Disclosure of Invention
The utility model aims to solve the defects in the prior art, and provides a building door and window heat preservation performance detection device.
In order to achieve the above purpose, the present utility model adopts the following technical scheme:
the equipment for detecting the heat preservation performance of the building doors and windows comprises a shell and a cover plate hinged on the shell, wherein an air cooler is fixedly connected to the cover plate;
the novel clamping device comprises a shell, and is characterized in that an adjusting mechanism is arranged on the shell and comprises a transverse plate and two first sliding blocks, wherein the transverse plate is arranged on the shell in a sliding mode, two extrusion blocks are fixedly connected to the transverse plate, each first sliding block is provided with an extrusion groove, each extrusion block is connected with the corresponding extrusion groove in a sliding mode, each first sliding block is connected with the shell through two first springs, a first transverse rod is fixedly connected to the first sliding block, each first transverse rod is connected with a second transverse rod through a vertical rod, the second transverse rods are connected with the shell in a sliding mode, each second transverse rod is fixedly connected with a clamping block, and clamping mechanisms are arranged on the clamping blocks.
Preferably, each clamping mechanism comprises a lower clamping block fixedly connected with the clamping block, a second sliding block is slidably arranged on the clamping block, each second sliding block is connected with the clamping block through a plurality of second springs, and an upper clamping block is fixedly connected with the second sliding block.
Preferably, two sealing rings are fixedly connected to the shell, each sealing ring is made of rubber, and the second cross rod is in sliding connection with the sealing ring.
Preferably, the reciprocating screw rod is rotatably arranged on the shell, the reciprocating screw rod is in threaded connection with the transverse plate, the rotating block is fixedly connected to the reciprocating screw rod, the limiting rod is arranged on the rotating block in a sliding penetrating mode, a plurality of first limiting grooves which are annularly arranged are formed in the shell around the reciprocating screw rod, and the limiting rod is clamped with the corresponding first limiting grooves.
Preferably, two installation blocks are fixedly connected to the shell and the cover plate, limiting blocks are slidably arranged on the two installation blocks, second limiting grooves are formed in the other two installation blocks, and each limiting block is clamped with the corresponding second limiting groove.
Preferably, an observation window is formed in the shell, and the observation window is made of transparent glass.
Preferably, a plurality of support rods are fixedly connected to the shell, and each support rod is rotatably connected with a roller.
According to the utility model, through the mutual matching of the extrusion block and the first sliding block, the detection of the thermal insulation performance of doors and windows with different sizes can be realized under the condition of using the device, the operation is very simple, the time and the labor are saved, and the practicability of the device is greatly improved.
Drawings
Fig. 1 is a schematic diagram of a front view structure of a device for detecting thermal insulation performance of a building door and window according to the present utility model;
fig. 2 is a schematic top view structure of a device for detecting thermal insulation performance of a building door and window according to the present utility model;
FIG. 3 is a schematic diagram of a front cross-sectional structure of a device for detecting thermal insulation performance of a door and a window of a building according to the present utility model;
FIG. 4 is a schematic top view of a cross-sectional structure of a first slider and a reciprocating screw;
fig. 5 is a schematic view of a partial enlarged structure of a in fig. 3.
In the figure: 1 a shell, 2 vertical rods, 3 a first cross rod, 4 rollers, 5 observation windows, 6 support rods, 7 a second cross rod, 8 a second spring, 9 a mounting block, 10 a limiting block, 11 a limiting rod, 12 a rotating block, 13 a reciprocating screw rod, 14 a cover plate, 15 an air cooler, 16 a first sliding block, 17 an extrusion block, 18 a first spring, 19 a transverse plate, 20 a sealing ring, 21 a clamping block, 22 an upper clamping block, 23 a lower clamping block and 24 a second sliding block.
Detailed Description
The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.
Referring to fig. 1-5, a building door and window thermal insulation performance detection device comprises a shell 1 and a cover plate 14 hinged to the shell 1, wherein an air cooler 15 is fixedly connected to the cover plate 14, an adjusting mechanism is arranged on the shell 1 and comprises a transverse plate 19 and two first sliding blocks 16 which are arranged on the shell 1 in a sliding mode, two extrusion blocks 17 are fixedly connected to the transverse plate 19, extrusion grooves are formed in each first sliding block 16, the extrusion blocks 17 are in sliding connection with the corresponding extrusion grooves, each first sliding block 16 is connected with the shell 1 through two first springs 18, a first transverse rod 3 is fixedly connected to the first sliding block 16, each first transverse rod 3 is connected with a second transverse rod 7 through a vertical rod 2, the second transverse rod 7 is in sliding connection with the shell 1, a clamping block 21 is fixedly connected to each second transverse rod 7, and a clamping mechanism is arranged on the clamping block 21.
Each clamping mechanism comprises a lower clamping block 23 fixedly connected to the clamping block 21, a second sliding block 24 is arranged on the clamping block 21 in a sliding manner, each second sliding block 24 is connected with the corresponding clamping block 21 through a plurality of second springs 8, an upper clamping block 22 is fixedly connected to the second sliding block 24, the two clamping blocks 21 are mutually close to each other, the lower clamping block 23 and the upper clamping block 22 on the clamping block 21 are simultaneously contacted and extruded to the side wall of a door and window needing to be detected, as the acting force of the door and window to the upper clamping block 22 is provided with a vertically upward component force, the upper clamping block 22 vertically moves upwards, the upper clamping block 22 moves to drive the second sliding block 24 to synchronously move, the second sliding block 24 and the clamping block 21 relatively slide, the second springs 8 deform until the door and window are embedded between the upper clamping block 22 and the lower clamping block 23, two sides of the door and window are respectively propped against the corresponding clamping blocks 21, the upper clamping block 22 and the lower clamping block 23 are clamped under the elastic action of the second springs 8, the door and the window with different sizes can be clamped and the two sealing rings 20 are fixedly connected to the shell 1 through the clamping, and each sealing ring 20 is provided with a vertically upward component force, and the sealing ring 20 is smoothly connected with the sealing ring 7 and the sealing ring 1, and the sealing ring is prevented from overflowing from the sealing ring 1, and the sealing ring is smoothly arranged between the sealing ring and the shell 1 and the sealing ring.
The reciprocating screw rod 13 is rotationally arranged on the shell 1, the reciprocating screw rod 13 is in threaded connection with the transverse plate 19, the rotating block 12 is fixedly connected to the reciprocating screw rod 13, the limiting rod 11 is arranged on the rotating block 12 in a sliding mode, a plurality of first limiting grooves which are annularly arranged are formed in the shell 1 around the reciprocating screw rod 13, the limiting rod 11 is clamped with the corresponding first limiting grooves, acting force is applied to the rotating block 12, the rotating block 12 rotates to drive the reciprocating screw rod 13 to synchronously rotate, the reciprocating screw rod 13 moves to drive the transverse plate 19 to move, the transverse plate 19 is enabled to do stable movement in the horizontal direction, acting force is applied to the limiting rod 11, the limiting rod 11 and the rotating block 12 are enabled to slide relatively until the limiting rod 11 and the corresponding limiting grooves are clamped, the rotating block 12 is fixed, two mounting blocks 9 are fixedly connected to the shell 1 and the cover plate 14, the limiting blocks 10 are slidably arranged on the two mounting blocks 9, the corresponding second limiting grooves are respectively clamped with the limiting blocks 10 are formed in the other two mounting blocks 9, the acting force is applied to the two limiting blocks 10, and the corresponding limiting blocks 10 are enabled to slide relatively to the corresponding mounting blocks 10, and the cover plate 14 is enabled to slide relatively to be fixed until the cover plate 14 is fixed to the corresponding mounting blocks 14.
The observation window 5 has been seted up on the casing 1, and observation window 5 sets up to transparent glass material, and the setting of observation window 5 makes things convenient for the staff to observe the work progress in the casing 1, and fixedly connected with a plurality of bracing pieces 6 on the casing 1 all rotate on every bracing piece 6 and are connected with gyro wheel 4, and bracing piece 6 and gyro wheel 4's setting for this equipment can remove arbitrary position department, thereby improves the practicality of this equipment greatly.
When the device is required to be used, the cover plate 14 is firstly opened, a door and window to be detected is placed in the shell 1 and positioned between the two clamping blocks 21, the bottom of the door and window is slightly higher than the two lower clamping blocks 23, acting force is applied to the rotating block 12, the rotating block 12 rotates to drive the reciprocating screw rod 13 to synchronously rotate, the reciprocating screw rod 13 moves to drive the transverse plate 19 to move, the transverse plate 19 moves in a horizontal direction, the transverse plate 19 moves to drive the two extrusion blocks 17 to move, the inclined surface parts of the two extrusion blocks 17 contact and extrude the extrusion grooves on the corresponding first sliding blocks 16, and as the acting force of the extrusion blocks 17 on the first sliding blocks 16 has a component force in the horizontal direction, the two first sliding blocks 16 simultaneously slide relatively to the shell 1, the two first sliding blocks 16 are mutually close, and the first spring 18 deforms.
The first sliding block 16 moves to drive the corresponding first cross rod 3 to move, under the cooperation of the corresponding vertical rods 2, the first cross rod 3 moves to drive the corresponding vertical rods 2 to move, so that the two vertical rods 2 are mutually close, and the two clamping blocks 21 are driven to mutually close, so that the lower clamping block 23 and the upper clamping block 22 on the clamping blocks 21 are simultaneously contacted and extruded with the side wall of the door and window to be detected, the acting force of the door and window to the upper clamping block 22 has a vertically upward component force, so that the upper clamping block 22 vertically moves upwards, the upper clamping block 22 moves to drive the second sliding block 24 to synchronously move, the second sliding block 24 and the clamping blocks 21 relatively slide, the second spring 8 deforms until the door and window is embedded between the upper clamping block 22 and the lower clamping block 23, two sides of the door and window are respectively abutted against the corresponding clamping blocks 21, and the upper clamping block 22 and the lower clamping block 23 are tightly clamped under the elastic force of the second spring 8, so that the door and window with different sizes can be clamped and fixed through the process.
Overall, for technical problems: the structure of traditional building door and window thermal insulation performance check out test set is comparatively fixed, can only detect fixed size's door and window, when needs to detect the door and window of multiple different sizes, often need use the check out test set of multiple different models just can accomplish, and the operation is very loaded down with trivial details, and consuming time and power to greatly reduced check out test set's practicality.
Adopts the technical proposal that: the utility model provides a building door and window heat preservation performance check out test set, including casing 1 and the apron 14 of articulated on casing 1, fixedly connected with air-cooler 15 on the apron 14, be provided with adjustment mechanism on the casing 1, adjustment mechanism includes diaphragm 19 and two first sliders 16 that slide on the casing 1 and set up, fixedly connected with two extrusion pieces 17 on the diaphragm 19, extrusion groove has all been seted up on every first slider 16, extrusion piece 17 and corresponding extrusion groove sliding connection, every first slider 16 all is connected with casing 1 through two first springs 18, fixedly connected with first horizontal pole 3 on the first slider 16, every first horizontal pole 3 all is connected with second horizontal pole 7 through montant 2, second horizontal pole 7 and casing 1 sliding connection, all fixedly connected with clamp splice 21 on every second horizontal pole 7, be provided with fixture on the clamp splice 21.
The implementation process of the technical scheme is as follows: when the device is required to be used, the cover plate 14 is firstly opened, a door and window to be detected is placed in the shell 1, the door and window is located between the two clamping blocks 21, the bottom of the door and window is slightly higher than the two lower clamping blocks 23, acting force is applied to the rotating block 12, the rotating block 12 rotates to drive the reciprocating screw rod 13 to synchronously rotate, the reciprocating screw rod 13 moves to drive the transverse plate 19 to move, the transverse plate 19 makes stable movement in the horizontal direction, the transverse plate 19 moves to drive the two extrusion blocks 17 to move, the inclined surface parts of the two extrusion blocks 17 contact and extrude extrusion grooves in the corresponding first sliding blocks 16, the two first sliding blocks 16 simultaneously slide relatively with the shell 1 due to the acting force of the extrusion blocks 17 on the first sliding blocks 16, the two first sliding blocks 16 are close to each other, the first springs 18 deform, the first sliding blocks 16 move to drive the corresponding first transverse rods 3 to move, the corresponding vertical rods 2 are driven to move to be close to each other under the cooperation of the corresponding vertical rods 2, and the two vertical rods 2 are driven to be close to each other.
So must solve this technical problem, through the cooperation of extrusion piece 17 and first slider 16, can be under the condition of only using this equipment, realize the detection to not unidimensional door and window heat preservation performance, the operation is got up very simply, labour saving and time saving to improve the practicality of this device greatly.
The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.