CN108105731B - Electronic ballast mounting structure - Google Patents

Abstract

The invention relates to the technical field of ballasts, in particular to an electronic ballast mounting structure. The installation shell comprises an installation shell body; the mounting shell comprises a mounting shell body and a first partition plate, wherein the mounting shell body is provided with a mounting cavity at the upper end face, the middle part of the mounting cavity is provided with the first partition plate, and the first partition plate is used for dividing the mounting cavity into a first circuit cavity and a second circuit cavity; a first circuit cavity cover plate is arranged at the first circuit cavity opening, and a second circuit cavity cover plate is arranged at the second circuit cavity opening; a second partition board is arranged in the middle of the second circuit cavity, and a ballast mounting cavity is formed above the second partition board; the ballast is located the ballast installation intracavity, and the ballast is located the second baffle top. The invention can preferably replace the ballast.

Description

Electronic ballast mounting structure

Technical Field

The invention relates to the technical field of ballasts, in particular to an electronic ballast mounting structure.

Background

The ballast is a device which plays a role in current limiting and generating instant high voltage on the fluorescent lamp, and is made by winding enameled wires on an iron core made of silicon steel, and when the coil with the iron core is powered on/off instantly, the coil can generate high voltage by self induction and is added on electrodes (filaments) at two ends of the fluorescent lamp tube. This action is performed alternately, when the starter (jump bulb) is closed, the filament of the lamp tube is conducted to generate heat through the current-limiting of the ballast; when the starter is opened, the ballast will generate high voltage by self-induction and apply it to the filaments at two ends of the lamp tube, the filaments emit electrons to bombard the fluorescent powder on the tube wall to give out light, and the starter is turned on and off several times, and the lamp tube is turned on. When the lamp tube is normally lighted, the internal resistance is reduced, and the starter is always kept in an open circuit state, so that the current stably passes through the lamp tube and the ballast to work, and the lamp tube is normally lighted. When the ballast works, current always passes through the ballast, so the ballast is easy to vibrate and generate heat, and the ballast can generate loud sound and is easy to burn out when the quality of the ballast is poor, particularly when the quality of the ballast is poor. The existing ballast is fixedly arranged in the lamp body, which brings great inconvenience to the replacement of the ballast.

Disclosure of Invention

It is an object of the present invention to provide an electronic ballast mounting arrangement which overcomes some or all of the disadvantages of the prior art.

The electronic ballast mounting structure comprises a mounting shell, a mounting base and a mounting base, wherein the mounting shell comprises a mounting shell main body; the mounting shell comprises a mounting shell body and a first partition plate, wherein the mounting shell body is provided with a mounting cavity at the upper end face, the middle part of the mounting cavity is provided with the first partition plate, and the first partition plate is used for dividing the mounting cavity into a first circuit cavity and a second circuit cavity; a first circuit cavity cover plate is arranged at the first circuit cavity opening, and a second circuit cavity cover plate is arranged at the second circuit cavity opening; a second partition board is arranged in the middle of the second circuit cavity, and a ballast mounting cavity is formed above the second partition board; the ballast is located the ballast installation intracavity, and the ballast is located the second baffle top.

In the invention, a power grid side circuit can be arranged in the first circuit cavity, and a light source side circuit can be arranged at the lower part of the first circuit cavity, so that circuit isolation can be better realized, and further, the power utilization safety can be better ensured. The arrangement of the first partition plate enables the ballast to be better arranged at the first partition plate, so that the ballast can be better replaced by directly opening the second circuit cavity cover plate.

Preferably, the lower end face of the mounting shell is provided with a light source mounting cavity. So that the installation of the light source can be preferably facilitated.

Preferably, the ballast is removably fixedly connected to the second partition by at least one connecting structure. Thereby preferably facilitating rapid mounting and dismounting of the ballast.

Preferably, the ballast is electrically connected to the circuitry located in the first and second circuit cavities by circuit connections. Thereby preferably facilitating rapid mounting and dismounting of the ballast.

Preferably, a first circuit cavity cover plate installation groove for installing the first circuit cavity cover plate is formed in the first circuit cavity opening. Thereby enabling the first circuit chamber cover plate to be preferably installed at the opening of the first circuit chamber.

