CN214749521U - Gypsum board hardness testing arrangement for architectural design - Google Patents

Abstract

The utility model relates to a testing arrangement technical field specifically is a gypsum board hardness testing arrangement for architectural design, including testing arrangement body and servo motor, the last fixed mounting of testing arrangement body has the fixing base, and fixed mounting has first shaft lever seat on the fixing base inner wall, insert on the first shaft lever seat and be equipped with the threaded rod, and the bottom of threaded rod is inserted and is established in the chuck block, fixed mounting has first conical gear on the threaded rod, and the cover is equipped with the cover block on the threaded rod, and fixedly connected with slider on the cover block, fixedly connected with connecting rod on the cover block, and fixed mounting has the clamp splice on the connecting rod, inside the inserting of fixing base is equipped with first bull stick. The utility model discloses be provided with the clamp splice, make the cover block remove through the rotation of threaded rod, thereby the removal of cover block is convenient for the clamp splice and is carried out the centre gripping to the gypsum board fixed, and the rotation through the fluted disc drives the push rod and carries out the downstream to be convenient for extrude the piece and extrude the gypsum board, test the hardness of gypsum board.

Description

Gypsum board hardness testing arrangement for architectural design

Technical Field

The utility model relates to a testing arrangement technical field specifically is a gypsum board hardness testing arrangement for architectural design.

Background

With the continuous development of society and the continuous improvement of science, a large amount of gypsum boards are needed to be hung on the ceiling in the house, and lamps and the like need to be installed on the gypsum boards, so the hardness of the gypsum boards needs to be tested during processing.

At present all when testing hardness to the gypsum board all make somebody a mere figurehead the gypsum board and then use the empty drum skin hammer slowly to strike the gypsum board, then see whether the hardness of gypsum board accords with the standard, this mode causes the damage to the gypsum board easily when striking, very extravagant resource, therefore a need for gypsum board hardness testing arrangement is used in architectural design solves above-mentioned problem urgently.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a gypsum board hardness testing arrangement for architectural design to the gypsum board that proposes among the above-mentioned background art of solution carries on makedly to make somebody a mere figurehead to strike and causes the damage problem to the gypsum board easily when knocking.

In order to achieve the above object, the utility model provides a following technical scheme: a gypsum board hardness testing device for building design comprises a testing device body and a servo motor, wherein a fixed seat is fixedly installed on the testing device body, a first shaft rod seat is fixedly installed on the inner wall of the fixed seat, a threaded rod is inserted into the first shaft rod seat, the bottom end of the threaded rod is inserted into a clamping block, a first conical gear is fixedly installed on the threaded rod, a sleeve block is sleeved on the threaded rod, a sliding block is fixedly connected onto the sleeve block, a connecting rod is fixedly connected onto the sleeve block, a clamping block is fixedly installed onto the connecting rod, a first rotating rod is inserted into the fixed seat, a second conical gear is fixedly installed on the side face of the first rotating rod, a rotating disc is fixedly installed on the first rotating rod, a supporting rod is fixedly connected onto the testing device body, the top end of the supporting rod is fixedly connected onto a transverse rod, and an equipment box is installed on the transverse rod, the utility model discloses an equipment box, including equipment box, extrusion piece, first shaft pole seat, second shaft pole seat, third shaft pole, middle-end fixed mounting, third bevel gear, fifth bevel gear, servo motor, and fixed mounting has sixth bevel gear on the servo motor, and the equipment box is inside to be inserted and to be equipped with the push rod, and push rod bottom fixedly connected with base, and base bottom fixed mounting has the extrusion piece, the equipment box is built-in to be equipped with the second shaft pole seat, and inserts on the second shaft pole seat and be equipped with the second bull stick, fixed mounting has the third bevel gear on the second bull stick, and fixed mounting has the fluted disc on the second bull stick, the equipment box is inside to have installed the third shaft pole seat, and inserts on the third shaft pole seat and be equipped with the third bull stick, the middle-end fixed mounting of third bull stick has the fourth bevel gear, and the side fixed mounting of third bull stick has the fifth bevel gear, the inside fixed mounting of equipment box has servo motor, and servo motor is last fixed mounting has the sixth bevel gear.

Preferably, the testing device body is internally provided with a sliding groove structure, and the sliding groove and the fixing seat form a sliding type structure.

Preferably, the first bevel gear is meshed with the second bevel gear, and the first bevel gear and the second bevel gear form a rotating structure.

Preferably, the sleeve block is internally provided with internal threads, and the sleeve block and the threaded rod form a spiral rotating structure.

Preferably, the push rod is provided with a latch, and the latch is meshed with the fluted disc.

Preferably, the third bevel gear is meshed with the fifth bevel gear, and the third bevel gear and the fifth bevel gear form a rotating structure.

Preferably, the fourth bevel gear is meshed with the sixth bevel gear, and the fourth bevel gear and the sixth bevel gear form a rotating structure.

