RU2674519C1 - Antenna - Google Patents

Abstract

FIELD: antenna equipment.

SUBSTANCE: invention relates to the ultra-wideband antennas with vertical polarization and circular radiation pattern in the horizontal plane, and can be used in transmission / receiving systems. In the antenna three separate emitters for GNSS, AM, and DW1 bands are used. GNSS band emitter is made spiral and is located at the antenna base. Emitters for the AM and DW1 bands are made of sets of metal tubes and dielectric bushings, ending with the conductive cable, and in their feeder lines coaxial cables sections chokes are installed.

EFFECT: invention allows to reduce the SWR, simplify the design, and improve operating in three bands (GNSS, AM, DW1) antenna usability.

6 cl, 4 dwg

Description

The invention relates to the field of antenna devices, in particular, to ultra-wideband antennas with vertical polarization and a circular radiation pattern in the horizontal plane, and can be used in transceiver systems.

From US patent application US2010302116, publ. 12/02/2010, an antenna is known that operates in the frequency range 30–512 MHz, having a base with a shock absorber, an emitter of the lower subband (MV range) and an emitter of the upper subband (DMV1 range). The antenna is made of a set of metal tubes and a conductive cable. The dipole of the upper subrange consists of two pipes interconnected by an insulating disk, inside of which there is a capacitive element - a conductor covered with insulating material. The dipole of the lower subrange is formed by a set of metal tubes of a smaller diameter and a conductive cable. To separate the lower and upper sub-bands, the antenna is equipped with a filter. The limitations of this device are the impossibility of functioning in GNSS satellite navigation systems (GNSS, from the Global Navigation Satellite System), the need to use a filter, and large longitudinal dimensions.

A known antenna operating in the medium frequency ranges 800 MHz and 1900 MHz, disclosed in US patent US5812097, publ. 09/22/1998. This antenna is intended for use in mobile telephones and is a combined helical and whip antenna. The advantage of the antenna is the simplicity of design, and the limitation is the ability to operate in only two frequency ranges.

The closest to the claimed technical solution is the antenna company Trival Antene AD-27 / V150-3512-DF, operating in the frequency ranges 30–88 MHz and 225–512 MHz (published on the website http://www.trivalantene.si/sites/default /files/brochures/AD-27-V150-3512-DF%20Rev-A%20ANG_0.pdf, accessed June 2017). This antenna contains a base in the form of a cup equipped with a flange designed for mounting it to the base surface, a shock absorber made in the form of a coil spring, pieces of two coaxial cables for the MV and DMV1 ranges, a single emitter of the lower and upper subbands made of metal tubes, and RFI separation board located at the base.

The limitations of this technical solution are:

- the impossibility of functioning in GNSS satellite navigation systems;

- a sufficiently large standing wave coefficient (SWR) of up to 3.5;

- the need to use radio frequency filters, which when using a single emitter are a complex and time-consuming product;

- insufficiently high degree of ease of use due to the integral structure when attaching the base to the base surface.

The problem solved by the invention is to expand the functionality and improve the technical and operational characteristics of the antenna.

The technical result achieved by the claimed technical solution is to reduce the SWR, simplify the design by eliminating the base of the separation of radio frequency filters from the base of the antenna, increasing the usability.

To solve the problem with achieving the specified technical result, the claimed antenna contains a base, a GNSS range emitter, a MV range emitter, and a DMV1 range emitter.

The base includes a base housing and a nozzle provided with a first flange for mounting to the base surface and a second flange for mounting to the base housing. The housing consists of a first dielectric sleeve, a second dielectric sleeve, a metal spacer located between the first and second dielectric bushings, a shock absorber made in the form of a coil spring, a third dielectric sleeve equipped with a radio-transparent cover installed one after the other along the longitudinal axis, as well as locks latches of tension mounted on the outer surface of the third dielectric sleeve, a round metal plate mounted in the bottom region of the first dielectric sleeve, three okochastotnyh connectors mounted on the side of the plate facing the pipe, the first and second RF connectors with bladed articulation means, which receiving portion is located outside of the radio transparent lid third dielectric sleeve, and the three segments of the coaxial cable, one end of which is connected by three high frequency terminals. The first and second segments of the coaxial cable are located inside the first dielectric sleeve, metal spacer, the second dielectric sleeve, shock absorber, the third dielectric sleeve, and the other ends of the first and second segments of the coaxial cable are connected respectively to the first and second connectors.