Preferably, a second circuit cavity cover plate mounting groove for mounting a second circuit cavity cover plate is formed in the second circuit cavity opening. Thereby enabling the second circuit chamber cover plate to be preferably arranged at the second circuit chamber opening.

Preferably, a second partition board mounting groove for mounting the second partition board is formed in the inner wall of the second circuit cavity. Thereby enabling the second partition to be preferably installed at the inner wall of the second circuit chamber.

Drawings

Fig. 1 is a schematic view of an electronic ballast mounting structure in embodiment 1;

fig. 2 is a schematic view of the mounting case body in embodiment 1;

FIG. 3 is a schematic half sectional view of the mounting case body in embodiment 1;

FIG. 4 is a schematic view of a connection structure in embodiment 2;

fig. 5 is a schematic view of a connecting head in embodiment 2;

fig. 6 is a schematic view of the connector holder housing in embodiment 2;

fig. 7 is a schematic view of the core of the coupling socket in embodiment 2;

fig. 8 is a half-sectional view of the core of the coupling socket in embodiment 2;

fig. 9 is a schematic view of the connecting socket bottom plate 421 in embodiment 2;

fig. 10 is a schematic view of a joint plug in embodiment 4;

fig. 11 is a schematic sectional view of a joint plug of embodiment 4;

FIG. 12 is a schematic view of a joint receptacle according to embodiment 4;

fig. 13 is a top view of the joint socket in embodiment 4;

fig. 14 is a schematic sectional view of a joint receptacle according to embodiment 4;

FIG. 15 is an enlarged view of portion A of FIG. 14;

FIG. 16 is a schematic view of a conductive slider in embodiment 4;

fig. 17 is a schematic view of a switch case in embodiment 4.

Detailed Description

For a further understanding of the invention, reference should be made to the following detailed description taken in conjunction with the accompanying drawings and examples. It is to be understood that the examples are illustrative of the invention and not limiting.

Example 1

As shown in fig. 1, the present embodiment provides an electronic ballast mounting structure including a mounting case 100, the mounting case 100 including a mounting case main body 110; the upper end face of the mounting shell body 110 is provided with a mounting cavity, the middle part of the mounting cavity is provided with a first partition plate 120, and the first partition plate 120 is used for dividing the mounting cavity into a first circuit cavity 131 and a second circuit cavity 132; a first circuit cavity cover plate 141 is arranged at the opening of the first circuit cavity 131, and a second circuit cavity cover plate 142 is arranged at the opening of the second circuit cavity 132; a second partition plate 151 is arranged in the middle of the second circuit cavity 132, and a ballast mounting cavity 153 is formed above the second partition plate 151; the ballast 160 is located in the ballast mounting chamber 153, and the ballast 160 is disposed above the second partition 151.

In this embodiment, a power grid side circuit can be disposed in the first circuit cavity 131, and a light source side circuit can be disposed at the lower portion of the first partition plate 120 in the first circuit cavity 131, so that circuit isolation can be preferably achieved, and power consumption safety can be preferably ensured. The first partition 120 is provided to allow the ballast 160 to be preferably disposed at the first partition 120, which allows the ballast 160 to be preferably replaced by directly opening the second circuit chamber cover 142.

Referring to fig. 2, a first circuit chamber cover plate mounting groove 210 for mounting the first circuit chamber cover plate 141 is formed at the opening of the first circuit chamber 131. So that the first circuit chamber cover plate 141 can be preferably installed at the opening of the first circuit chamber 131.

A second circuit chamber cover plate mounting groove 220 for mounting the second circuit chamber cover plate 142 is formed at the opening of the second circuit chamber 132. So that the second circuit chamber cover 142 can be preferably installed at the opening of the second circuit chamber 132.

A second partition installation groove 230 for installing the second partition 151 is formed at an inner wall of the second circuit chamber 132. So that the second partition 151 can be preferably installed at the inner wall of the second circuit chamber 132.

As shown in fig. 3, the lower end surface of the mounting housing 100 is provided with a light source mounting cavity 170. So that the installation of the light source can be preferably facilitated.

