Patent Description:
In an existing explosion-proof lamp, assembly and connection (such as a connecting structure) of a mounting cover and a lamp rod thereof usually encounter problems such as a plurality of components, a complex structure, difficult mounting, etc., and inappropriate design results in a problem in which a cable is prone to entanglement during a mounting or removal process of the two. In order to meet various requirements of the explosion-proof lamp in terms of safety performance, such as waterproofing performance, dustproofing performance, etc., an existing connecting structure usually needs to use a plurality of gaskets to achieve this function. In addition, since a connecting member included in the connecting structure is usually mounted in a connecting end of the mounting cover extending from a main body thereof to the lamp rod, part of the mounting process needs to be performed in the connecting end of the mounting cover, thereby increasing operation difficulty of the assembly, and resulting in inconvenience for future maintenance. <CIT> shows an example of such an explosion proof lamp.

On this basis, relevant technicians are committed to designing a connecting assembly for an explosion-proof lamp. The connecting assembly facilitates assembly, thereby effectively reducing the difficulty of the assembly, and therefore eliminating the defects in the prior art.

Therefore, the objective of the present invention is to provide a column-type cable entry assembly for an explosion-proof lamp so as to eliminate the defects in the prior art.

In order to achieve the aforementioned objective, the present invention provides a column-type cable entry assembly for an explosion-proof lamp as set forth in claim <NUM>. Further embodiments are inter alia disclosed in the dependent claims.

In particular, the cable entry assembly is used to connect a cover and a rod of the explosion-proof lamp and to allow a cable for power transmission to pass therethrough and the cable entry assembly comprises: a first connecting member, one end of the first connecting member configured to be joined to the cover; a positioning member, wherein the positioning member is configured to be an explosion-proof cable gland and comprises: a connecting portion configured to be joined to the first connecting member, a sealing portion abutting to the connecting portion, and a locking portion configured to disengage from or lock the sealing portion so as to release or lock and position the cable thus allowing not locking the cable during joining of the first connecting member to the cover, and locking and positioning the cable after the first connecting member is joined to the cover so as to prevent the cable from rotating during joining of the positioning member to the first connecting member and during the joining of the first connecting member to the cover, wherein the locking portion is not joined to the first connecting member; and a second connecting member configured to be connected to the other end of the first connecting member so as to cause the positioning member to be sleeved therein and the first connecting member to be exposed.

In a preferred embodiment, the second connecting member is configured to be column-shaped; the second connecting member is provided with a first positioning hole and a second positioning hole on a peripheral surface thereof; the first positioning hole and the second positioning hole are respectively close to two ends of the second connecting member; the first connecting member and the second connecting member are fixed to each other by causing a fastener to pass through the first positioning hole and abut to the first connecting member; the rod is inserted into the second connecting member, and the rod and the second connecting member are fixed to each other by causing a fastener to pass through the second positioning hole and abut to the rod, so as to prevent axial and radial displacement from occurring between the second connecting member and the first connecting member and between the second connecting member and the rod.

In a preferred embodiment, the first positioning hole and the second positioning hole are circumferentially and evenly arranged on the peripheral surface of the second connecting member.

In a preferred embodiment, the first positioning hole and the second positioning hole are coaxially arranged on the peripheral surface of the second connecting member.

In a preferred embodiment, the cover has an extension portion protruding from a main body thereof towards the second connecting member; the extension portion is provided with a third positioning hole; the first connecting member and the cover are fixed to each other by causing a fastener to pass through the third positioning hole so as to prevent axial and radial displacement of the cover relative to the first connecting member.

In a preferred embodiment, one end of the first connecting member is provided with a first thread so as to be threadedly coupled to the cover; the other end of the first connecting member is provided with a second thread so as to be threadedly coupled to an end of the second connecting member; the other end of the first connecting member is further provided with a third thread so as to be threadedly coupled to the positioning member.

