of the present invention.

Figure 13 is a schematic cross-sectional view of the metal mesh and the coupling column of the fifth embodiment of the present invention.

The fourteenth figure is a three-dimensional schematic diagram of the metal mesh and the coupling column according to the sixth embodiment of the present invention.

The fifteenth figure is a schematic cross-sectional view of the metal mesh and the binding column according to the sixth embodiment of the present invention.

The sixteenth figure is a three-dimensional schematic diagram of the metal mesh and the coupling column according to the seventh embodiment of the present invention.

Figure 17 is a schematic cross-sectional view of the metal mesh and the coupling column in the seventh embodiment of the present invention.

The eighteenth figure is a three-dimensional schematic diagram of the metal mesh and the coupling column of the eighth embodiment of the present invention.

The nineteenth figure is a schematic cross-sectional view of the metal mesh and the coupling column of the eighth embodiment of the present invention.

Figure twentieth is a three-dimensional schematic diagram of the metal mesh and the combining column of the ninth embodiment of the present invention.

FIG. 21 is a schematic cross-sectional view of the metal mesh and the bonding column according to the ninth embodiment of the present invention.

The present invention is a device for transmitting and deriving high-frequency oscillations. The first embodiment is shown in the first, second, third, fourth, and fifth figures. It is a thin-type high-frequency oscillation transmission and derivation device, which includes a box body 10 and an array of high The transmitter 20 for high frequency oscillation, several electric bridges 30 and an electronic control device 40, there is a storage space 11 in the box body 10, the transmitter 20 for high frequency oscillation is integrated in the box body 10, the transmitter for high frequency oscillation 20 is a combination of a right oscillator 21 and a symmetrical left oscillator 22. The right oscillator 21 is a combination of a right front oscillator 210 and a right rear oscillator 2100. The left oscillator 22 is a left front oscillator 220 and a left oscillator. The left rear shock group 2200 is assembled, the right front shock group 210 and the right rear shock group 2100, as well as the left front shock group 220 and the left rear shock group 2200, all have a number of metal mesh 23, a coupling column 240 and a number of insulating spacers 27. The bonding pillar 240 includes a first bonding pillar 24, a second bonding pillar 25, and a third bonding pillar 26. The arrangement of the metal mesh 23 and the insulating spacer 27 is that a metal mesh 23 and an insulating spacer 27 are attached to each other at intervals. The insulating spacer 27 is an insulating mesh. The insulating spacer 27 is inserted between the metal mesh 23 and the metal mesh 23 so that the metal mesh 23 and the metal mesh 23 are not in contact with each other. The first bonding column 24 is The double-headed stud is combined with the number nut 241, the clip 242, the elastic gasket 243 and the inner gasket 244. The inner gasket 244 is located between the metal mesh 23 and the insulating spacer 27. The elastic gasket 243 is a curved gasket with Compressively elastic, the first coupling column 24 and its accessories penetrate the upper end of the right front shock assembly 210 for coupling and positioning. The second coupling column 25 is a combination of a long stud 251 and a short top stud 252, and a coupling nut 253 And the inner gasket 254, the inner gasket 254 is located between the metal mesh 23 and the insulating spacer 27, the second combining column 25 and its accessories penetrate into the lower end of the right front oscillation group 210 and the right rear oscillation group 2100 for bonding and positioning, The third combining column 26 combines a solenoid 261, a nut 262 and an inner gasket 263. The inner gasket 263 is located between the metal mesh 23 and the insulating spacer 27. The third combining column 26 is used for combining and passing through the right rear shock assembly. At the upper end of 2100, there is a middle insulating partition 270 between the right front oscillating group 210 and the right rear oscillating group 2100, and between the left front oscillating group 220 and the left rear oscillating group 2200, there is a middle insulating partition 270, and the middle insulating partition has a raised surface 2701. A blocking groove 2702 and a perforation 2703. The raised surface 2701 has compressive elasticity. The blocking groove 2702 allows the first coupling column 24 to enter the top and blocks the third coupling column 26. The perforation 2703 allows the second coupling column 25 to pass through and oscillates right front. Group 210 The right rear shock group 2100, the left front shock group 220 and the left rear shock group 2200 each have a protective frame 28 covering the periphery. The bridge 30 is connected to the third combining column 26 of the right rear shock group 2100 of the right shock 21 and the right rear shock group 2100. The third binding column 26 of the left rear oscillation group 2200 of the left oscillator 22, the left front oscillation group 220 and the left rear oscillation group 2200 of the left oscillator 22, are related to the right front oscillation group 210 and the right rear oscillation group of the right oscillator 21 The 2100 is relatively symmetrical and has the same structure, which will not be repeated here. The electronic control device 40 can be activated by an alternating current (AC) or direct current (DC) system.