In this embodiment, the ballast 160 is detachably fixedly coupled to the second barrier 151 by at least one coupling structure 181. Thereby preferably facilitating quick installation and removal of ballast 160.

In this embodiment, the ballast 160 is electrically connected to the circuits in the first circuit chamber 131 and the second circuit chamber 132 through the circuit connector 182. Thereby preferably facilitating quick installation and removal of ballast 160.

Example 2

This embodiment provides a concrete form of the connection structure 181 used in embodiment 1.

Referring to fig. 4, the connection structure 181 includes a connection socket 410 disposed at the ballast 160 and a connection socket disposed at the mounting case 100, and the connection socket includes a connection socket bottom plate 421, a connection socket outer shell 423, and a connection socket inner core 422.

As shown in fig. 5, the connector 410 includes a cylindrical connector main body 510, one end of the connector main body 510 is connected to the ballast 160, and a cylindrical assembly groove 520 is formed at an end surface of the other end of the connector main body 510; the middle part of the bottom wall of the assembling groove 520 is provided with an installing column 530, and the outer end of the installing column 530 is provided with a connecting insert block 540; the side wall of the assembly groove 520 comprises 4 push blocks 521 which are connected end to end in sequence in the circumferential direction, and the outer end faces of the push blocks 521 are configured to be slopes which gradually decrease in the clockwise direction.

As shown in fig. 6, the connecting socket housing 423 includes a cylindrical connecting socket housing main body 610, and an assembling through hole 620 having a circular cross section is axially formed in the connecting socket housing main body 610; the side wall of the connector main body 510 corresponding to any pushing block 521 is provided with a guide sliding groove 550 along the axial direction, and the inner wall of the assembling through hole 620 corresponding to any guide sliding groove 550 is provided with a guide sliding rail 630 for matching.

As shown in fig. 7 and 8, the connecting seat inner core 422 includes a cylindrical inner core main body 710, 4 slots 720 connected end to end are formed on the upper side wall of the inner core main body 710 in the circumferential direction, and the bottom walls of the slots 720 form inclined planes matched with the outer end faces of the push blocks 521; the upper end face of the inner core main body 710 is provided with a connecting slot 730 used for being matched with the connecting plug block 540, the connecting plug block 540 comprises a plurality of fan-shaped connecting fixture blocks 541 which are uniformly arranged at intervals in the circumferential direction, and the periphery of the connecting slot 730 corresponding to any fan-shaped connecting fixture block 541 is provided with a fan-shaped clamping hole 731; connecting seat shell 423 and connecting seat bottom plate 421 fixed connection, connecting seat inner core 422 is located in connecting seat shell 423, is equipped with a first compression spring between connecting seat inner core 422 and connecting seat bottom plate 421, is equipped with the transition interval between direction slide rail 630 lower extreme and assembly through-hole 620 lower extreme, and the length of transition interval makes draw-in groove 720 card completely go into or break away from direction slide rail 630 at least.

In this embodiment, when the connector 410 is not assembled with the connector, the inner core 422 of the connector has an upward trend under the action of the first compression spring, and the slot 720 can be completely inserted into the guide rail 630, that is, the lower end surface of the guide rail 630 is abutted against the lowest point of the slot 720; with the insertion of the connector 410, the connecting seat core 422 descends, and the engaging groove 720 gradually disengages from the guiding slide rail 630 until completely disengaging, and the connecting block 540 extends into the connecting slot 730; in the process that the connection plug 540 extends into the connection slot 730, the fan-shaped connection fixture block 541 can pass through the fan-shaped fixture hole 731; when the clamping groove 720 is completely separated from the guide sliding rail 630, the connecting seat inner core 422 can rotate counterclockwise by an angle under the matching of the outer end face of the pushing block 521 and the bottom face of the clamping groove 720; then, the external force at the connecting head 410 is removed, the connecting seat inner core 422 can move upwards again under the action of the first compression spring, the connecting seat inner core 422 can be completely clamped into the guide slide rail 630 again as the clamping groove 720 gradually enters the guide slide rail 630, and the connecting seat inner core 422 can rotate for 90 degrees before and after being clamped; at this time, the fan-shaped engaging protrusion 541 is misaligned with the fan-shaped engaging hole 731, so that the connecting head 410 can be better connected to the connecting base.