Compared with the prior art, the beneficial effects of the utility model are that: this gypsum board hardness testing arrangement for architectural design is provided with the clamp splice, makes the cover block remove through the rotation of threaded rod, thereby the removal of cover block is convenient for the clamp splice and carries out the centre gripping to the gypsum board fixed, drives the push rod through the rotation of fluted disc and carries out the downstream to be convenient for extrude the piece and extrude the gypsum board, test the hardness of gypsum board.

(1) The device is provided with the clamp splice, and the rotation through first bull stick drives the threaded rod and rotates, and the cover is equipped with the cover piece on the threaded rod, makes the cover piece remove through the rotation of threaded rod, thereby the removal of cover piece is convenient for the clamp splice and carries out the centre gripping to the gypsum board fixed.

(2) The device drives the third bull stick through the rotation of sixth conical gear and rotates, and the rotation of fifth conical gear drives the second bull stick and rotates to the fluted disc of being convenient for rotates, and the rotation of fluted disc drives the push rod and carries out the downstream, thereby the extrusion piece of being convenient for extrudees the gypsum board, tests the hardness of gypsum board.

Drawings

FIG. 1 is a schematic front view of the structure of the present invention;

FIG. 2 is a schematic view of the sectional structure of the equipment box of the present invention;

FIG. 3 is a schematic view of the sectional structure of the fixing base of the present invention;

fig. 4 is a schematic view of the top-view cross-sectional structure of the equipment box of the present invention.

In the figure: 1. a testing device body; 101. a fixed seat; 102. a first shaft lever seat; 103. a threaded rod; 104. a clamping block; 105. a first bevel gear; 106. sleeving blocks; 107. a slider; 108. a connecting rod; 109. a clamping block; 2. a first rotating lever; 201. a second bevel gear; 202. a turntable; 3. a support bar; 301. a cross bar; 302. an equipment box; 303. a push rod; 304. clamping teeth; 305. a base; 306. extruding the block; 4. a second spindle base; 401. a second rotating rod; 402. a third bevel gear; 403. a fluted disc; 404. a third shaft lever seat; 405. a third rotating rod; 406. a fourth bevel gear; 407. a fifth bevel gear; 5. a servo motor; 501. and a sixth bevel gear.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides an embodiment: a gypsum board hardness testing device for architectural design comprises a testing device body 1 and a servo motor 5, wherein a fixed seat 101 is fixedly installed on the testing device body 1, a sliding groove structure is arranged inside the testing device body 1, the sliding groove and the fixed seat 101 form a sliding structure, the fixed seat 101 can move on the testing device body 1 conveniently, so that gypsum boards with different sizes can be fixed on the fixed seat 101 conveniently, a first shaft rod seat 102 is fixedly installed on the inner wall of the fixed seat 101, a threaded rod 103 is inserted on the first shaft rod seat 102, the bottom end of the threaded rod 103 is inserted in a clamping block 104, a first conical gear 105 is fixedly installed on the threaded rod 103, a sleeve block 106 is sleeved on the threaded rod 103, an internal thread is arranged inside the sleeve block 106, the sleeve block 106 and the threaded rod 103 form a spiral rotating type structure, the sleeve block 106 is driven to move by the rotation of the threaded rod 103, and a sliding block 107 is fixedly connected on the sleeve block 106, fixedly connected with connecting rod 108 on pocket piece 106, and fixed mounting has clamp splice 109 on the connecting rod 108, fixing base 101 is inside to be inserted and is equipped with first bull stick 2, and the side fixed mounting of first bull stick 2 has second bevel gear 201, first bevel gear 105 meshes with second bevel gear 201 mutually, and first bevel gear 105 constitutes the rotary type structure with second bevel gear 201, rotation through first bull stick 2 drives threaded rod 103 and rotates, fixed mounting has carousel 202 on the first bull stick 2, fixedly connected with bracing piece 3 on the testing arrangement body 1, and the top fixed connection of bracing piece 3 is on horizontal pole 301, install equipment box 302 on horizontal pole 301.

A push rod 303 is inserted into the equipment box 302, a base 305 is fixedly connected to the bottom end of the push rod 303, an extrusion block 306 is fixedly installed at the bottom end of the base 305, a second shaft base 4 is installed in the equipment box 302, a second rotating rod 401 is inserted into the second shaft base 4, a third bevel gear 402 is fixedly installed on the second rotating rod 401, a fluted disc 403 is fixedly installed on the second rotating rod 401, a latch 304 is installed on the push rod 303, the latch 304 is meshed with the fluted disc 403, the push rod 303 is driven to move up and down by the rotation of the fluted disc 403, a third shaft base 404 is installed in the equipment box 302, a third rotating rod 405 is inserted into the third shaft base 404, a fourth bevel gear 406 is fixedly installed at the middle end of the third rotating rod 405, a fifth bevel gear 407 is fixedly installed on the side surface of the third rotating rod 405, the third bevel gear 402 is meshed with the fifth bevel gear 407, and the third bevel gear 402 and the fifth bevel gear form a rotating structure, the second rotating rod 401 is driven to rotate through the rotation of the third rotating rod 405, the servo motor 5 is fixedly mounted inside the equipment box 302, the sixth bevel gear 501 is fixedly mounted on the servo motor 5, the fourth bevel gear 406 is meshed with the sixth bevel gear 501, the fourth bevel gear 406 and the sixth bevel gear 501 form a rotating structure, and the third rotating rod 405 is driven to rotate through the rotation of the sixth bevel gear 501.