With the above-mentioned structural combination, a device for transmitting and deriving high-frequency oscillations of the present invention. In the first embodiment, power is supplied to the first coupling column 24 through the metal mesh 23 of the right front oscillation group 210, and the metal mesh 23 is The power flows through the second connecting column 25, and then to the metal mesh 23 to the third connecting column 26 of the right rear oscillating group 2100. The third connecting column 26 passes through the bridge 30 to the left oscillator 22, that is, the current flows through the right front oscillating group 210 to The right rear shock group 2100, then the right rear shock group 2100 flows to the left rear shock group 2200, the current from the left rear shock group 2200 to the left front shock group 220, and the current flows to the electronic control device 40 to generate extremely high frequencies. The metal mesh 23 is attached to the insulating spacer 27 at intervals. The mesh of the metal mesh 23 and the mesh of the insulating spacer 27 are opposite, so the mesh is used as convective air, although the metal mesh 23 is separated from the insulating spacer. The sheet 27 is in contact with each other, and heat dissipation can still be achieved by mesh convection; the above-mentioned attachment posts 240, nuts 241, 253, 262 and other accessories are made of good conductor materials such as superconductors or graphene. This case can extend the high frequency indefinitely. As long as the oscillator 20 is connected to another high-frequency oscillator 20 by a bridge 30, several high-frequency oscillators 20 can be extended in series or in parallel. In this embodiment, several high-frequency oscillators 20 are connected in series. Extension, if the bridge 30 is removed, each high-frequency oscillation transmitter 20 is not connected to each other, and the current output end of each high-frequency oscillation transmitter 20 is connected to the electronic control device 40 by a wire, then Connect each high-frequency oscillation transmitter 20 in parallel; the principle of supramolecular oscillation cutting is briefly described as follows: through two or more different atomic or molecular targets, environment, geography, temperature, height, space, and scope needs to be deployed Atom (hydrogen atom, oxygen atom, sodium, nitrogen, wave, ..., etc.) or molecule (water, molecular water, sodium ion water, fog molecule, ..., etc.) Etc.) More or less or size, atoms or molecules are separately processed by the electronic control device 40, and then the large and small atoms and molecules are merged into the closed case 10, and the pulse signal and the ultra-high frequency general wave electric energy wave are controlled by the machine surface IC. The energization (AC or DC) is based on the required target and the energization (AC or DC) current is delivered through the combination of the devices in the box 10 of the present case, so as to achieve the goal and effect of high-frequency oscillation of supramolecular cutting.

The second embodiment, as shown in Figures 6 and 7, includes a box body 50, an array of high-frequency oscillatory transmitters 60, an electric bridge 70 and an electronic control device 80. There is a storage space 51 in the box body 50. The high-frequency oscillation transmitter 60 is integrated into the box. The high-frequency oscillation transmitter 60 is a combination of a right oscillator 61 and a symmetrical left oscillator 62. The right oscillator 61 is a right front oscillator group 610 and a right oscillator. The rear shock group 6100 is assembled, the left shock 62 is a left front shock group 620 and a left rear shock group 6200 assembled, the right front shock group 610 and the right rear shock group 6100, and the left front shock group 620 and left rear shock group 6200. Each has several pieces of metal mesh 63, a coupling post 640, and several insulating spacers 67. The coupling post 640 includes a first coupling post 64, a second coupling post 65, a third coupling post 66, a metal mesh 63 and an insulating spacer 67 The arrangement is that two metal mesh sheets 63 and an insulating spacer 67 are arranged in a non-adjacent arrangement, resulting in a heat dissipation space 631. The first coupling column 64 is a short stud, which combines the nut 641, the clip 642 and the elastic gasket 643 The elastic gasket 643 is a curved gasket with compression elasticity. The second coupling column 65 is a front long stud 651 and a rear short stud 652. The clip 653 and the elastic gasket 654 are combined. The tube 661 and the nut 662, the insulating spacer mesh 67 has two convex rings 671 at one end, and a perforation 672 and two convex posts 673 at the other end. The two convex rings 671 isolate the two metal mesh plates 63, and the two convex posts 673 are located in the two insulating spaces. Between the sheets 67, the right front shock group 610 and the right rear shock group 6100, as well as the left front shock group 620 and the left rear shock group 6200, can each have a protective frame (not shown) covering the surroundings, and the electric bridge connects 70 to the right shock The right rear oscillating group 6100 of the second connecting column 65 after the short stud 652 and the left rear oscillating group 6200 of the left rear oscillating group 6200 of the second connecting column 65 after the short stud 652 and the left oscillator 62 are related to the left oscillation The left front oscillating group 620 and the left rear oscillating group 6200 of the device 62 are the same as the right front oscillating group 610 and the right rear oscillating group 6100 of the right oscillator 61. It is symmetrical and has the same structure, which will not be repeated here. The electronic control device 80 can be activated by an alternating current (AC) or direct current (DC) system.

In the second embodiment, the power is supplied to the first combining column 64 through the metal mesh 63 of the right front oscillating group 610, and the power of the metal mesh 63 flows through the second combining column 65, and then to the metal mesh of the right rear oscillating group 6100 63 to the third connecting column 66, the third connecting column 66 passes through the metal mesh 63 of the right rear oscillation group 6100 to the short stud 652 behind the second connecting column 65 and the bridge 70 to the left oscillator 62, so that the current oscillates through the right front From group 610 to right rear shock group 6100, then from right rear shock group 6100 to left rear shock group 6200, the current from left rear shock group 6200 to left front shock group 620, and the current flows to the electronic control device 80 to generate extremely high There is a heat dissipation space 631 between the metal mesh 63 and the metal mesh 63, and there is also a heat dissipation space 631 between the metal mesh 63 and the insulating spacer 67. Therefore, the heat dissipation space is used as convective air, so that the heat dissipation space 631 can convectively dissipate heat. ; In this case, the high-frequency oscillatory transmitter 60 can be extended indefinitely. As long as the bridge 70 is used to connect another high-frequency oscillatory transmitter 60, the high-frequency oscillatory transmitter 60 can be extended in series or in parallel.

The third embodiment, as shown in Figures 8 and 9, is the transmission and derivation of ultra-thin high-frequency oscillations. It includes a box 90, an array of high-frequency oscillation transmitters 100, a bridge 110, and an electronic control device. 120. There is a storage space 91 in the box body 90. The high-frequency oscillation transmitter 100 is integrated in the box body 90. The high-frequency oscillation transmitter 100 is a combination of a right oscillator 1010 and a symmetrical left oscillator 1020. , The right oscillator 1010 and the left oscillator 1020 each have several pieces of metal mesh 101, a coupling post 10200 and a number of insulating spacers 105. The coupling post 10200 includes a first coupling post 102, a second coupling post 103, and a third coupling post 104. Insert the insulating spacer 105 between the metal mesh 101 and the metal mesh 101 so that the metal mesh 101 and the metal mesh 101 are not in contact with each other. The arrangement of the metal mesh 101 and the insulating spacer 105 is a metal mesh The sheet 101 is attached to an insulating spacer 105 at intervals. The insulating spacer 105 is an insulating mesh. The mesh of the metal mesh 101 and the mesh of the insulating spacer 105 are opposite, and the first bonding column 102 is a long The stud 1021 is combined with a short top stud 1022, combined with the nut 1023 and the inner gasket 1024, the inner The gasket 1024 is located between the metal mesh 101 and the insulating spacer 105. The second coupling column 103 is a double-ended stud, a coupling nut 1031, a clip 1032, an elastic gasket 1033, and an inner gasket 1034. The inner gasket 1034 is located between the metal mesh 101 and the insulating spacer 105. The elastic gasket 1033 is a curved gasket with compression elasticity. The third coupling column 104 is combined with a solenoid 1041, a nut 1042 and a gasket 1043. The first coupling column 102 serves as Combine and pass through the upper end of the right oscillator 1010, the second combining column 103 is used for joining and passes through the lower front end of the right oscillator 1010, the third combining column 104 is used for joining and passes through the lower rear end of the right oscillator 1010, and the bridge 110 is connected to the right The first coupling post 102 of the oscillator 1010 and the first coupling post 102 of the left oscillator 1020, the right oscillator 1010 and the left oscillator 1020 each have a protective frame 106 covering the periphery, and the electronic control device 120 can be powered by alternating current (AC) Or the direct current (DC) system starts.

In the third embodiment, the electronic control device 120 feeds power to the second coupling post 103 of the right oscillator 1010 and its metal mesh 101, and the power of the metal mesh 101 flows through the first coupling post 102, and then from the electric bridge 110 to The metal mesh 101 of the left oscillator 1020 allows current to pass through the right oscillator 1010 through the bridge 110 to the left oscillator 1020, and the current flows to the electronic control device 120 to generate extremely high frequencies. The metal mesh 101 is separated from the insulation The sheets 105 are attached at intervals, in which the mesh of the metal mesh 101 and the mesh of the insulating spacer 105 are opposite, so the mesh is used as convective air, although the metal mesh 101 is in contact with the insulating spacer 105, The heat is dissipated by mesh convection; in this case, the high-frequency oscillating transmitter 100 can be extended indefinitely. As long as a bridge 110 is connected to another right oscillating device 1010, the high-frequency oscillating transmitter 100 can be extended in series or in parallel.

As shown in the tenth figure, one of the left oscillators 1020 is connected to the other right oscillators 1010 at an angle with a bridge 110, so that the transmitter 100 of high frequency oscillations can be extended indefinitely to meet the requirements of the terrain environment.

In the fourth embodiment, as shown in Figure 11, the outer end of the metal mesh sheet 130 may be provided with a hole 131 or the outer end of the insulating spacer 140 may be provided with a hole 141 for the coupling posts of the foregoing embodiments to pass through. Within the scope of the implementation of this case; the shape of the metal mesh and the insulating spacer is not only It is a square piece, and any simple shape change such as a regular shape piece (square piece, rectangular piece, round piece, oval piece, triangle piece, trapezoidal piece, etc.) or irregular shape piece, will be implemented in this case Within range.

高頻震盪之傳遞及衍生，

，而且可以串聯及並聯作無限延伸，大範圍地驅鳥、驅蟲，並且電子控制裝置可以調整其頻率，適合驅離不同種的鳥類及昆蟲，若使用於水方面，得以做為水細分子化、水分子氫氧化、水霧芬多精負離子化、水霧分離氫氧化等等廣泛用途。 In the present invention, multiple boxes 10 of the first embodiment can be connected in series or parallel, or one or more of the boxes 10, 50, 90 of the first, second, and third embodiments can be connected in series or parallel. This case is not only

The transmission and derivation of high-frequency oscillations,

, And it can be infinitely extended in series and parallel to repel birds and insects in a wide range, and the electronic control device can adjust its frequency, which is suitable for repelling different species of birds and insects. If used in water, it can be used as water molecules. It has a wide range of applications, such as hydrogenation of water molecules, hydrogenation of water molecules, negative ionization of water mist and Fendol, and separation of water mist for hydrogenation.

