JPH0110718Y2 - - Google Patents

Description

[Detailed explanation of the invention] This invention uses radio waves to detect intruding objects,
The present invention relates to a radio wave alarm device that issues an alarm.

In general, radio wave warning devices that use radio waves to block the opposition have fewer false alarms and are more reliable than those that use other methods, such as those that use light or ultrasonic waves, so It is often used in

However, since most radio alarm devices use a parabolic antenna or an electromagnetic horn as the antenna, a certain size is required in order to obtain the beam width necessary for the radio alarm device. For example, when using a parabolic antenna, the diameter is 30 mm.
cm, length 20cm, and those using an electromagnetic horn require a length of 30cm or more, and cannot be easily installed anywhere.

Further, a radio wave alarm device of a counter-blocking type is also called an electromagnetic fence, and its detection range is ideally wide in the vertical direction and narrow in width. In other words, when it comes to radio wave beams, the Fann beam is ideal, but with normal parabolic antennas and electromagnetic horns,
There is no significant difference in beam width in both the vertical and horizontal directions, and a fan beam cannot be obtained. Furthermore, an electromagnetic horn with a cut parabola or a single-sided aperture is not practical in terms of efficiency and size.

This invention was made in view of the above circumstances, and its purpose is to provide an inexpensive radio wave warning device that is small, lightweight, easy to install, has few malfunctions, and is highly reliable.

An embodiment of this invention will be described below with reference to the drawings. FIG. 1 is a block diagram of a radio wave alarm device using a counter-blocking method using microwaves, in which a indicates a transmitting section and b indicates a receiving section. In the transmitter a, 11 is a stabilized power supply circuit, and when a predetermined voltage is applied by this stabilized power supply circuit 11,
Gunn oscillator 12 generates predetermined microwaves. This microwave is amplitude-modulated by a modulator 13 that outputs, for example, a 1KHz pulse signal,
It is radiated into space by the transmitting antenna 14.

On the other hand, in the receiving section b, 15 is a receiving antenna, and this antenna 15 is installed at a predetermined distance from the transmitting antenna 14. When the antenna 15 receives the microwaves radiated into the space, the received microwaves are removed, for example, by a bandpass wave generator 16, and are further detected by a wave detector 17 and output. . The detected output is amplified by a low frequency amplifier 18 and input to a Schmitt circuit 19.
Here, the output signal from the low frequency amplifier 18 is input to the wave detector 20, and the AGC circuit 21 is operated by the detected output from the wave detector 20. That is, by controlling the gain of the AGC circuit 21,
A signal at a constant level is supplied to the Schmitt circuit 19. Further, a stabilized power supply circuit 22 is connected to the Schmitt circuit 19,
This provides power. When an intruding object such as a human interrupts the gap between the transmitting antenna 14 and the receiving antenna 15, the microwave is attenuated and the input voltage to the Schmitt circuit 19 becomes below the set level. This drop in voltage level is
It is detected by the detection circuit 23. The output signal from the detection circuit 23 is amplified and waveform-shaped to drive a relay (not shown), and an alarm device (not shown) is activated by the alarm signal to display an alarm.

Figures 2A, B, and C and Figures 3A, B, and C show the specific configuration of the radio wave alarm device.
Figures A, B, and C are the transmitter a, and Figure 3 A, B, and C.
indicates the receiving section b. In FIG. 2A, reference numeral 24 denotes a box-shaped cover with an open lower portion, and this cover 24 is molded, for example, with a plastic mold. The cover 24 is attached so as to cover the casing 25 part in FIG. 2B,
This prevents the effects of environmental changes such as rain and wind. The casing 25 is formed by bending an aluminum plate so that the side surfaces are approximately U-shaped, and the front surface thereof is opened to expand in the vertical direction. The bottom member of the casing 25 is appropriately formed by extrusion or the like, and the transmitting antenna 14, for example, the slot waveguide 26 shown in FIG. 2C, is incorporated therein. The slot waveguide 26
is constructed of aluminum and has a rectangular cross section;
A plurality of slots 27, 27, . . . are formed in the narrow surface so as to be inclined in opposite directions. Further, a short circuit plate 28 is attached to one end of the slot waveguide 26 in the longitudinal direction.
Here, the intervals between the plurality of slots 27, 27, . . . and the short circuit plate 28 are appropriately set so that the microwaves resonate and are radiated into space without loss. A coupling hole is formed in the wide surface of the slotted waveguide 26, and the gun oscillator 12 for generating microwaves is attached to this coupling hole via a mounting bracket 29 with screws 30, 30, . . . . Here, a shorting plate 31 is attached to the other end of the slot waveguide 26 at a position where the coupling efficiency of the Gunn oscillator 12 is the best. Furthermore, a horn 32 made of aluminum formed by sheet metal processing is attached to the bottom surface of the slots 27, 27, . It is assembled into the housing 25 as shown in FIG. Further, the stabilized power supply circuit 11
The printed circuit board of the electronic circuit section is assembled into the housing 25 at the rear of the horn 32, and plugs for connecting cables for external signals, power, etc. are attached to the bottom of the housing 25. The cover 24 is attached to the housing 25 with set screws 33, 33, . . . . That is, in the receiving section a having such a configuration, when a predetermined microwave is generated from the Gunn oscillator 12, this microwave passes through the slot waveguide 26 and passes through the slots 27, 2.
7 and is emitted by the horn 32 so as to spread in the vertical direction.