The GNSS range emitter is located inside the base case and includes a spiral, a fourth dielectric sleeve and a broadband matching device. The spiral is made of a metal tape wound around the fourth dielectric sleeve mounted inside the second dielectric sleeve, and the other end of the third segment of the coaxial cable is connected to the end of the spiral facing it through a matching device.

The MV range emitter consists of a hollow dielectric body, a first metal tube, a fifth dielectric sleeve provided with end rings, a second metal tube, a sixth dielectric sleeve, a seventh dielectric sleeve fixed outside the sixth dielectric sleeve mounted one after the other along the longitudinal axis as well as the first choke of the MV range, the second and third chokes of the DMV1 range, latches of latches-latches fixed on the outer surface of the dielectric of the housing, the first and second connectors, the mating part of which is installed inside the dielectric housing with the possibility of connecting the mating part with the receiving part of the connectors by means of snap locks, the third radio frequency connector with the cutting means of coupling, the receiving part of which is located at the end of the sixth dielectric sleeve inside the seventh dielectric sleeve , on the outer surface of which is made a thread of Edison, the fourth length of the coaxial cable and the fifth length of the coaxial cable. The fourth segment of the coaxial cable is connected to the first connector, and through the first choke of the MV range, installed inside the dielectric housing, is connected by its central core to the second metal tube, and the braid to the first metal tube. The emitter of the MV range also consists of a matching transformer made with a winding of a two-wire line on a ferrite ring installed in the hole, which is made in the side wall of the fifth dielectric sleeve. The ends of the matching transformer are connected to the contact rings of the fifth dielectric sleeve, one of which is in contact with the first metal tube, and the other with the second metal tube. One end of the fifth segment of the coaxial cable is connected to the second connector. The other end of the fifth segment of the coaxial cable through the second choke of the DMV1 range installed in the dielectric casing and the third choke of the DMV1 range installed in the fifth dielectric bushing is connected to the third connector.

The emitter of the DMV1 range consists of an eighth dielectric sleeve, a third metal tube, a twisted spiral, a capacitor, a conductive cable installed one after the other along the longitudinal axis, as well as the sixth segment of the coaxial cable and ferrite rings. On the inner surface of the eighth dielectric sleeve, an Edison thread is made with the possibility of connecting the eighth dielectric sleeve with the seventh dielectric tube through the Edison thread. The counterpart of the above-mentioned third connector is installed inside the eighth dielectric sleeve with the possibility of connecting the counterpart with the receiving part of the third connector when connecting the eighth dielectric sleeve outside the seventh dielectric tube. The sixth segment of the coaxial cable mentioned is located inside the eighth dielectric sleeve and the third metal tube, with one end connected to the third connector, the central core of the other end connected to one end of the twisted spiral, and the braid to the third metal tube. The other end of the twisted spiral is electrically connected through a capacitor to a conductive cable. Ferrite rings are mounted on the outer surface of the sixth segment of the coaxial cable inside the eighth dielectric sleeve in the region adjacent to the third connector.

Additional embodiments of the device are possible, in which it is advisable that:

- matching device emitter GNSS range was made on a printed circuit board according to the scheme of the active receiving antenna and placed in a sleeve-bracket mounted on the aforementioned metal spacer, and provided with a polyamide cover;

- studs were inserted into the base body, tightening the second dielectric sleeve with the first dielectric sleeve through a metal spacer to the second pipe flange;

- the base shock absorber was made in the form of a twisted shaped barrel-shaped spring, and the pipe was conical;

- the emitter of the DMV1 range was equipped with a hollow dielectric cone-shaped nozzle installed in the area of a twisted spiral and capacitor on a third metal tube and on a conductive cable;

- The first dielectric sleeve of the base case was filled with a compound.

These advantages, as well as the features of the present invention are explained using its implementation with reference to the figures.

In FIG. 1 shows the base of the antenna with a GNSS range emitter.

In FIG. 2 shows an emitter of the MV range.

In FIG. 3 shows a radiator of the DMV1 range.

In FIG. 4 shows a General view of the claimed antenna (left) and the order of its assembly (right).

The claimed antenna contains a base, a GNSS range emitter, a MV range emitter, and a DMV1 range emitter.