In a preferred embodiment, the first connecting member is configured to be provided with a gripping portion on a peripheral surface thereof so as to allow coupling and mounting of the explosion-proof lamp.

In a preferred embodiment, the gripping portion is configured to be an annular flange arranged on the peripheral surface, and the flange has at least one pair of flat surfaces parallel to each other on the peripheral surface.

In a preferred embodiment, the gripping portion is configured to be at least one pair of flat surfaces arranged on the peripheral surface, and the at least one pair of flat surfaces correspond to and are parallel each other.

Part of the other features and advantages of the present invention will become apparent to those skilled in the art after reading of the present invention, and the rest will be described in the following embodiments with reference to the accompanying drawings.

Embodiments of the present invention are described in detail in the following with reference to the accompanying drawings, wherein:.

<NUM> - explosion-proof lamp; <NUM> - cover; <NUM> - extension portion; 100a - third positioning hole; <NUM> - cable entry assembly; <NUM> - first connecting member; <NUM> - positioning member; 122a - connecting portion; 122b - locking portion; <NUM> - second connecting member; 120a - gripping portion; 120b - flat surface; 124a - first positioning hole; 124b - second positioning hole; 124c - fastener.

Exemplary schemes of an explosion-proof lamp according to the present invention will be described in detail with reference to the accompanying drawings. Although providing the accompanying drawings is to present a plurality of implementations of the present invention, the accompanying drawings do not need to be drawn according to the size of specific implementation schemes, and certain features can be enlarged, removed, or locally exploded to better illustrate and explain the disclosure of the present invention. Part of members in the accompanying drawings can be positionally adjusted according to actual requirements without affecting the technical effect. In the description, the term "in the accompanying drawings" or similar terms do not necessarily refer to all of the accompanying drawings or examples.

Certain directional terms used in the following to describe the accompanying drawings, such as "in," "out," "upper," and "lower," and other directional terms are construed as having normal meanings thereof and refer to those directions involved when the accompanying drawings are viewed normally. Unless otherwise specified, the directional terms in the description are substantially in accord with conventional directions understood by those skilled in the art.

The terms "first," "first one," "second," and "second one" and similar terms used in the present invention do not indicate any sequence, number, or importance in the present invention, but are used to distinguish one component from other components.

The terms "join" and "connect" and similar terms used in the present invention refer to two components being indirectly connected to each other by an intermediate layer (such as an adhesive or a solder) or an intermediate member (such as a connection member or a transition member), and also refer to two components being directly connected to each other without any intermediate layer (such as an adhesive or a solder) or any intermediate member (such as a connection member or a transition member).

<FIG> show a column-type cable entry assembly <NUM> for an explosion-proof lamp provided by the present invention. Specifically, as shown in <FIG>, the explosion-proof lamp <NUM> includes a cover <NUM>, a cable entry assembly <NUM>, and a rod. The cover <NUM> is mainly used to arrange or mount a lamp body. The cable entry assembly <NUM> is (detachably) joined to the cover <NUM>. The cable entry assembly <NUM> leads a cable to the interior thereof so as to guide and protect the cable. The cable is always connected to the cover <NUM>. The rod is connected to the cover <NUM> by being (detachably) joined to the cable entry assembly <NUM>. The rod is used to support the cover <NUM> (especially after the lamp body is arranged or mounted) so as to support the cover <NUM> to a certain height to meet lighting requirements of a use scenario.