As described above, when the engaging groove 720 and the guiding rail 630 are completely disengaged and engaged again, the connecting base core 422 rotates 90 ° counterclockwise, so that the connecting and disengaging of the connecting base 410 and the connecting base can be preferably realized by pressing the connecting base 410. Replacement of the ballast 160 can be preferably facilitated by this configuration.

In this embodiment, the number of the fan-shaped connecting blocks 541 is 2, and the central angle of the fan-shaped connecting blocks 541 is 90 °. So that the connection head 410 can be firmly engaged with the connection seat.

In this embodiment, a first compression spring installation groove 810 for being matched with a corresponding end of the first compression spring is formed in the lower end surface of the inner core main body 710. So that the installation of the first compression spring can be preferably facilitated.

Referring to fig. 9, the connecting seat bottom plate 421 includes a connecting seat bottom plate base 910, a connecting seat bottom plate mounting post 920 for cooperating with the connecting seat housing 423 is disposed at the connecting seat bottom plate base 910, and a first compression spring mounting cavity 921 for cooperating with a first compression spring is disposed in the connecting seat bottom plate mounting post 920. So that the assembly of the connecting socket can be preferably facilitated.

In this embodiment, a first compression spring positioning column 930 for inserting into the first compression spring is disposed in the middle of the first compression spring mounting cavity 921. So that the installation of the first compression spring can be preferably facilitated.

In this embodiment, a mounting socket 640 is disposed on the lower end surface of the connecting socket housing body 610, and a mounting socket 922 for matching with the mounting socket 640 is disposed on the connecting socket bottom plate mounting column 920. So that the installation between the coupling holder housing 423 and the coupling holder base plate 421 can be preferably facilitated.

Example 3

The present embodiment provides a ballast for a lamp with an improved connection structure, which includes a connection structure 181 provided between the ballast 160 and the mounting case 100, wherein the connection structure 181 adopts the connection structure 181 of embodiment 2.

Example 4

This embodiment provides a concrete form of the circuit connector 182 used in embodiment 1, wherein the circuit connector 182 includes a connector plug 1000 and a connector socket 1200 for fitting with each other.

As shown in fig. 10, the connector plug 1000 includes a plug carrier, the plug carrier includes a plug carrier substrate 1010, a cylindrical conductive pillar 1020 is disposed in the middle of the upper end surface of the plug carrier substrate 1010, and a first insert ring 1030, a second insert ring 1040 and a third insert ring 1050 are further disposed on the upper end surface of the plug carrier substrate 1010 from inside to outside in sequence concentrically with the conductive pillar 1020.

Referring to fig. 12 and 13, the connector socket 1200 includes a first slot 1210, a second slot 1220, a third slot 1230 and a fourth slot 1240 that are concentrically arranged from inside to outside, and a conductive ring 1410 for cooperating with the conductive post 1020 is disposed on an inner wall of the first slot 1210.

As shown in fig. 11 and 14, the outer wall of the second slot 1220 is provided with a first conductive plate a1420, and the outer wall of the first insert ring 1030 is provided with a first conductive plate B1110 for cooperating with the first conductive plate a 1420; a second conducting strip A1430 is arranged on the inner wall of the third slot 1230, and a second conducting strip B1120 is arranged on the inner wall of the second inserting ring 1040; a third conducting strip A1440 is arranged on the outer wall of the third slot 1230, and a third conducting strip B1130 is arranged on the outer wall of the second inserting ring 1040; a fourth conducting strip A1450 is arranged on the inner wall of the fourth slot 1240, and a fourth conducting strip B1140 is arranged on the inner wall of the third inserting ring 1050; a fifth conductive plate a1460 is disposed on the outer wall of the fourth slot 1240, and a fifth conductive plate B is disposed on the outer wall of the third insert ring 1050.