The base 1 (Fig. 1) consists of a base body 2 and a nozzle 3 provided with a first flange 4, intended for fastening the base 1, therefore, the antenna, to the base surface, and a second flange 5, used to fasten the nozzle 3 to the base body 2 . The housing 2 of the base consists of a first dielectric sleeve 6, a second dielectric sleeve 7, a metal spacer 8 located between the first and second dielectric bushings 6, 7. The base 1 also has a shock absorber 9, made in the form of a coil spring, and a third dielectric sleeve 10 (configured ) equipped with a radiolucent cover 11.

The housing 2 of the base, the shock absorber 9 and the third dielectric sleeve 10 are installed one after another along the longitudinal axis. The base 1 is equipped with locks-latches 12 (tension), mounted on the outer surface of the third dielectric sleeve 10. In the bottom area of the first dielectric sleeve 6 is installed plate 13 (metal, round). On the side of the plate 13, facing the pipe 2, three high-frequency connectors 14, 15, 16 are installed. On the radiolucent cover 11 of the third dielectric sleeve 10, the first and second radio-frequency connectors 17, 18 are made, made with the cutting means of articulation.

Three ends of the three segments 19, 20, 21 of the coaxial cable are connected to three high-frequency connectors 14, 15, 16, respectively. The first and second cable sections 19, 20 are located inside the first dielectric sleeve 6, the metal spacer 8, the second dielectric sleeve 7, the shock absorber 9, the third dielectric sleeve 10, and their other ends are connected respectively to the first and second connectors 17, 18.

The emitter 22 of the GNSS range (Fig. 1) is located inside the housing 2 of the base and consists of a spiral 23, the fourth dielectric sleeve 24, the matching device 25 (broadband). The spiral 23 is made of a metal tape wound on a fourth dielectric sleeve 24 mounted inside the second dielectric sleeve 7. The other end of the third segment 21 of the coaxial cable is connected to the end of the spiral 23 facing it through a matching device 25.

In FIG. 1 also shows the studs 26 and the sleeve-bracket 27, the purpose of which will be disclosed below.

The emitter 30 of the MV range (Fig. 2) consists of a dielectric housing 31 made hollow, the first metal tube 32, the fifth dielectric sleeve 33, provided with ends with contact rings 34, 35, the second metal tube 36, the sixth dielectric sleeve 37, the seventh dielectric sleeve 38 mounted outside the sixth dielectric sleeve 37, mounted one after the other along the longitudinal axis. The emitter 30 has a first choke 39 range MV; it also houses the second and third chokes 40, 41 of the DMV1 range.

The latches 42 of the above latches-latches 12 (Fig. 1) are mounted on the outer surface of the dielectric housing 31. The counterpart of the first and second connectors 17, 18 (Fig. 1) is installed inside the dielectric housing 31 with the possibility of connecting the counterpart to the receiving part of the connectors 17 , 18 by means of latches 12.

The third radiofrequency connector 43 with the die-cutting articulation means has a receiving part, which is located at the end of the sixth dielectric sleeve 37 inside the seventh dielectric sleeve 38. On the outer surface of the seventh dielectric sleeve 38, an Edison thread is made. The fourth segment 44 of the coaxial cable is connected to the first connector 17, and through the first choke 39 of the MV range, installed inside the dielectric housing 31, is connected with its central core to the second metal tube 36 and the braid to the first metal tube 32.

The matching transformer 45 is made with a two-wire line winding on a ferrite ring installed in the hole that is made in the side wall of the fifth dielectric sleeve 33. The ends of the matching transformer 45 are connected respectively to the contact rings 34, 35 of the fifth dielectric sleeve 33, one of which is in contact with the first a metal tube 32, and the other with a second metal tube 36. One end of the fifth segment 46 of the coaxial cable is connected to the second connector 18. The other end of the fifth segment 46 of the coax the cable is connected to the third connector 43 through the second inductor 40 of the DMV1 range, installed in the dielectric housing 31, and the third inductor 41 of the DMV1 range, installed in the fifth dielectric sleeve 33.