On the other hand, in FIG. 3A, 34 is the transmitter a
This cover has the same shape and dimensions as the cover 24 shown in FIG. In addition, in FIG. 3B, 35 is a housing having the same shape and size as the housing 25 in the transmitter a, and the open both ends of the housing 35 are fitted with the housing 25, respectively. The side members 36a and 36b are attached by screws 37, 37, . . . . In FIG. 3C, 38 is a slot waveguide serving as the receiving antenna 15. In FIG. The slot waveguide 38 is the slot waveguide 26 for transmission.
It has the same cross-sectional shape as the transmitting slot waveguide 26, but it is extended from the transmission slot waveguide 26, and the bandpass waveguide 16 is attached to the wide surface of the extended part.
A band pass wave detector 16 and a wave detector 17 are respectively attached thereto. A plurality of slots 39, 39, . . . are formed in the narrow side of the slot waveguide 38, corresponding to the transmission slot waveguide 26, and a shorting plate 40 is attached to one end in the longitudinal direction. There is. Further, a shorting plate 41 is fixed to the other end of the slotted waveguide 38 at a position where the detection efficiency by the detector 17 is the best, and the impedance is adjusted by a matching screw 42 as necessary. It's summery. A terminal 43 is attached to the detector 17 and is connected to the low frequency amplifier 18. A horn 44 is attached to the bottom of the slot waveguide 38,
This is assembled into the housing 35 as shown in FIG. 3B. Further, the printed circuit board of the electronic circuit section such as the AGC circuit 21 is mounted in the housing 35 at the rear of the horn 44.
Also, plugs for connecting cables such as external signals and power sources are attached to the bottom of the housing 35. The cover 34 is attached to the housing 3 with set screws 33, 33...
It can be attached to 5.

In other words, in the case of a radio wave alarm device consisting of the transmitting section a and the receiving section b configured as above, if the microwave is in the 10 GHz band, the external dimensions are approximately 30 GHz.
It is small in size (cm x 10cm x 10cm) and weighs approximately 2kg.
It becomes lighter. Therefore, it can be easily installed anywhere using simple mounting hardware. In addition, since slotted horn-shaped waveguides 26 and 38 are used for the transmitting antenna 14 and the receiving antenna 15, respectively, the half-width in the horizontal direction is approximately 8 degrees, and the half-width in the vertical direction is approximately 30 degrees.
A fan beam of 300 degrees can be obtained. Therefore, the installation width can be narrow and the security area can be widened. Furthermore, it is extremely economical as it can be made at about one-fifth of the cost of a conventional parabolic antenna type radio wave alarm system.

As described above, according to this invention, it is possible to provide an inexpensive radio wave warning device that is small, lightweight, easy to install, has few malfunctions, and is highly reliable.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a radio wave alarm device according to an embodiment of this invention, and FIGS. 2A, B, and C are perspective views showing the specific configuration of the transmitter in the above embodiment.
3 is a diagram showing a cover, B is a housing, and C is a slot waveguide section. FIGS. 3A, B, and C are perspective views showing the specific configuration of the receiving section in the above embodiment; A is a cover, and B is a diagram showing a slot waveguide section. 1 is a diagram showing a housing, and C is a diagram showing a slot waveguide section, respectively. 12... Gun oscillator, 14... Transmission antenna,
15...Antenna for reception, 16...Bandpass waveguide, 17...Detector, 26...Slot waveguide for transmission, 27...Slot for transmission, 32...Horn, 38...Slot guide for reception Wave tube, 39...reception slot, 44...horn, a...transmission section,
b... Receiving section.

Claims (1)

[Scope of utility model registration request] In a radio wave alarm device using microwaves and a counter-blocking method, a slot for transmitting microwaves is provided on the narrow side of a waveguide whose both ends are short-circuited, and a horn is provided in this slot portion, and one end of the waveguide is provided with a horn. The horn consists of a transmission slot waveguide to which a gun oscillator is attached, a circuit board installed at the rear of the horn, a casing for housing these, and a cover attached to cover the casing. A slot for receiving microwaves is provided in the narrow side of the waveguide whose transmitter and both ends are short-circuited, a horn is provided in this slot portion, and a microwave detector is built into one end of the waveguide. a reception slot waveguide section including a bandpass waveguide between the wave detector and the slot; a circuit board provided at the rear of the horn;
a receiver comprising a housing for storing these and a cover attached to cover the housing; means for detecting and alarming attenuation of microwaves between the transmitting unit and the receiving unit; A radio wave alarm device characterized by comprising: