CN112554388A - Buckle formula partition wall structure - Google Patents

Abstract

The invention relates to the technical field of assembly type partition walls, in particular to a buckle type partition wall structure. The ladder comprises a first keel and a second keel which are perpendicular to each other, wherein the first keel is provided with a plurality of through holes, one end of the second keel is inserted into the through hole of one first keel, and the other end of the second keel is inserted into the through hole of the other first keel to form a ladder frame; the ladder also comprises partition boards arranged on two opposite surfaces of the ladder frame; the first keel comprises a first single bone, a first form bone and a first connecting bone, wherein the first form bone is arranged on two sides of the first single bone respectively and is parallel to the first single bone, and the first connecting bone connects the first form bone and the first single bone; a groove is formed among the end part of the first single bone in the width direction, the first connecting bone and the end part of the first middle bone in the width direction; the partition board comprises a flat plate and a raised line which is arranged on the flat plate and can be inserted into the groove. The application discloses partition plate mounting structure does not have nail and does not have gluey, can improve the security and the planarization of the convenience of installation, partition wall.

Description

Buckle formula partition wall structure

Technical Field

The invention relates to the technical field of assembly type partition walls, in particular to a buckle type partition wall structure.

Background

With the increasing demand of people on houses and office environments, the materials used by non-bearing walls such as household walls, peripheral protective walls and indoor partition walls adopted by common house buildings have higher and higher demands on the aspects of energy conservation, environmental protection, sound insulation, fire resistance, service life and the like.

The partition wall is a wall for partitioning an inner space of a building. The assembled indoor partition wall has the characteristics of small weight and thin thickness, and the existing internal partition wall in the residential engineering mainly adopts a masonry partition wall, so that the masonry partition wall is high in material cost, large in engineering quantity and poor in economic effect. And the masonry partition wall can not meet the modern development requirements in the aspects of energy conservation, heat preservation, sound insulation, heat insulation and the like. Therefore, an assembled indoor partition wall structure is developed, at present, most of the assembled indoor partition walls are non-bearing partition walls, mainly comprise light steel keel gypsum plaster board cover systems, a frame supporting structure is formed by a top keel, a ground keel, a transverse keel and a reinforcing keel, and the assembled indoor partition walls are structurally connected by a clamping piece, a connecting piece, a fixing piece and the like; the fastening connection is formed by shooting nails, self-tapping screws, expansion bolts, caulking materials and the like. For example, the utility model CN210530042U discloses a modular internal partition wall structure. The construction process flow is as follows: paying off, installing a top keel and a bottom keel, installing a vertical keel, installing a transverse keel, installing a gypsum panel on one side, filling a sound insulation material, installing a gypsum panel on the other side, performing seam treatment and constructing a surface layer. Such as the construction process flow mentioned in the Chinese patent CN 103938764A.

The existing indoor partition wall system mainly has the following defects: a. the installation of the transverse keel, the vertical keel, the filling material, the balance layer and the decorative layer of the indoor partition wall is finished on a construction site, and the integral installation cannot be realized; b. after finishing the surface layer construction, caulking treatment is needed to ensure the integrity of the finish coat; c. for each connecting node, especially for the upper and lower connecting nodes of the indoor partition wall and the upper and lower floor slabs, the construction is complex and inconvenient; usually, a groove is formed on a poured concrete beam or a floor slab again, and then a partition wall connecting piece is embedded, so that the original bearing structure of the concrete beam or the floor slab is easy to damage, such as cracks, steel bar fracture and the like, and meanwhile, the wall plate of the partition wall in the method is directly contacted with the floor slab, and the wall plate inevitably generates displacement and shaking in the construction process, so that the end face of the wall plate is damaged; d. the wall boards of the indoor partition wall are usually only one layer, and the keel system is used for fixedly installing the layer of wall board, so that the thickness of the partition wall is completely met by the thickness of the wall board under the condition that the design requirement of the thickness of the partition wall is met, the overall weight of the partition wall is increased, and the requirement on the connection strength of each node is further increased; e. because the whole partition wall only has one deck wallboard, this has also led to the whole solid construction that is of partition wall, when the wiring installation of various circuits need be carried out, the operation of need slotting on the wallboard to increase the operation process, destroyed the complete degree on wallboard surface, and produced new building rubbish in the job site. e. When partition wall wallboard and fossil fragments use and screw connection, partition wall wallboard probably jack-up the wallboard during because the nailing easily, leads to the wallboard out of plumb or not vertical. And meanwhile, the keel is easily affected and deformed. In addition, when the worker installs the partition wall through the screw, the worker is difficult to work and is easy to be injured.

Disclosure of Invention

The present invention provides a snap-in partition structure to solve the above problems.

The technical scheme for solving the problems is to provide a buckle type partition wall structure, which is characterized in that: the ladder comprises a first keel and a second keel which are perpendicular to each other, wherein the first keel is provided with a plurality of through holes, one end of the second keel is inserted into the through hole of one first keel, and the other end of the second keel is inserted into the through hole of the other first keel so as to form a ladder frame; the ladder comprises a ladder frame and partition boards arranged on two opposite surfaces of the ladder frame; the first keel comprises a first single bone, a first single-form bone and a first connecting bone, wherein the first single bone is arranged on two sides of the first single bone respectively and is parallel to the first single bone, and the first connecting bone is used for connecting the first single-form bone and the first single bone; grooves are formed among the end part of the first single bone in the width direction, the first connecting bone and the end part of the first single bone in the width direction; the partition board comprises a flat plate and a raised line which is arranged on the flat plate and can be inserted into the groove.

Preferably, two ends of the first form rib in the width direction are respectively provided with an external convex strip, the external convex strips are connected with the first form rib in a non-parallel manner, and the free ends of the external convex strips protrude out of one surface of the first form rib away from the first middle rib; the free end of the outer convex strip is connected with a stop strip in a non-parallel way; a hook groove is formed between the outer convex strip and the stop strip; still including connecting two the connecting piece of ladder frame, the connecting piece include the body and set up in two combination coupler bodies of body, combination coupler body include can with one two of first fossil fragments the hook groove is the single coupler body of connecting respectively.

Preferably, the combined hook body comprises a connecting plate connected with the body, and the two single hook bodies are arranged in an axisymmetric manner by taking a central axis of the connecting plate as an axis.

Preferably, the body comprises two parallel straight plates, and the end part of one straight plate is connected with the end part of the other straight plate through the connecting plate.

Preferably, the body comprises a first straight plate and a second straight plate which are connected in a non-parallel manner, and the ends of the first straight plate and the second straight plate are respectively connected with the connecting plate.

Preferably, the body comprises a third straight plate, the two ends of the third straight plate are respectively provided with the connecting plate, and the free ends of the two connecting plates are connected through another connecting plate, so that the connecting member forms a T-shaped connecting member.

Preferably, the body comprises two connecting plates, and the ends of the four connecting plates are connected in sequence, so that the connecting piece forms a cross-shaped connecting piece.

Preferably, the second keel comprises three parallel second single bones and a second connecting bone for connecting the three second single bones, wherein the second connecting bone is perpendicular to the second single bones; the second single rib comprises a second single rib and second form ribs which are arranged on two sides of the second single rib and parallel to the first single rib, inner convex strips are respectively arranged at two ends of the second form rib along the width direction of the second form rib, the inner convex strips are connected with the second form rib in a non-parallel mode, and the inner convex strips protrude out of one surface, close to the second single rib, of the second form rib; the inner top and the inner bottom of the through hole are respectively abutted with the second table rib, an L-shaped inserting block is arranged at the inner side of the through hole and comprises a first inserting part and a second inserting part which are vertically connected, one end of the first inserting part is abutted with the second table rib, and the other end of the first inserting part is abutted with the end face of the free end of the inner convex strip; one end of the second insertion part is abutted against the side face of the second connecting bone, and the other end of the second insertion part is abutted against the side face of the inner convex strip.

Preferably, the through hole includes an upper half hole and a lower half hole which are mirror images of each other, and the upper half hole and the lower half hole are respectively disposed at two ends of the first keel.

Preferably, the two ends of the connecting plate between the two single hooks are respectively provided with the upper half hole and the lower half hole.

The invention has the beneficial effects that:

1. this application is through with the direct concatenation of mortise type structure between first fossil fragments and the second fossil fragments, need not to use screw or glue in addition, has improved the security of the convenience of installation, partition wall to and the planarization of the keel frame of formation.

2. This application realizes the connection of keel frame and partition plate through recess and sand grip, and is equal no nail and glueless, and then has guaranteed the planarization of partition plate yet.