In the fifth embodiment, as shown in the twelfth and thirteenth figures, the metal mesh 150 and the coupling post 151 can be joined by welding, so that several pieces of the metal mesh 150 can be fixed on the coupling post 151; sixth In an embodiment, as shown in the fourteenth and fifteenth figures, the metal mesh 152 and the coupling post 153 are combined by welding, and the inner wall of the protective frame 154 is provided with a plurality of embedding grooves 1541 or embedding holes 1542. The groove 1541 is for the corners of the metal mesh 152 to be embedded. The metal mesh 152 can be provided with a number of protrusions 1521, and the recessed holes 1542 are for the protrusions 1521 of the metal mesh 152 to be embedded, so that the metal mesh 152 and the protective frame 154 are combined; the seventh embodiment For example, as shown in the sixteenth and seventeenth figures, the metal mesh 155 and the insulating spacer 158 are combined by a combining post 156 (stud), and the inner wall of the protective frame 157 is provided with a plurality of embedding grooves 1571 or embedding holes 1572, the embedding groove 1571 is for the corners of the metal mesh 155 to be embedded. The two sides of the metal mesh 155 can be provided with a number of protrusions 1551. The embedding hole 1572 is for embedding the protrusions 1551 of the metal mesh 155 to make the metal mesh 155 and the protective frame 157 The eighth embodiment, as shown in the eighteenth and nineteenth figures, the metal mesh 159 can be provided with a number of protruding pieces 1591 on the outside, and the protruding pieces 1591 are combined with the coupling post 160 by welding; the ninth embodiment, such as the second 10. As shown in Figure 21, a single outer side of the metal mesh 161 can be provided with a protruding piece 1611. The protruding piece 1611 is welded to the coupling column 162. The inner wall of the protective frame 163 is provided with a plurality of embedding grooves 1631 and a number Embedded hole 1632, embedded groove 1631 for the corner of the metal mesh 161 to be embedded, and part of the metal mesh 161 for the protrusion 1611 to be embedded Embedded hole 1632.

In summary, the novelty, practicability and advancement of a high-frequency oscillating transmission and derivative device of the present invention is undoubtedly in full compliance with the requirements of the patent, and it is submitted in accordance with the law.

10: Box body

20: Transmitter of high frequency oscillation

30: electric bridge

11: Placement space

21: right oscillator

22: Left Oscillator

210: Right front shock group

2100: right rear shock group

220: Left front shock group

2200: Left rear shock group

23: Metal mesh

240: binding column

24: The first binding column

25: The second binding column

26: The third binding column

28: Protective frame

Claims (9)