The emitter 50 of the DMV1 range (Fig. 3) consists of an eighth dielectric sleeve 51, a third metal tube 52, a twisted spiral 53, a capacitor 54, a conductive cable 55 installed one after the other along the longitudinal axis, the sixth segment 56 of the coaxial cable and ferrite rings 57. On the inner surface of the eighth dielectric sleeve 51, an Edison thread is made with the possibility of connecting the Edison thread of the eighth dielectric sleeve 51 with the seventh dielectric tube 38 (Fig. 2). The counterpart of said third connector 43 is installed inside the eighth dielectric sleeve 51 with the possibility of connecting the counterpart with the receiving part of the third connector 43 when connecting the eighth dielectric sleeve 51 outside the seventh dielectric tube 38. The sixth segment 56 of the coaxial cable is located inside the eighth dielectric sleeve 51 and the third metal tube 52. One end of the sixth segment 56 of the coaxial cable is connected to the third connector 43, the Central core of the other end is connected to one m the end of the twisted spiral 53, and the braid with the third metal tube 52. The other end of the twisted spiral 53 is electrically connected through a capacitor 54 to the conductive cable 55. Ferrite rings 57 are mounted on the outer surface of the sixth segment 56 of the coaxial cable inside the eighth dielectric sleeve 51 in the region adjacent to the third connector 43.

In FIG. 3 also shows a nozzle 58 and contact parts 59 for connecting the braid of the sixth section 56 of the coaxial cable to the third metal tube 52.

The matching device 25 of the GNSS emitter 22 can be performed on a printed circuit board according to the scheme of an active receiving antenna (typical), placed in a metal bushing-bracket 27, mounted on said metal spacer 8, and equipped with a polyamide cover.

In the base case 2, studs 26 can be inserted, tightening the second dielectric sleeve 7 with the first dielectric sleeve 6 through a metal spacer 8 to the second pipe flange, which provides additional structural rigidity.

The shock absorber 9 of the base 1 can be made in the form of a twisted shaped barrel-shaped spring, and the pipe is conical, which increases the usability of the antenna.

To ensure reliability of the structure, the emitter 50 of the DMV1 range can be equipped with a hollow dielectric nozzle 58 that is cone-shaped and is installed in the area of a twisted spiral 53 and a capacitor 54 on the third metal tube 52 and on the conductive cable 55.

The first dielectric sleeve 6 of the housing 2 of the base 1 is preferably filled with a compound.

The claimed antenna works as follows.

The antenna (Fig. 4) is made in the form of a single collapsible design, which contains separate emitters 22, 30, 50 of different ranges, which reduces the SWR (as shown by tests, the SWR is not more than 3.1 for the ranges MV and DMV1 and not more than 2, 8 for the GNSS range), and also improves the usability of the antenna. Improving the usability of the antenna is also achieved due to the simplicity of assembly-disassembling of the structure due to the use of the first and second connectors 17, 18 and the third connector 43 with the cutting means of articulation, locks-latches 12, thread Edison on the outer surface of the seventh dielectric sleeve 38 and the inner the surface of the eighth dielectric sleeve 51.

The international standard ISO 9241-11 defines usability as the degree to which a product can be used by certain users in a specific use context to achieve certain goals with due efficiency, productivity and satisfaction. The term "usability" can be considered a synonym for the word "ergonomics" with the difference that the latter determines the minimum specific physical efforts when using a thing, and the first - the final total degree of convenience, a measure of the intellectual effort necessary to obtain the useful qualities of this thing and the speed of achievement a positive result when managing it.

At the base of 1 antenna, there is a GNSS range emitter 22 with a matching device 25 made on a printed circuit board and soldered to it by means of a thin wire pin with a spiral 23 (spiral-shaped radiator) made of brass tape wound around the fourth dielectric sleeve 24 (polyamide, radiolucent) . The sleeve-bracket 27 of the matching device 25 is made of brass and has a polyamide cover protecting the module of the matching device board 25 from the casting compound (pentelast or PEK-74), which is used to fill the internal cavity of the base case 2 to ensure tightness and, at the same time, maintainability module board matching device 25. To ensure sufficient structural strength in the first dielectric sleeve 6 made holes in which are inserted studs 26 (steel) with threaded holes on the ends for Pezha to other component parts. A plate 13 is screwed to the first dielectric sleeve 6, in which there are three high-frequency connectors 14, 15, 16 (TNC connectors from Threaded Neill-Concelman can be used) - three antenna ports.