3. This application can be used for various figurative partition plates through the body structure of transform connecting piece, and the practicality is strong, and application scope is wide.

Drawings

FIG. 1 is a schematic view of a button-type partition structure;

FIG. 2 is an enlarged view at A in FIG. 1;

FIG. 3 is a schematic view of the construction of a partition panel of a buckle-type partition structure;

FIG. 4 is a schematic view of a first runner of a buckle-type partition structure;

FIG. 5 is an enlarged view at B in FIG. 4;

FIG. 6 is an enlarged view at C of FIG. 4;

figure 7 is a schematic view of a second runner of a buckle-type partition structure;

FIG. 8 is a schematic view of the construction of embodiment 1 of a buckle type partition wall structure;

FIG. 9 is a top view of the structure of example 1 of a buckle-type partition structure;

FIG. 10 is a schematic view showing the structure of the coupling member of embodiment 1 of a buckle type partition wall structure;

FIG. 11 is a schematic view of the construction of embodiment 2 of a buckle type partition wall construction;

FIG. 12 is a plan view of the structure of embodiment 2 of a buckle type partition wall structure;

FIG. 13 is a schematic view showing the structure of the connector of embodiment 2 of a buckle type partition wall structure;

FIG. 14 is a schematic view of the construction of embodiment 3 of a button type partition wall structure;

FIG. 15 is a top view of the construction of example 3 of a retaining wall construction;

FIG. 16 is a schematic view showing the construction of the connector of embodiment 3 of a button type partition wall structure;

FIG. 17 is a schematic view of the construction of embodiment 4 of a button type partition wall structure;

FIG. 18 is a top view of the construction of example 4 of a retaining wall construction;

FIG. 19 is a schematic view showing the structure of the connecting member of embodiment 4 of a buckle type partition wall structure;

FIG. 20 is a schematic view of the structure of the combined hook body of a button type partition wall structure;

in the figure: the first keel 1, the through hole 10, the insert 101, the first connecting bone 11, the first middle rib 12, the groove 121, the first form rib 13, the outer convex strip 131, the stop strip 132, the hook groove 133, the second keel 2, the second connecting bone 21, the second middle rib 22, the second form rib 23, the inner convex strip 231, the wall plate 3, the flat plate 31, the convex strip 32, the connecting piece 4, the body 41, the combined hook body 42, the single hook body 421 and the connecting plate 422.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

Example 1

A buckle type partition wall structure is shown in figure 1 and comprises a first keel 1 and a second keel 2 which are perpendicular to each other, wherein the first keel 1 is provided with a plurality of through holes 10, one end of the second keel 2 is inserted into the through hole 10 of one first keel 1, and the other end of the second keel is inserted into the through hole 10 of the other first keel 1 to form a ladder frame; and the ladder also comprises partition boards 3 arranged on two opposite surfaces of the ladder frame.

In order to improve the connection tightness and stability of the first keel 1 and the second keel 2, in the present application, as shown in fig. 7, the second keel 2 includes three parallel second single bones and a second connecting bone 21 connecting the three second single bones, the second connecting bones 21 may be set to any number, in this embodiment, two second connecting bones 21 are provided, and the two second connecting bones 21 are both provided in the middle of the second single bone and are not connected with both ends of the second single bone in the width direction. The two second connecting bones 21 form a vertical reinforced cavity. Meanwhile, the second connecting bone 21 may be at any angle to the second simple bone, but in order to secure the supporting effect, the second connecting bone 21 is generally perpendicular to the second simple bone. The second single bone includes a second single bone 22 and second single bones 23 disposed on two sides of the second single bone 22, wherein the second single bones 22 may be disposed in any number, and in this embodiment, one second single bone 22 is disposed. However, in the embodiment, the thickness of the second middle keel 22 is larger than that of the second single form keel 23, and the second middle keel 22 is hollow and provided with a plate parallel to a second connecting keel, so as to divide the inner cavity of the second middle keel 22 into two horizontal reinforcing cavities perpendicular to the vertical reinforcing cavities, thereby improving the strength of the whole second keel 2 through the vertical reinforcing cavities and the horizontal reinforcing cavities. The two second ribs 23 are respectively provided with an inner protruding strip 231 at two ends along the width direction, the inner protruding strips 231 are connected with the second ribs 23 in a non-parallel manner, in this embodiment, the inner protruding strips 231 are vertically connected with the second ribs 23. The inner protrusion 231 protrudes from one surface of the second middle rib 22 adjacent to the second form rib 23. Meanwhile, the width of the second form bone 23 is slightly larger than the width of the second middle bone 22. Under the action of the inner protruding strips 231, the second keel 2 forms four L-shaped slots.