As shown in <FIG>, the cable entry assembly <NUM> includes a first connecting member <NUM>, a second connecting member <NUM>, and a positioning member <NUM>. Taking a direction in which the rod is upright as a reference, in an axial direction of the rod, an upper end of the first connecting member <NUM> is joined to the cover <NUM>. The cover <NUM> is substantially a circular structure, and a connecting portion extends radially from the cover <NUM>. The connecting portion is usually bent by a certain angle. A side of the bent connecting portion facing the rod is used to connect the first connecting member <NUM>. A lower end of the first connecting member <NUM> is connected to (an upper end of) the positioning member <NUM>. After the positioning member <NUM> is joined to the first connecting member <NUM>, the first connecting member <NUM> is then joined to the cover <NUM>. During the joining of the first connecting member <NUM> to the cover, the positioning member <NUM> does not lock the cable, and after the two are joined to each other, the positioning member <NUM> locks and positions the cable. In this period, rotation caused by the joining of the positioning member <NUM> to the first connecting member <NUM> and the joining of the first connecting member <NUM> to the cover <NUM> does not cause the cable to rotate, and this prevents the cable from becoming entangled during assembly of the explosion-proof lamp. An upper end of the second connecting member <NUM> is connected to the lower end of the first connecting member <NUM> so as to cause the positioning member <NUM> to be sleeved therein and expose the first connecting member <NUM>, and this facilitates use of a tool to rotate the first connecting member.

The positioning member <NUM> used herein is an explosion-proof cable gland. The cable gland is applicable to hazardous environments, and meets explosion-proof certification requirements. The cable gland is an explosion-proof accessory applicable to a demanding cable. The cable gland can fix the position of and seal the cable, has superior flameproof performance and a safe and reliable structure, and facilitates mounting. The positioning member <NUM> includes a connecting portion 122a, a sealing portion, and a locking portion 122b. The connecting portion 122a is joined to the first connecting member. The sealing portion abuts to the connecting portion 122a. The locking portion 122b usually achieves locking by acting on the sealing portion. For example, when the locking portion 122b performs locking, the sealing portion deforms to fix the cable and seal the same, and when the locking portion 122b does not perform locking, the sealing portion restores the shape and releases the cable so that the cable can move axially relative to the positioning member.

The first connecting member <NUM>, the positioning member <NUM>, and the second connecting member <NUM> are all threadedly connected to each other. The first connecting member <NUM> is configured to be column-shaped, and optionally the upper end and the lower end thereof form a tapered structure. The first connecting member <NUM> is internally hollow so as to accommodate the positioning member <NUM>, allow the cable to pass therethrough, and guide the cable. Similar to the first connecting member <NUM>, the second connecting member <NUM> is also configured to be a hollow column-type structure. After being connected to the first connecting member <NUM>, the second connecting member <NUM> can accommodate a lower portion of the first connecting member <NUM>.

Exemplarily, in order to further fix and limit respective positions of the first connecting member <NUM>, the second connecting member <NUM>, and the cover <NUM> so as to prevent axial movement and radial rotation from occurring therebetween, the second connecting member <NUM> is further provided with positioning holes on a peripheral surface. The positioning holes mainly include a first positioning hole 124a located at the upper end of the second connecting member <NUM> and a second positioning hole 124b located at a lower end of the second connecting member <NUM>. The first positioning hole 124a at the upper end of the second connecting member <NUM> is used to limit relative rotation and axial movement between the second connecting member <NUM> and the first connecting member <NUM>. The second positioning hole 124b at the lower end of the second connecting member <NUM> is used to limit relative rotation and axial movement between the second connecting member <NUM> and the rod. The numbers of first positioning holes 124a and second positioning holes 124b are respectively plural, for example, three as shown in <FIG>. However, those skilled in the art can understand that the number of positioning holes can be adjusted according to actual requirements. Fixing of the second connecting member <NUM> to the first connecting member <NUM> is achieved by causing a fastener to pass through the first positioning hole 124a and abut to the first connecting member <NUM>, and fixing of the second connecting member <NUM> to the rod is achieved by causing a fastener to pass through the second positioning hole 124b and abut to the rod.