A high-frequency oscillation transmission and derivative device, which includes: a box body with at least one storage space; a machine surface IC, which controls pulse signals and ultra-high-frequency general-wave electric energy waves; at least one set of high-frequency oscillations The transmitter is integrated in the box and has several pieces of metal mesh and several binding posts. The several binding posts combine several pieces of metal mesh, and the metal mesh does not touch the metal mesh; at least one protective frame , Set around the high-frequency oscillating transmitter; an electronic control device, the receiver face IC's ultra-high frequency general wave electric energy wave, the power is inserted into one of the binding columns, and the current flows through the binding column to the metal mesh The chip is then led by other binding columns, and the current flows to the electronic control device. In the box, a set of high-frequency oscillators in parallel or in series, or a box with high-frequency oscillators ，Use the parallel or series connection method to generate extremely high frequency transmission and derivation. The device for transmitting and deriving high-frequency oscillations according to claim 1, wherein there is an insulating spacer between the metal mesh and the metal mesh, the insulating spacer is a mesh, and the mesh and the insulating spacer of the metal mesh The mesh of the film is relative. A set of high-frequency oscillators is a combination of a right oscillator and a symmetrical left oscillator. The right oscillator is a combination of a right front oscillator and a right rear oscillator. The left oscillator It is an assembly of a left front shock group and a left rear shock group, a right front shock group and a right rear shock group, and a left front shock group and a left rear shock group. The binding columns include a first binding column, a second binding column and a third binding column , The first combination column is a double-ended stud, which combines several nuts, clips, elastic gaskets and inner gaskets. The inner gasket is located between the metal mesh and the insulating spacer. The elastic gasket is a curved gasket with compression elasticity , The second combining column is a combination of a short top stud and a long stud, combining the nut and the inner gasket, the inner gasket is located between the metal mesh sheet and the insulating spacer, and the third combining column combines a solenoid, Nut and inner gasket, the inner gasket is located between the metal mesh and the insulating spacer, the right front shock group and the right rear shock group There is a middle insulating partition between the left front shock group and the left rear shock group. There is a middle insulating partition between the left front shock group and the left rear shock group. The middle insulating partition has a raised surface, a barrier groove and a perforation. The binding column enters the top and blocks the third binding column. Perforated for the second binding column to pass through. The first binding column is used for binding and passing through one end of the right front oscillation group, and the second binding column is used for binding and passing through the right front oscillation group and right rear oscillation. At the other end of the group, the third combining column is used to combine and pass through one end of the right rear shock group. There is a bridge connecting the third combination column of the right rear shock group of the right oscillator and the third combination column of the left rear shock group of the left oscillator. column. The high-frequency oscillation transmission and derivative device according to claim 1, wherein the metal mesh piece and the metal mesh piece are not attached, and an insulating spacer is arranged between two metal mesh pieces and a metal mesh piece, between The distance generates heat dissipation space. A set of high-frequency oscillators is a combination of a right oscillator and a symmetrical left oscillator. The right oscillator is a right front oscillator and a right rear oscillator. The left oscillator is a left front oscillator. The concussion group is assembled with a left rear concussion group, the right front concussion group and the right back concussion group, and the left front concussion group and the left back concussion group. The binding columns include a first binding column, a second binding column and a third binding column. The binding column is a short stud, which combines the nut, clip and elastic gasket. The elastic gasket is a curved pad with compression elasticity. The second binding column is a front long stud and a rear short stud, which combines the clip and Elastic gasket, the third binding post combines a solenoid and a nut. The insulating spacer has two convex rings at one end, and a perforation and two convex posts at the other end. The two convex rings separate the two metal mesh pieces, and the two convex posts are located on the two insulation. Between the spacers, there is an electrical bridge connecting the third combining column of the right rear oscillating group of the right oscillator and the third combining column of the left rear oscillating group of the left oscillator. The device for transmitting and deriving high-frequency oscillations according to claim 1, wherein there is an insulating spacer between the metal mesh and the metal mesh, the insulating spacer is a mesh, and the mesh and the insulating spacer of the metal mesh The mesh of the film is opposite. The transmitter of this group of high-frequency oscillations is a combination of a right oscillator and a symmetrical left oscillator. The right oscillator and the left oscillator. The combined column has a first combined column and a second combined column. And the third combination column, the first combination column is a combination of a short top stud and a long stud, the combination of the nut and Inner gasket, the inner gasket is located between the metal mesh and the insulating spacer, the second binding column is a double-ended stud, and the number of nuts, clamps, elastic gaskets and inner gasket are combined, and the inner gasket is located on the metal mesh Between the sheet and the insulating spacer, the elastic gasket is a curved gasket with compression elasticity. The third coupling column combines a solenoid, a nut and a gasket. The first coupling column is used for coupling and passes through the upper end of the right oscillator. The second coupling The column is used to combine and pass through the lower front end of the right oscillator, the third combining column is used to combine and pass through the lower rear end of the right oscillator, and a bridge connects the first combining column of the right oscillator and the first combining column of the left oscillator. The electronic control device feeds power to the second combining column of the right oscillator and its metal mesh, and the power from the metal mesh flows through the first combining column, and then from the bridge to the metal mesh of the left oscillator, so that the current flows through the right The oscillator passes through the bridge to the left oscillator, and the current flows to the electronic control device to generate extremely high frequencies. The device for transmitting and deriving high-frequency oscillations according to claim 4, wherein the left oscillator can be connected to another right oscillator at an angle through a bridge. The high-frequency oscillation transmission and derivation device as described in claim 1, wherein the metal mesh sheet and the bonding column can be combined by welding. The transmission and derivation device of high-frequency oscillation as described in claim 1, wherein the inner wall of the protective frame is provided with a plurality of embedding grooves and several embedding holes, the embedding grooves are used for the corners of the metal mesh to be embedded, and the outside of the metal mesh Several protruding pieces can be provided, and the protruding pieces are embedded in the embedding hole. The high-frequency oscillation transmission and derivation device as described in claim 1, wherein the metal mesh sheet can be provided with a number of protruding pieces on the outside, and the protruding pieces are combined with the coupling column by welding. The transmission and derivation device of high-frequency oscillation as described in claim 1, wherein the inner wall of the protective frame is provided with a plurality of embedding grooves and several embedding holes, the embedding grooves are for the corners of the metal mesh to be embedded, and the metal mesh is single A protruding piece can be provided on the outer side, and the protruding piece is combined with the combining post by welding, and part of the protruding piece of the metal mesh is embedded in the embedded hole.

Images