CN220604226U - Daylighting analogue means for architectural design - Google Patents

Abstract

The utility model relates to the field of building design, in particular to a lighting simulation device for building design. The intelligent fluorescent lamp comprises a base, a simulation table and a fluorescent lamp, wherein the simulation table is fixedly connected with the upper surface of the base, the adjustment structure is positioned on the simulation table and comprises two sliding plates, and the arc surface of the simulation table is slidably connected with the two sliding plates. The lighting simulation device for the architectural design provided by the utility model has the advantages that the simulated prop is firstly placed on the simulation platform, the rotation adjusting rod can enable the fluorescent lamp to do arc track movement above the prop, the connecting frame can be rotated along the arc surface of the simulation platform, the facing direction of the prop relative to the fluorescent lamp can be adjusted without frequently moving the prop, the simulated lighting height of the fluorescent lamp can be changed by rotating the auxiliary rod, the round rod can be moved along the connecting frame to further change the simulated lighting angle of the fluorescent lamp, the operation is simple and convenient, the lighting simulation effect is good, and the lighting simulation device is convenient to operate.

Description

Daylighting analogue means for architectural design

Technical Field

The utility model relates to the field of building design, in particular to a lighting simulation device for building design.

Background

The lighting simulation device consists of a simulation platform and a light source, and in the building design, the lighting simulation is carried out on a building model, data are recorded and improved, so that the lighting problem of the building is continuously improved.

The utility model of prior art such as CN217004191U discloses a daylighting simulator for architectural design, the utility model sets up the track board between the platform and the locating piece are placed at the base top, through rotating the platform of placing, and the track board carries out inclination adjustment, can adjust according to the activity orbit of the position of building and sunshine under different seasons, the practicality is higher, in addition slide on the track board through the daylighting lamp, can be according to the position that the sunshine is located in the control day, ensured the simulation effect to the architectural daylighting, including the base, the top of base rotates and installs the platform of placing, the inside of base is provided with rotary mechanism, the bilateral symmetry at base top is provided with the locating piece, rotates between two sets of locating pieces and installs the track board, the inside of locating piece all is provided with positioning mechanism, the spout has been seted up on the track board.

With respect to the above and related art, the inventors believe that there are often the following drawbacks: in the use, can't finely tune the illumination height of light source according to actual demand to lead to daylighting simulation error great.

Therefore, it is necessary to provide a new lighting simulation device for architectural design to solve the above technical problems.

Disclosure of Invention

In order to solve the technical problems, the lighting simulation device for architectural design provided by the utility model comprises: the fluorescent lamp comprises a base, a simulation table and a fluorescent lamp, wherein the simulation table is fixedly connected to the upper surface of the base;

the adjusting structure is positioned on the simulation platform and comprises two sliding plates, the arc surface of the simulation platform is slidably connected with two sliding plates, a fixedly connected adjusting frame is arranged on one side, far away from the simulation platform, of each sliding plate, a fixedly connected fixing block is arranged on one side, far away from the sliding plates, of each adjusting frame, a screw is inserted into the internal threads of each fixing block, an auxiliary rod is rotatably connected inside each adjusting frame, an adjusting plate is slidably connected inside each adjusting frame, the adjusting plate is in threaded connection with the auxiliary rod, an adjusting rod is rotatably connected on one side, far away from the simulation platform, of each adjusting plate, a fixedly connected connecting frame is arranged on the arc surface of each adjusting rod, a round rod is slidably connected on the inner wall of each connecting frame, a handle is arranged on the upper surface of each round rod, a clamping ring is in threaded connection with the arc surface of each round rod, and the lower surface of each round rod is fixedly connected with a fluorescent lamp;

the auxiliary structure is positioned on the connecting frame;

the effects achieved by the components are as follows: the simulation prop is placed on the simulation platform, the rotation adjusting rod can enable the fluorescent lamp to do arc track movement above the prop, lighting simulation is achieved, the connecting frame can be rotated along the arc surface of the simulation platform, the facing direction of the prop relative to the fluorescent lamp can be changed without frequently moving the prop, the simulation irradiation height of the fluorescent lamp can be changed by rotating the auxiliary rod, the round rod can be moved along the connecting frame, the simulation irradiation angle of the fluorescent lamp can be changed, operation is simple and convenient, multi-direction adjustment can be achieved, and lighting simulation effect is good.