Exemplarily, the first positioning hole 124a and the second positioning hole 124b may be arranged with reference to the following manner. Taking <FIG> as an example, three first positioning holes 124a and three second positioning holes 124b are respectively circumferentially evenly distributed on the peripheral surface of the second connecting member <NUM>. That is, a plurality of first positioning holes 124a are circumferentially co-circularly arranged, and similarly, a plurality of second positioning holes 124b are also circumferentially co-circularly arranged. In addition, the first positioning hole 124a and the second positioning hole 124b are coaxially arranged on the second connecting member <NUM>, and vertically correspond to each other. Certainly, those skilled in the art can understand that the above arrangement is merely exemplary, and can also conceive of other possible arrangements.

In addition to the aforementioned further position-limiting and fixing between the two connecting members, the present invention further provides position-limiting and fixing between the cover <NUM> and the first connecting member <NUM>. Specifically, the cover <NUM> has an extension portion protruding from a main body thereof towards a lower end. The extension portion is provided with a third positioning hole 124c. Similar to the connection between the aforementioned two connecting members, the cover <NUM> and the first connecting member <NUM> are fixed to each other by causing a fastener to pass through the third positioning hole 124c and abut to the first connecting member <NUM>. Advantageously, this prevents axial movement and radial rotation that may occur between the cover <NUM> and the first connecting member <NUM>.

The aforementioned fixing of the first connecting member <NUM> to the second connecting member <NUM> is described in detailed below. Specifically, the connection between the first connecting member <NUM> and the second connecting member <NUM> is fixed by using the aforementioned anti-rotation position-limiting method. That is, after the second connecting member <NUM> is threadedly connected to the first connecting member <NUM>, anti-rotation position-limiting of the two is achieved by causing the fastener configured to be a locking screw to pass through the first positioning hole 124a at the upper end of the second connecting member <NUM> and causing the locking screw to tightly abut to the first connecting member <NUM>.

The aforementioned fixing of the rod to the second connecting member <NUM> is described in detailed below. Specifically, the rod is usually relatively long in order to easily support the explosion-proof lamp <NUM> to a relatively high position so as to meet lighting requirements. The rod is inserted into a relatively deep position of the second connecting member <NUM> from the lower end of the second connecting member <NUM>. After the rod is inserted into an appropriate position in the second connecting member <NUM>, the fastener 124c (as shown in <FIG>) is inserted into the second positioning hole 124b and is caused to abut to the peripheral surface of the second connecting member <NUM> so as to limit or prevent relative rotation between the rod and the second connecting member <NUM>. The positioning hole 124a is usually a through-hole perpendicular to the peripheral surface of the second connecting member <NUM>. Certainly, it is understandable that those skilled in the art can adaptively adjust the number, the positions, and the arrangement of positioning holes 124a according to experience. However, these adjustments are all obtained on the basis of the teaching provided by the present invention, and do not depart from the protection scope of the present invention.

As an example, the first connecting member <NUM> is provided with a first thread (for example, an external thread) and a second thread (for example, an internal thread) respectively at two ends on the peripheral surface, and is internally provided with a third thread (for example, an internal thread) at the lower end (namely, an end facing the cable gland). The connecting portion of the cover <NUM> is provided with a coupling thread on an end portion facing the first connecting member <NUM> so as to be threadedly coupled to the first connecting member <NUM>. The positioning member <NUM> (cable gland) is threadedly connected, by means of a coupling thread provided on an upper end portion, to the third thread provided at the lower end of the first connecting member <NUM>. The second connecting member <NUM> (also referred to as a rod adapter) is provided with a coupling thread on an upper end portion so as to be threadedly connected to the second thread at the lower end of the first connecting member <NUM>. In the interior of the second connecting member <NUM>, except for the second internal thread provided on the upper portion, the other portion may be an unthreaded hole. After the connection between the second connecting member <NUM> and the first connecting member <NUM> is completed, the second connecting member <NUM> causes the positioning member <NUM> and part of the first connecting member <NUM> to be sleeved therein. Since the connections between the first connecting member <NUM>, the positioning member <NUM>, and the second connecting member <NUM> are appropriately designed, during mounting of the aforementioned components, the cable does not need to be rotated, thereby effectively avoiding the problem in which a cable becomes entangled during rotation due to that the cable is overly long. The aforementioned thread may be, for example, an NPT <NUM><NUM>/<NUM>thread (an American-standard <NUM>-degree taper pipe thread), and has good sealing performance.