The shock absorber 9 is designed to compensate for mechanical stresses destroying the antenna caused by bending moment that occurs when the antenna meets an obstacle, as well as when the speed or direction of movement of the object with the antenna mounted on it or during vibration changes sharply. A third dielectric sleeve 10 (made of polyamide) with a radiolucent cover 11 (made of polyamide) is screwed to the shock absorber 9, in which the first and second connectors 17, 18 (for example, type СР-50-902ФВ) are installed, which are connected by the first and second segments 14, 15 coaxial cables with two connectors 14, 15 (TNC) and form with them two feeder lines MV and DMV1 paths. The third connector 16 (TNC) is connected by the third segment 21 of the coaxial cable to the matching device 25.

The emitter 30 of the MV range (Fig. 2) consists of a dielectric housing 31 (polyamide, radiolucent) with two connectors 17, 18 (for example, type CP-50-903FV) and two chokes 39, 40 on ferrite rings that are built into the feeder lines MV and DMV1 and are extensions of feeder lines MV and DMV1 at the base of 1 antenna. Above are two metal pipes 32, 36 (aluminum). The first metal pipe 32 serves as a counterweight to the emitter 30 of the MV range, and the second metal pipe 36 is emitting. The metal pipes 32, 36 are interconnected by a fifth dielectric sleeve 33 (radiolucent), accommodating a matching transformer 45 in its cavity. The contact rings 34, 35 are designed for soldering the terminals of the matching transformer 45. The terminals of the matching transformer 45 are soldered to the petals of the contact rings, and the rings are placed between the fifth dielectric sleeve 33 and the metal pipes 32, 36. Also, the fifth dielectric sleeve 33 accommodates another choke on a ferrite ring related to the feeder line DMV1. The emitter 30 of the MV range in the upper part of the sixth dielectric sleeve 37 and the seventh dielectric sleeve 38 (polyamide), one of which is the dielectric sleeve 37, contains a third connector 43 (for example, of the type CP-50-903FV) to which the range emitter 50 is connected DMV1 through the thread of Edison. Edison thread is noteworthy in that it has an increased resistance to dynamic loads, is well screwed and unscrewed in conditions of increased pollution and has a long service life.

The emitter 30 is attached to the base 1 using special latches-latches 12 (for example, the company OJOP 704 L / C, model 520963), which makes the antenna quick-detachable.

The emitter 50 of the range DMV1 (Fig. 3) is a pin emitter, in which the role of inductance is played by a twisted spiral 53 which is part of the web and which is a conductive cable 55 (steel). The conductive cable 55 is crimped by a sleeve to which the twisted spiral 53 is soldered through the capacitor 54. On the opposite side from the sheet to the twisted spiral 53 through the contact parts 59, the sixth section 56 of the coaxial cable is soldered, which passes through the third metal tube 52 (aluminum), which is a counterweight radiator 50 connected to these contact parts 59. Next, the third metal tube 52 is connected to the eighth dielectric sleeve 51 (radiolucent, polyamide), in the cavity of which eight ferrite rings 57 are placed, x in the sixth segment 56 at a third coaxial cable connector base 43 (e.g., type CP 50-903FV) in order to cut off the common-mode currents.

The invention allows to expand the functionality of the antenna by combining three antennas of different ranges (GNSS, MV, DMV1) in one device, which allows you to use one antenna and, as a result, one seat for the antenna on a vehicle or base station.

While the closest analogue has one common radiator in two ranges (MV and DMV1), the claimed antenna contains three separate radiators in the GNSS, MV and DMV1 ranges located along the vertical axis of the antenna. In addition to improving the SWR, this also simplifies the design by eliminating the RF separation filter boards from the base of the antenna, which in the case of a single emitter are a complex and time-consuming product, and in addition increases the usability of the antenna.

The most successfully claimed antenna is industrially applicable in transceiver systems.