The working principle is as follows: during the use, according to fig. 1, when needs are fixed to different gypsum boards, adjust the size of being fit for testing the gypsum board to the position of fixing base 101, then place the gypsum board on clamp splice 109, then rotate carousel 202, rotation through first bull stick 2 drives threaded rod 103 and rotates, the cover is equipped with cover piece 106 on threaded rod 103, rotation through threaded rod 103 makes cover piece 106 remove, thereby the removal of cover piece 106 is convenient for clamp splice 109 and carries out the centre gripping to the gypsum board fixed.

After fixing the gypsum board, the inside servo motor 5 of equipment box 302 begins to operate, make sixth conical gear 501 rotate through servo motor 5's operation, rotation through sixth conical gear 501 drives third bull stick 405 and rotates, fixed mounting installs fifth conical gear 407 on the third bull stick 405, and fifth conical gear 407 meshes with third conical gear 402 mutually, rotation through fifth conical gear 407 drives second bull stick 401 and rotates, thereby be convenient for fluted disc 403 rotates, the rotation of fluted disc 403 drives push rod 303 and moves down, thereby be convenient for extrude the piece 306 and extrude the gypsum board, test the hardness of gypsum board.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein, and any reference signs in the claims are not intended to be construed as limiting the claim concerned.

Claims (7)

1. The utility model provides a gypsum board hardness testing arrangement for architectural design, includes testing arrangement body (1) and servo motor (5), its characterized in that: the testing device comprises a testing device body (1), wherein a fixed seat (101) is fixedly installed on the testing device body (1), a first shaft rod seat (102) is fixedly installed on the inner wall of the fixed seat (101), a threaded rod (103) is inserted into the first shaft rod seat (102), the bottom end of the threaded rod (103) is inserted into a clamping block (104), a first bevel gear (105) is fixedly installed on the threaded rod (103), a sleeve block (106) is sleeved on the threaded rod (103), a sliding block (107) is fixedly connected onto the sleeve block (106), a connecting rod (108) is fixedly connected onto the sleeve block (106), a clamping block (109) is fixedly installed onto the connecting rod (108), a first rotating rod (2) is inserted into the fixed seat (101), a second bevel gear (201) is fixedly installed on the side surface of the first rotating rod (2), a rotating disc (202) is fixedly installed onto the first rotating rod (2), and a supporting rod (3) is fixedly connected onto the testing device body (1), the top end of the supporting rod (3) is fixedly connected to the cross rod (301), an equipment box (302) is installed on the cross rod (301), a push rod (303) is inserted into the equipment box (302), the bottom end of the push rod (303) is fixedly connected with a base (305), an extrusion block (306) is fixedly installed at the bottom end of the base (305), a second shaft rod seat (4) is installed in the equipment box (302), a second rotating rod (401) is inserted into the second shaft rod seat (4), a third bevel gear (402) is fixedly installed on the second rotating rod (401), a fluted disc (403) is fixedly installed on the second rotating rod (401), a third shaft rod seat (404) is installed inside the equipment box (302), a third rotating rod (405) is inserted into the third shaft rod seat (404), a fourth bevel gear (406) is fixedly installed at the middle end of the third rotating rod (405), and a fifth bevel gear (407) is fixedly installed on the side surface of the third rotating rod (405), the servo motor (5) is fixedly installed in the equipment box (302), and a sixth bevel gear (501) is fixedly installed on the servo motor (5).

2. The apparatus for testing the hardness of gypsum board for architectural design according to claim 1, wherein: the testing device is characterized in that a sliding groove structure is arranged inside the testing device body (1), and the sliding groove and the fixing seat (101) form a sliding type structure.

3. The apparatus for testing the hardness of gypsum board for architectural design according to claim 1, wherein: the first bevel gear (105) is meshed with the second bevel gear (201), and the first bevel gear (105) and the second bevel gear (201) form a rotary structure.

4. The apparatus for testing the hardness of gypsum board for architectural design according to claim 1, wherein: the internal thread is arranged inside the sleeve block (106), and the sleeve block (106) and the threaded rod (103) form a spiral rotating type structure.

5. The apparatus for testing the hardness of gypsum board for architectural design according to claim 1, wherein: the push rod (303) is provided with a latch (304), and the latch (304) is meshed with the fluted disc (403).

6. The apparatus for testing the hardness of gypsum board for architectural design according to claim 1, wherein: the third bevel gear (402) is meshed with the fifth bevel gear (407), and the third bevel gear (402) and the fifth bevel gear (407) form a rotary structure.

7. The apparatus for testing the hardness of gypsum board for architectural design according to claim 1, wherein: the fourth conical gear (406) is meshed with the sixth conical gear (501), and the fourth conical gear (406) and the sixth conical gear (501) form a rotary structure.

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