After being assembled to the cover and the rod, the aforementioned cable entry assembly can effectively prevent external gas, dust, etc. from entering the structure and affecting use performance and safety performance thereof. Sealing performed by the positioning member, namely the cable gland (mainly referring to the explosion-proof cable gland), on the cable can enable the structure provided herein to be applicable to hazardous explosive environments, for example, to be applicable to the petrochemical industry. Generally, depending on states of matter present in locations, hazardous locations are mainly divided into explosive gas environments and combustible dust environments. Depending on duration of hazardous matter in a location, a hazardous location including matter in two different states is divided into three regions. Taking the explosive gas environment as an example, depending on the frequency and duration of existence of an explosive gas mixture, the explosive gas environment is divided into three regions in China. These three regions are respectively region <NUM>, region <NUM>, and region <NUM>, and hazard levels thereof are in a descending order. The explosion-proof cable gland described herein is applicable to region <NUM>.

As shown in <FIG>, the first connecting member <NUM> is provided with a gripping portion 120a on a peripheral surface thereof. The gripping portion 120a is mainly used to allow an operator to readily use a tool to grip the same so as to complete coupling and mounting of the explosion-proof lamp. Generally, during a mounting or removal process, the operator uses a tool such as a wrench to grip the gripping portion 120a of the first connecting member <NUM> so as to rotate the same.

In an embodiment, the gripping portion 120a may be an annular flange arranged on the peripheral surface of the first connecting member <NUM>. The annular flange substantially surrounds the first connecting member <NUM>, and is formed by extending radially outwards from a surface of the first connecting member <NUM>. A surface of the flange is formed by a plurality of flat surfaces 120b, and the plurality of flat surfaces 120b are in pairs. For example, taking a diameter of the flange as a reference, one pair of flat surfaces 120b are distributed at two ends of the diameter of the flange on a peripheral surface of the flange. That is, at least one pair of flat surfaces 120b corresponding to each other on the flange is present on the peripheral surface of the flange, so that the operator can readily use a tool such as a wrench to grip the flange so as to rotate the same.

In another embodiment, the gripping portion 120a may be at least one pair of flanges arranged on the peripheral surface of the first connecting member <NUM>. For example, the flange does not form any continuous annular structure, but extends radially from the surface of the first connecting member <NUM> to form a boss. The surface of the flange, especially a surface located away from the peripheral surface of the first connecting member <NUM>, forms a flat surface 120b. Flanges in each of one or more pairs of flanges on the first connecting member <NUM> are both arranged along the same diameter of the first connecting member <NUM>, and respective flat surfaces 120b of respective surfaces of the paired flanges are parallel to each other, so that the operator can readily use a tool such as a wrench to grip the flange so as to rotate the same.

In yet another embodiment, referring again to <FIG> and <FIG>, the gripping portion 120a may be at least one pair of flat surfaces 120b directly arranged on the peripheral surface of the first connecting member <NUM>. Similar to the arrangement of the flange, the flat surfaces 120b directly arranged on the peripheral surface of the first connecting member <NUM> also correspond to each other and are parallel to each other. As described above, the advantage of such arrangement is that the operator can readily use a tool such as a wrench to grip the flat surface so as to rotate the first connecting member <NUM>, so that the first connecting member <NUM> is connected to or disengages from other structures, such as the cover <NUM>.