Preferably, an auxiliary groove is formed in the upper surface of the base, and a plurality of anti-slip protrusions are mounted on the inner wall of the auxiliary groove.

The effects achieved by the components are as follows: the friction between the screw rod and the base is increased through the auxiliary groove, so that the limiting effect of the screw rod is better.

Preferably, the arc surface of the adjusting rod is sleeved with a coil spring, and two ends of the coil spring are fixedly connected with the adjusting plate and the connecting frame respectively.

The effects achieved by the components are as follows: when the connecting frame rotates, the coil spring always gives a torsion force to the connecting frame, so that the connecting frame is more stable when rotating.

Preferably, the upper surface of the simulation platform is provided with a fixedly connected anti-slip pad, and one side of the anti-slip pad, which is far away from the simulation platform, is provided with a plurality of anti-slip patterns.

The effects achieved by the components are as follows: the friction between the simulation platform and the simulation prop is increased through the anti-slip pad, so that the simulation prop is prevented from sliding on the simulation platform.

Preferably, the auxiliary structure comprises a clamping plate and a supporting frame, two clamping plates are abutted to two sides of the connecting frame, a fixedly connected spring is arranged on one side, far away from the connecting frame, of the clamping plate, one end, far away from the clamping plate, of the spring is fixedly connected with the supporting frame, and a fixedly connected protective cover is arranged at the lower end of the supporting frame.

The effects achieved by the components are as follows: when the device is not used for a long time, the protective cover is moved to surround the fluorescent lamp, and then the clamping plate is operated, so that the clamping plate is fixed on the connecting frame, the protective cover is fixed in position, the fluorescent lamp is protected, and the fluorescent lamp is prevented from being damaged due to false touch.

Preferably, a rubber pad which is fixedly connected is arranged on one side, close to the connecting frame, of the clamping plate.

The effects achieved by the components are as follows: the abrasion of the clamping plates to the connecting frame is reduced through the rubber pad, and the service life is prolonged.

Preferably, a limiting rod which is fixedly connected is arranged on one side, far away from the connecting frame, of the clamping plate, and the limiting rod is in sliding connection with the supporting frame.

The effects achieved by the components are as follows: the limiting rod is used for limiting the moving direction of the clamping plate, so that the clamping plate is prevented from shifting.

Compared with the related art, the lighting simulation device for the building design has the following beneficial effects:

the utility model provides a lighting simulation device for architectural design, when lighting simulation is needed, firstly, a building model is placed on a simulation platform, a screw rod is rotated, the screw rod is far away from a base by virtue of threads, at the moment, an adjusting frame can be rotated along the arc surface of the simulation platform, the adjusting frame drives the connecting frame to rotate, the connecting frame is rotated to a proper position according to one surface of the building model compared with the designated direction of the fluorescent lamp, the screw rod is rotated in the opposite direction to enable the screw rod to abut against the base, the adjusting frame is fixed in position, after the building model is adjusted in the opposite direction compared with the facing direction of the fluorescent lamp, an auxiliary rod is rotated, an adjusting plate slides out of the adjusting frame along the arc surface of the auxiliary rod by virtue of threads, the height of a day-turning lamp is changed, only a handle is rotated while the clamping ring is moved along the direction away from the connecting frame by virtue of threads, at the moment, the fluorescent lamp can be moved along the connecting frame, the angle of the fluorescent lamp is adjusted, the fluorescent lamp is simulated, the fluorescent lamp is further, the connecting frame is rotated according to the opposite direction of the clamping ring, after the position of the fluorescent lamp is fixed on the connecting frame, the fluorescent lamp is adjusted in the opposite direction, the adjusting rod is rotated, the connecting frame is driven to rotate, the fluorescent lamp is enabled to move along the arc track curve, the arc surface of the building model, the simulated lamp is moved along the arc surface, the arc surface is changed, the simulated arc surface is changed, the angle can be changed, and the lighting effect can be changed, and the lighting simulation device can be changed conveniently, and the lighting simulation device can be rotated along the arc plane, and can be changed conveniently.

When the fluorescent lamp needs to be protected, the two clamping plates are moved towards the direction away from each other, the spring is in a compressed state, the protective cover is operated to surround the fluorescent lamp from bottom to top, the clamping plates are loosened, the clamping plates move towards the direction close to the connecting frame under the action of elastic force of the spring, the two clamping plates are clamped on the two sides of the connecting frame, the protective cover is fixed, the protective cover is moved to surround the fluorescent lamp after adjustment, when the fluorescent lamp is not used for a long time, the clamping plates are operated, and the clamping plates are fixed on the connecting frame, so that the protective cover is fixed in position, the fluorescent lamp is protected, and damage to the fluorescent lamp due to false touch is prevented.

Drawings

FIG. 1 is a schematic diagram of a structure provided by the present utility model;

FIG. 2 is a schematic structural view of the adjustment structure shown in FIG. 1;

FIG. 3 is an enlarged view at A of FIG. 2;

FIG. 4 is an enlarged view at B of FIG. 2;

FIG. 5 is a partial schematic view of the adjustment structure shown in FIG. 2;

FIG. 6 is a schematic view of the auxiliary structure shown in FIG. 1;

fig. 7 is an enlarged view at C of fig. 6.

Reference numerals in the drawings: 1. a base; 2. a simulation station; 3. a fluorescent lamp; 4. an adjustment structure; 401. a slide plate; 402. an adjusting frame; 403. a fixed block; 404. a screw; 405. an auxiliary groove; 406. an auxiliary lever; 407. an adjusting plate; 408. an adjusting rod; 409. a connection frame; 410. a coil spring; 411. a round bar; 412. a handle; 413. a clamping ring; 414. an anti-slip pad; 5. an auxiliary structure; 51. a clamping plate; 52. a spring; 53. a rubber pad; 54. a limit rod; 55. a support frame; 56. and a protective cover.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Specific implementations of the utility model are described in detail below in connection with specific embodiments.

Referring to fig. 1 to 7, a lighting simulation device for architectural design provided by an embodiment of the present utility model includes: the fluorescent lamp comprises a base 1, a simulation platform 2 and a fluorescent lamp 3, wherein the simulation platform 2 which is fixedly connected is arranged on the upper surface of the base 1;

in the embodiment of the present utility model, referring to fig. 2 to 5, an adjusting structure 4 is shown, the adjusting structure 4 is located on a simulation platform 2, the adjusting structure 4 includes two sliding plates 401, an arc surface of the simulation platform 2 is slidably connected with the two sliding plates 401, a fixedly connected adjusting frame 402 is installed on one side of the sliding plates 401 away from the simulation platform 2, a fixedly connected fixing block 403 is installed on one side of the adjusting frame 402 away from the sliding plates 401, a screw 404 is inserted into an internal thread of the fixing block 403, an auxiliary rod 406 is rotatably connected to the inside of the adjusting frame 402, an adjusting plate 407 is slidably connected to the inside of the adjusting frame 402, the adjusting plate 407 is in threaded connection with the auxiliary rod 406, an adjusting rod 408 is rotatably connected to one side of the adjusting plate 407 away from the simulation platform 2, a fixedly connected connecting frame 409 is installed on the arc surface of the adjusting rod 408, a round rod 411 is slidably connected to an inner wall of the connecting frame 409, a fixedly connected handle 412 is installed on the upper surface of the round rod 411, the circular arc surface of the round rod 411 is in threaded connection with the clamping ring 413, the lower surface of the round rod 411 is fixedly connected with the fluorescent lamp 3, the simulated prop is firstly arranged on the simulation platform 2, the rotation adjusting rod 408 can enable the fluorescent lamp 3 to do arc track motion above the prop so as to realize lighting simulation, the connecting frame 409 can be rotated along the circular arc surface of the simulation platform 2, the facing direction of the prop relative to the fluorescent lamp 3 can be changed without frequently moving the prop, the simulated irradiation height of the fluorescent lamp 3 can be changed by rotating the auxiliary rod 406, the round rod 411 can be moved along the connecting frame 409 so as to change the simulated irradiation angle of the fluorescent lamp 3, the operation is simple and convenient, the lighting simulation effect is good, the auxiliary groove 405 is formed on the upper surface of the base 1, the inner wall of the auxiliary groove 405 is provided with a plurality of anti-skid protrusions, the friction between the screw 404 and the base 1 is increased through the auxiliary groove 405, the limiting effect of the screw 404 is better, the arc surface of the adjusting rod 408 is sleeved with the coil spring 410, two ends of the coil spring 410 are respectively fixedly connected with the adjusting plate 407 and the connecting frame 409, when the connecting frame 409 rotates, the coil spring 410 always gives a torsion force to the connecting frame 409, so that the connecting frame 409 is more stable when rotating, the upper surface of the simulation platform 2 is provided with the fixedly connected anti-slip pad 414, one side of the anti-slip pad 414 far away from the simulation platform 2 is provided with a plurality of anti-slip patterns, friction between the simulation platform 2 and a simulation prop is increased through the anti-slip pad 414, and the simulation prop is prevented from sliding on the simulation platform 2;