In this embodiment, the conductive post 1020 and the conductive ring 1410, the first conductive piece a1420 and the first conductive piece B1110, the second conductive piece a1430 and the second conductive piece B1120, the third conductive piece a1440 and the third conductive piece B1130, the fourth conductive piece a1450 and the fourth conductive piece B1140, and the fifth conductive piece a1460 and the fifth conductive piece B can form 6 connection terminals together, and the 6 connection terminals can be used as connection terminals for a power grid side zero line, a power grid side live wire, a power grid side ground wire, a light source side positive electrode, a light source side negative electrode, and a light source side ground wire, respectively, so that the electrical connection between the ballast 160 and the related circuits is preferably realized. Moreover, the above-described structure can preferably facilitate the insertion and removal of the connector plug 1000 and the connector socket 1200, thereby facilitating the replacement of the ballast 160.

Referring to fig. 15, the first slot 1210 has openings at both ends, and the lower end surface of the connector socket 1200 is provided with a switch device 1470 corresponding to the opening of the first slot 1210; the switch device 1470 comprises a cylindrical switch housing 1510, and a switch cavity 1511 with an opening facing the inner hole of the first slot 1210 is arranged in the switch housing 1510; a conductive contact ring 1520 is arranged at the edge of the bottom wall of the switch cavity 1511, a conductive slider 1530 is slidably arranged in the conductive ring 1410, and a second compression spring 1540 is arranged between the conductive slider 1530 and the middle part of the bottom wall of the switch cavity 1511; a conductive ring 1531 is disposed on the outer wall of the lower end of the conductive slider 1530, and the conductive ring 1531 is located between the conductive contact ring 1520 and the lower end of the conductive ring 1410.

In this embodiment, the connection terminal formed by the conductive post 1020 and the conductive ring 1410 can be used for accessing the grid-side live wire, so that when the connector plug 1000 is not inserted into the connector socket 1200, the conductive slider 1530 is separated from the conductive contact ring 1520 by the second compression spring 1540, and the conductive ring 1410 is disconnected from the conductive contact ring 1520, so that the conductive ring 1410 is not electrified; when the connector plug 1000 is inserted into the connector receptacle 1200, the conductive slider 1530 moves downward under the action of the conductive posts 1020 until it abuts against the conductive contact ring 1520, and at this time, the conductive ring 1410 and the conductive contact ring 1520 allow an electrical circuit to be formed between the connector plug 1000 and the connector receptacle 1200. The safety of electricity utilization can be preferably ensured by the above configuration.

Referring to fig. 16, a second compression spring upper mounting cavity 1610 for placing a second compression spring 1540 is disposed on a lower end surface of the conductive slider 1530, and an insulating inner container 1550 is disposed in the second compression spring upper mounting cavity 1610. The installation of the mounting cavity 1610 on the second compression spring can preferably facilitate the installation of the second compression spring 1540, and the insulating inner container 1550 can preferably electrically isolate the second compression spring 1540 from the conductive slider 1530.

Referring to fig. 17, an insulating protection pillar 1710 for inserting into the second compression spring upper mounting cavity 1610 is disposed in the middle of the bottom wall of the switch cavity 1511, and a second compression spring lower mounting cavity 1720 for placing the second compression spring 1540 is disposed in the middle of the insulating protection pillar 1710. The arrangement of the second compression spring lower mounting cavity 1720 can preferably facilitate the arrangement of the second compression spring 1540, and through the cooperation of the insulating protection pillar 1710 and the insulating inner container 1550, the second compression spring 1540 and the conductive slider 1530 can be further electrically isolated from each other.

Example 5

The present embodiment provides an electronic ballast with improved circuit connector, which includes a circuit connector 182 disposed between the ballast 160 and the installation housing 100, the ballast 160 is electrically connected to the circuit located in the installation housing 100 through the circuit connector 182, and the circuit connector 182 adopts the circuit connector 182 of embodiment 3.

Example 6

The present embodiment provides a ballast for a lamp, which includes an electronic ballast mounting structure of embodiment 1 and a connection structure 181 of embodiment 2.

Example 7

The present embodiment provides a ballast for a lamp, which includes an electronic ballast mounting structure of embodiment 1 and a circuit terminal 182 of embodiment 4.

Example 8

The present embodiment provides a ballast for a lamp, which includes an electronic ballast mounting structure of embodiment 1, a connection structure 181 of embodiment 2, and a circuit terminal 182 of embodiment 4.