Preferably, the aforementioned column-type second connecting member <NUM> may be a polygonal column-type structure. In other words, the surface of the second connecting member <NUM> may include at least one pair of flat surfaces 120b. As shown in <FIG> and <FIG>, flat surfaces 120b of the at least one pair of flat surfaces 120b are opposite each other, that is, the flat surfaces 120b of the at least one pair of flat surfaces 120b are arranged at two ends of the diameter of the second connecting member <NUM> and are parallel to each other. The objective of such configuration is also similar to the objective of providing the gripping portion 120a on the first connecting member <NUM> described above, and such configuration allows the operator to readily rotate the second connecting member <NUM>. Similar to the first connecting member <NUM>, the second connecting member <NUM> may also be optionally provided with a flange or another protruding gripping portion 120a. However, such configuration will be appropriately adjusted according to ease of operation and machining costs. Certainly, those skilled in the art can expect other possible alternatives after learning the technical solution of the present application. However, none of modifications or substitutions made thereto departs from the protection scope of the present invention.

Regarding the mounting process of the explosion-proof lamp <NUM> provided herein, for ease of description and in order to highlight key points, only mounting of the cable entry assembly <NUM> to the cover <NUM> and the rod is described herein; other possible mounting steps involved in this process may be implemented with reference to the prior art or are steps known to those skilled in the art, and are therefore not repeatedly described herein.

At a mounting site, components to be mounted are prepared, and mainly include the cover <NUM>, the first connecting member <NUM>, the positioning member <NUM>, the cable, the second connecting member <NUM>, and the rod. The positioning member <NUM>, namely the explosion-proof cable gland, meets explosion-proof standards for the use environment, and acquires relevant explosion-proof certification. The explosion-proof cable gland is used to fasten and seal the cable. The fastening is mainly implemented by locking the cable by means of the cable gland so that the cable does not move axially, and does not rotate radially, thereby ensuring that the connection of the cable is normal. The sealing is mainly implemented in that dust, moisture, etc. are isolated and blocked in the use environment so as to protect the cable. The explosion-proof cable gland described herein is widely applicable to the petroleum industry, the chemical industry, and other locations requiring electrical safety and explosion proofing.

After the cable gland is sleeved on the cable and when the cable is not locked, the connecting portion 122a of the cable gland is connected to the first connecting member <NUM>. During this period, the cable passes through the first connecting member <NUM>, and the cable gland is coupled and connected, by means of a coupling thread provided at an upper end thereof, to the third thread provided at the lower end of the first connecting member <NUM> so that the two are fixed to each other.

Then, the first connecting member <NUM> is connected to the cover <NUM>, and the cover <NUM> is coupled and connected, by means of a coupling thread thereof, to the first thread provided at the upper end of the first connecting member <NUM> so that the two are fixed to each other. The third positioning hole 100a on the extension portion <NUM> at the lower end of the cover <NUM> is coupled to the fastener 124c, and the fastener 124c abuts to the first connecting member <NUM>, so that respective positions of the cover <NUM> and the first connecting member <NUM> are limited. Then, the locking portion 122b of the cable gland is caused to act on the sealing portion so as to lock the cable; then, the second connecting member <NUM> is connected to the first connecting member <NUM>, and the second connecting member <NUM> is coupled and connected, by means of the coupling thread provided at the upper end thereof, to the second thread provided at the lower end of the first connecting member <NUM>, so that the two are fixed to each other. In addition, the first positioning hole 124a provided on the peripheral surface at the upper end of the second connecting member <NUM> is coupled to the fastener 124c, and the fastener 124c abuts to the first connecting member 124a, so that respective positions of the two connecting members are limited. Those skilled in the art can conceive that the aforementioned threaded connection is achieved by means of connection between an internal thread and an external thread of two components. Certainly, the internal thread and the external thread may be interchangeable, and this can be adaptively adjusted in consideration of machining costs and ease of operation.

Then, the rod is inserted into the second connecting member <NUM>, and after the rod reaches a pre-configured position in the second connecting member <NUM> (after mounting is completed, the rod supports a position at a required height on the lamp), the fastener 124c is aligned with and inserted into the second positioning hole 124b provided on the second connecting member <NUM>, so that the fastener 124c tightly abuts to the rod. The coupling between the fastener 124c and the positioning hole achieves anti-rotation position-limiting between components connected to each other, and prevents axial movement and radial rotation between the components connected to each other.

During the aforementioned mounting process, the positioning member <NUM> locks the cable only after the first connecting member <NUM> is connected to the cover <NUM> so as to prevent the cable from being entangled in preceding mounting steps, thereby improving on-site assembly efficiency and ease of operation.

After using the column-type cable entry assembly provided herein to complete the assembly of the explosion-proof lamp, the inventor conducted performance tests on the assembled explosion-proof lamp, the tests including dustproofing and waterproofing performance tests. A test result indicates that no dust or moisture can enter or permeate into the aforementioned explosion-proof lamp, and therefore the explosion-proof lamp has excellent dustproofing and waterproofing performance.

The column-type assembly provided herein connects the rod and the cover. In addition, the appropriate design of the column-type assembly simplifies mounting steps of the explosion-proof lamp, and avoids the problem in the existing design in which a cable is prone to entanglement during assembly and connection of various components, thereby effectively improving assembly efficiency, and improving user experience. However, those skilled in the art can expect that the column-type assembly provided by the present invention is applicable to the explosion-proof lamp, and is also applicable to any other vertical lamp. If the column-type assembly is applied to another vertical lamp, then those skilled in the art can adjust and replace, according to experience, components involved therein. For example, it is not necessary to use an explosion-proof cable gland, and a cable gland applicable to a corresponding environment is selected, and so on.

The column-type cable entry assembly provided by the present invention has an appropriate structure and arrangement, and therefore does not need a plurality of additional components for structural sealing, thereby reducing costs and simplifying mounting steps. In addition, during assembly, a cable no longer needs to rotate together with components attached thereto, thereby solving the technical problem in the prior art in which a long cable is prone to entanglement. Moreover, the column-type cable entry assembly also has good and stable waterproofing and dustproofing performance, improves assembly efficiency, and ensures the safety performance of a product. Further, after the first connecting member is connected to the cover, most of the main body is still exposed, so that a user can readily access and operate the same, thereby also reducing the difficulty of operation performed on the structure, and providing good experience to the user.

Claim 1:
A column-type cable entry assembly (<NUM>) for an explosion-proof lamp, the cable entry assembly (<NUM>) being used to connect a cover (<NUM>) and a rod of the explosion-proof lamp and to allow a cable for power transmission to pass therethrough, characterized by comprising:
a first connecting member (<NUM>), the first connecting member (<NUM>) having one end configured to be joined to the cover (<NUM>);
a positioning member (<NUM>), wherein the positioning member (<NUM>) is configured to be an explosion-proof cable gland, and the positioning member (<NUM>) comprises:
a connecting portion (122a), the connecting portion (122a) being configured to be joined to the first connecting member (<NUM>);
a sealing portion, the sealing portion abutting to the connecting portion (122a); and
a locking portion (122b), the locking portion (122b) being configured to disengage from or lock the sealing portion so as to release or lock and position the cable thus allowing not locking the cable during joining of the first connecting member (<NUM>) to the cover (<NUM>), and locking and positioning the cable after the first connecting member (<NUM>) is joined to the cover (<NUM>) so as to prevent the cable from rotating during joining of the positioning member (<NUM>) to the first connecting member (<NUM>) and during the joining of the first connecting member (<NUM>) to the cover (<NUM>), and the locking portion (122b) being not joined to the first connecting member (<NUM>); and
a second connecting member (<NUM>), the second connecting member (<NUM>) being configured to be connected to the other end of the first connecting member (<NUM>) so as to cause the positioning member (<NUM>) to be sleeved therein and the first connecting member (<NUM>) to be exposed.