in the embodiment of the present utility model, referring to fig. 6 to 7, the auxiliary structure 5 includes a clamping plate 51 and a supporting frame 55, two clamping plates 51 are abutted to two sides of a connecting frame 409, a fixedly connected spring 52 is installed at one side of the clamping plate 51 far away from the connecting frame 409, one end of the spring 52 far away from the clamping plate 51 is fixedly connected with the supporting frame 55, a fixedly connected protecting cover 56 is installed at the lower end of the supporting frame 55, when the device is not used for a long time, the protecting cover 56 is moved to surround a fluorescent lamp 3, and then the clamping plate 51 is operated to fix the clamping plate 51 on the connecting frame 409, so that the position of the protecting cover 56 is fixed, the fluorescent lamp 3 is protected from being damaged by false touch, a fixedly connected rubber pad 53 is installed at one side of the clamping plate 51 near the connecting frame 409, abrasion of the connecting frame 409 is reduced by the rubber pad 53, the service life is prolonged, a fixedly connected limiting rod 54 is installed at one side of the clamping plate 51 far away from the connecting frame 409, the limiting rod 54 is slidably connected with the supporting frame 55, and the limiting rod 54 is used for limiting the moving direction of the clamping plate 51, so that the shifting of the clamping plate 51 is prevented;

the utility model provides a lighting simulation device for building design, which has the following working principle: when lighting simulation is needed, the building model is firstly placed on the simulation platform 2, the screw 404 is rotated, the screw 404 is far away from the base 1 by virtue of threads, at the moment, the adjusting frame 402 can be rotated along the arc surface of the simulation platform 2, the adjusting frame 402 drives the connecting frame 409 to rotate, the connecting frame 409 is rotated to a proper position according to the appointed direction of one side of the building model compared with the fluorescent lamp 3, the screw 404 is rotated in the opposite direction, the screw 404 is abutted against the base 1, the adjusting frame 402 is fixed in position, after the building model is adjusted in the opposite direction compared with the fluorescent lamp 3, the auxiliary rod 406 is rotated, the adjusting plate 407 slides out of the adjusting frame 402 along the arc surface of the auxiliary rod 406 by virtue of threads, the height of the daylight lamp is changed, only the handle 412 is rotated while the clamping ring 413 is pinched, the clamping ring 413 moves towards the direction far away from the connecting frame 409 by virtue of the threads, at the moment, the fluorescent lamp 3 can be moved along the connecting frame 409, further, the angle of the simulated irradiation of the fluorescent lamp 3 is adjusted, the handle 412 is rotated in the opposite direction of the clamping ring 413, the fluorescent lamp 3 is fixed on the connecting frame 409 in real time, after the position adjustment of the fluorescent lamp 3 is finished, the adjusting rod 408 is rotated to drive the connecting frame 409 to rotate, so that the fluorescent lamp 3 moves in an arc track above a building model to perform lighting simulation, the simulated prop is firstly placed on the simulation platform 2, the arc track of the fluorescent lamp 3 can be moved above the prop by rotating the adjusting rod 408, lighting simulation is further realized, the connecting frame 409 can be rotated along the arc surface of the simulation platform 2, the facing direction of the prop relative to the fluorescent lamp 3 can be changed without frequently moving the prop, the simulated irradiation height of the fluorescent lamp 3 can be changed by rotating the auxiliary rotating rod 406, the simulated irradiation angle of the fluorescent lamp 3 can be changed by moving the round rod 411 along the connecting frame 409, the simulated irradiation angle of the fluorescent lamp 3 is simple and convenient to operate, can be adjusted in multiple directions, and has good lighting simulation effect.