Claims (10)

1. An antenna containing: a base consisting of a housing comprising a first dielectric sleeve, a second dielectric sleeve and a metal spacer located between them, a nozzle equipped with a first flange for attaching the base to the base surface and a second flange for attaching the nozzle to the base body, a shock absorber made in the form of a coil spring, and a third dielectric sleeve equipped with a radiolucent cover, mounted one after the other along the longitudinal axis, as well as latches, latches, mounted on the outer surface of a third a dielectric sleeve, a plate mounted in the region of the bottom of the first dielectric sleeve, three high-frequency connectors mounted on the side of the plate facing the nozzle, the first and second radio frequency connectors with the cutting means of coupling, the receiving part of which is located outside on the radiolucent cover of the third dielectric sleeve, three pieces of coaxial cable, one ends of which are connected by three high-frequency connectors, while the first and second pieces of coaxial cable are located inside a first dielectric sleeve, a metal spacer, a second dielectric sleeve, a shock absorber, a third dielectric sleeve, and their other ends are connected respectively to the first and second connectors, GNSS range emitter located inside the base case and consisting of a spiral, fourth dielectric sleeve and a broadband matching device, the spiral being made of a metal tape wound around a fourth dielectric sleeve installed inside the second dielectric sleeve and the other end of the third segment of the coaxial cable is connected with the end of the spiral facing it through a matching device, MV range emitter, consisting of a hollow dielectric body, a first metal tube, a fifth dielectric sleeve provided with end rings, a second metal tube, a sixth dielectric sleeve and a seventh dielectric sleeve fixed outside the sixth dielectric sleeve mounted one after another along the longitudinal axis as well as the first choke of the MV range, the second and third chokes of the DMV1 range, latches of latches-latches fixed on the outer surface of the dielectric the housing, the first and second connectors, the mating part of which is installed inside the dielectric housing with the possibility of connecting the mating part with the receiving part of the connectors by means of latches, the third radio-frequency connector with the cutting means of coupling, the receiving part of which is located at the end of the sixth dielectric sleeve inside the seventh dielectric sleeve , on the outer surface of which is made the thread of Edison, the fourth segment of the coaxial cable, the fifth segment of the coaxial cable I, while the fourth segment of the coaxial cable is connected to the first connector, and through the first choke of the MV range, installed inside the dielectric housing, connected by its central core to the second metal tube and braid to the first metal tube, and a matching transformer made with a two-wire winding lines on the ferrite ring installed in the hole in the side wall of the fifth dielectric sleeve, while the ends of the matching transformer are connected to the contact rings of the fifth dielectric bushings, one of which is in contact with the first metal tube, and the other with the second metal tube, one end of the fifth segment of the coaxial cable is connected to the second connector, and through the second choke of the DMV1 range installed in the dielectric housing and the third choke of the DMV1 range installed in the fifth dielectric sleeve, the other end of the fifth length of the coaxial cable is connected to the third connector, and a radiator of the DMV1 range, consisting of an eighth dielectric sleeve, a third metal tube, a twisted spiral, a capacitor and a conductive cable installed one after the other along the longitudinal axis, as well as the sixth segment of the coaxial cable and ferrite rings, while the thread is made on the inner surface of the eighth dielectric sleeve Edison with the ability to connect the Edison thread of the eighth dielectric sleeve with the seventh dielectric tube, and the mate of the third connector is installed inside the eighth dielectric sleeve with the possibility of connecting the mate with the receiving part of the third connector when connecting the eighth dielectric sleeve outside the seventh dielectric tube, the sixth segment of the coaxial cable is located inside the eighth dielectric sleeve and the third metal tube, one end is connected to the third connector, the central core of the other end is connected to one end of a twisted spiral, and the braid with a third metal tube, the other end of a twisted spiral is electrically connected through a conden ator with a conductive cable, the ferrite ring mounted on the outer surface of the sixth segment of the coaxial cable within the eighth dielectric sleeve in the region adjacent to the third connector. 2. The antenna according to claim 1, characterized in that the matching device of the GNSS range emitter is made on a printed circuit board in accordance with an active receiving antenna circuit and is placed in a bracket sleeve mounted on said metal spacer and provided with a polyamide cover. 3. The antenna according to claim 1, characterized in that the studs are inserted into the base body, tightening the second dielectric sleeve with the first dielectric sleeve through a metal spacer to the second pipe flange. 4. The antenna according to claim 1, characterized in that the base shock absorber is made in the form of a twisted shaped barrel-shaped spring, and the pipe is conical. 5. The antenna according to claim 1, characterized in that the radiator of the DMV1 range is equipped with a nozzle mounted in the area of a twisted spiral and capacitor on a third metal tube and on a conductive cable. 6. The antenna according to claim 1, characterized in that the first dielectric sleeve of the base housing is filled with a compound.

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