The present invention and its embodiments have been described above schematically, without limitation, and what is shown in the drawings is only one of the embodiments of the present invention, and the actual structure is not limited thereto. Therefore, if the person skilled in the art receives the teaching, without departing from the spirit of the invention, the person skilled in the art shall not inventively design the similar structural modes and embodiments to the technical solution, but shall fall within the scope of the invention.

Claims (7)

1. Electronic ballast mounting structure, its characterized in that: comprises a mounting case (100), the mounting case (100) comprises a mounting case main body (110); the upper end face of the mounting shell body (110) is provided with a mounting cavity, the middle of the mounting cavity is provided with a first partition plate (120), and the first partition plate (120) is used for dividing the mounting cavity into a first circuit cavity (131) and a second circuit cavity (132); a first circuit cavity cover plate (141) is arranged at the opening of the first circuit cavity (131), and a second circuit cavity cover plate (142) is arranged at the opening of the second circuit cavity (132); a second partition plate (151) is arranged in the middle of the second circuit cavity (132), and a ballast mounting cavity (153) is formed above the second partition plate (151); the ballast (160) is positioned in the ballast mounting cavity (153), and the ballast (160) is arranged above the second partition plate (151);

the ballast is characterized by further comprising a circuit connector (182) arranged between the ballast (160) and the mounting shell (100), wherein the ballast (160) is electrically connected with a circuit positioned in the mounting shell (100) through the circuit connector (182), and the circuit connector (182) comprises a connector plug (1000) and a connector socket (1200) which are matched with each other; the connector plug (1000) comprises a plug bearing seat, the plug bearing seat comprises a plug bearing seat substrate (1010), a cylindrical conductive column (1020) is arranged in the middle of the upper end face of the plug bearing seat substrate (1010), and a first insert ring (1030), a second insert ring (1040) and a third insert ring (1050) are further sequentially arranged on the upper end face of the plug bearing seat substrate (1010) from inside to outside in a concentric mode with the conductive column (1020); the joint socket (1200) comprises a first slot (1210), a second slot (1220), a third slot (1230) and a fourth slot (1240) which are concentrically arranged from inside to outside, and a conducting ring (1410) used for being matched with the conducting post (1020) is arranged on the inner wall of the first slot (1210); a first conducting strip A (1420) is arranged on the outer wall of the second slot (1220), and a first conducting strip B (1110) matched with the first conducting strip A (1420) is arranged on the outer wall of the first insert ring (1030); a second conducting strip A (1430) is arranged on the inner wall of the third slot (1230), and a second conducting strip B (1120) is arranged on the inner wall of the second inserting ring (1040); a third conducting strip A (1440) is arranged on the outer wall of the third slot (1230), and a third conducting strip B (1130) is arranged on the outer wall of the second inserting ring (1040); a fourth conducting strip A (1450) is arranged on the inner wall of the fourth slot (1240), and a fourth conducting strip B (1140) is arranged on the inner wall of the third insert ring (1050); a fifth conducting strip A (1460) is arranged on the outer wall of the fourth slot (1240), and a fifth conducting strip B is arranged on the outer wall of the third inserting ring (1050).

2. The electronic ballast mounting structure according to claim 1, wherein: the lower end face of the mounting shell (100) is provided with a light source mounting cavity (170).

3. The electronic ballast mounting structure according to claim 1, wherein: the ballast (160) is detachably fixedly connected to the second partition (151) by at least one connecting structure (181).

4. The electronic ballast mounting structure according to claim 1, wherein: the ballast (160) is electrically connected to the circuitry located in the first circuit chamber (131) and the second circuit chamber (132) by a circuit connector (182).

5. The electronic ballast mounting structure according to claim 1, wherein: the opening of the first circuit cavity (131) is provided with a first circuit cavity cover plate installation groove (210) for installing a first circuit cavity cover plate (141).

6. The electronic ballast mounting structure according to claim 1, wherein: a second circuit cavity cover plate mounting groove (220) for mounting a second circuit cavity cover plate (142) is formed in the opening of the second circuit cavity (132).

7. The electronic ballast mounting structure according to claim 1, wherein: a second clapboard installing groove (230) used for installing a second clapboard (151) is arranged at the inner wall of the second circuit cavity (132).

Images