When the fluorescent lamp 3 needs to be protected, the two clamping plates 51 are moved towards the direction away from each other, the spring 52 is in a compressed state, the protective cover 56 is operated to surround the fluorescent lamp 3 from bottom to top, the clamping plates 51 are loosened, the clamping plates 51 move towards the direction close to the connecting frame 409 under the action of the elastic force of the spring 52, the two clamping plates 51 are clamped at two sides of the connecting frame 409, the protective cover 56 is fixed, and after the adjustment is completed, the protective cover 56 is moved to surround the fluorescent lamp 3 when the fluorescent lamp 3 is not used for a long time, the clamping plates 51 are operated, the clamping plates 51 are fixed on the connecting frame 409, so that the position of the protective cover 56 is fixed, the fluorescent lamp 3 is protected, and the fluorescent lamp 3 is prevented from being damaged due to false touch.

The circuits and control involved in the present utility model are all of the prior art, and are not described in detail herein.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims (7)

1. A lighting simulation device for architectural design, comprising: the fluorescent lamp comprises a base (1), a simulation platform (2) and a fluorescent lamp (3), wherein the simulation platform (2) which is fixedly connected is arranged on the upper surface of the base (1);

the fluorescent lamp comprises an adjusting structure (4), wherein the adjusting structure (4) is positioned on a simulation platform (2), the adjusting structure (4) comprises two sliding plates (401), the arc surface of the simulation platform (2) is slidably connected with two sliding plates (401), one side of the sliding plates (401) far away from the simulation platform (2) is provided with a fixedly connected adjusting frame (402), one side of the adjusting frame (402) far away from the sliding plates (401) is provided with a fixedly connected fixing block (403), the internal threads of the fixing block (403) are inserted with a screw (404), the inside of the adjusting frame (402) is rotatably connected with an auxiliary rod (406), the inside of the adjusting frame (402) is slidably connected with an adjusting plate (407), one side of the adjusting plate (407) far away from the simulation platform (2) is rotatably connected with an adjusting rod (408), the arc surface of the adjusting rod (408) is provided with a fixedly connected connecting frame (409), the inner wall of the connecting frame (409) is slidably connected with a round rod 411, the upper surface of the round rod (412) is provided with a circular rod (411), and the round rod (411) is fixedly connected with the surface of a circular lamp (413), and the round rod (413) is fixedly connected with the surface of a fluorescent lamp (3).

And the auxiliary structure (5), wherein the auxiliary structure (5) is positioned on the connecting frame (409).

2. A lighting simulation device for architectural design according to claim 1, characterized in that an auxiliary groove (405) is provided on the upper surface of the base (1), and a plurality of anti-slip protrusions are mounted on the inner wall of the auxiliary groove (405).

3. The lighting simulation device for architectural design according to claim 1, wherein the arc surface of the adjusting rod (408) is sleeved with a coil spring (410), and two ends of the coil spring (410) are fixedly connected with the adjusting plate (407) and the connecting frame (409) respectively.

4. The lighting simulation device for architectural design according to claim 1, wherein the upper surface of the simulation platform (2) is provided with a fixedly connected anti-slip pad (414), and a plurality of anti-slip patterns are arranged on one side of the anti-slip pad (414) away from the simulation platform (2).

5. The daylighting analogue means for architectural design of claim 1, wherein, auxiliary structure (5) include splint (51) and support frame (55), the both sides butt of connection frame (409) has two splint (51), fixed connection's spring (52) are installed to one side that connection frame (409) were kept away from to splint (51), one end and support frame (55) fixed connection that splint (51) were kept away from to spring (52), fixed connection's protection casing (56) are installed to the lower extreme of support frame (55).

6. A lighting simulation device for architectural design according to claim 5, wherein a fixedly connected rubber pad (53) is mounted on the side of the clamping plate (51) close to the connecting frame (409).

7. The lighting simulation device for architectural design according to claim 5, wherein a stop lever (54) is fixedly connected to one side of the clamping plate (51) far away from the connecting frame (409), and the stop lever (54) is slidably connected to the supporting frame (55).