In order to match the insertion of the second keel 2, as shown in fig. 4 and 6, the through hole 10 of the first keel 1 is square, four insertion blocks 101 capable of being inserted into the L-shape of the slot are respectively arranged at two inner sides of the through hole 10, the insertion blocks 101 comprise a first insertion part and a second insertion part which are vertically connected, the first insertion part is a part vertically connected with the inner side of the through hole 10, and the second insertion part is a part vertically connected with the first insertion part. When the end part of the second keel 2 is inserted into the through hole 10, the inner top and the inner bottom of the through hole 10 of the first keel 1 are respectively abutted against one surface of the second single rib 22 away from the second single rib 23, one end of the first insertion part is abutted against the second single rib 22, and the other end is abutted against the end surface of the free end of the inner convex strip 231; the side butt of second spigot one end and second connection bone 21, the side butt of the other end and interior convex strip 231 to the no nail of first fossil fragments and second fossil fragments is connected through the grafting structure of mortise-tenon joint formula. In addition, in order to improve the strength of the first keel 1, as shown in fig. 5, the first keel 1 comprises three parallel first single bones and a first connecting bone 11 for connecting the three first single bones, wherein the three first single bones are not abutted, and a reinforcing cavity is formed between the adjacent first single bones. The three first single bones are all provided with through holes 10, and the through holes 10 of the three first single bones are aligned. Because the first keel 1 is provided with the through hole 10, the first single keel comprises bracket parts at two ends along the width direction of the first single keel and a plurality of connecting parts arranged between the two bracket parts 121, and the through hole 10 is formed between the end parts of the connecting parts along the length direction; therefore, in order to ensure the connection stability, the first connecting bone 11 includes an end connecting bone connecting the three stent portions, and a plurality of middle connecting bones connecting the three connecting portions. The first single bone includes a first single bone 12 and first form bones 13 disposed on two sides of the first single bone 12, the number of the first single bones 12 can be set to any number, and in this embodiment, one first single bone 12 is disposed.

After the connection steadiness of first fossil fragments 1 and second fossil fragments 2 is guaranteed through above-mentioned structure, install partition plate 3 again. As shown in FIG. 2, grooves 121 are formed between the end portions of the first form bone 13 in the width direction thereof, the first connecting bone 11, and the end portions of the first middle bone 12 in the width direction thereof. As shown in fig. 3, the partition plate 3 includes a flat plate 31 and a rib 32 provided on the flat plate 31 and inserted into the groove 121. The installation of the partition wall plate 3 is achieved by snapping the ribs 32 into the grooves 121. In order to improve the connection tightness, the thickness of the end part of the first middle rib 12 can be widened, and the end part of the first form rib 13 is widened towards the direction close to the first middle rib 12, so that the groove 121 forms a major arc groove with a wide inner cavity and a narrow groove opening.

In order to obtain a partition wall structure with a larger area, it is often necessary to connect several ladder frames together. In one through hole 10, a second keel 2 is inserted into one half of the through hole 10, and the other second keel 2 is inserted into the other half of the through hole 10, so that the second keels 2 are respectively arranged on two sides of one first keel 1. However, this requires the through hole 10 to be thick, otherwise the second runner 2 is easily removed from the through hole 10. In order to avoid this problem, the present application is purposely provided with a connecting member 4.

Before the connecting member 4 is disposed, as shown in fig. 5, first, two ends of the first rib 13 in the width direction are respectively provided with an outer convex strip 131, the outer convex strips 131 are connected with the first rib 13 in a non-parallel manner, and a free end of the outer convex strip 131 protrudes from a surface of the first rib 13 away from the first middle rib 12; the free end of the outer convex strip 131 is connected with a stop strip 132 in a non-parallel way; the hook groove 133 is formed between the external bead 131 and the stopper 132. On the basis, the connecting member 4 includes a body 41 and two combined hooks 42 disposed on the body 41, and the combined hooks 42 include single hooks 421 capable of being connected with two hook slots 133 of a first keel 1 respectively. As shown in fig. 20, the combined hook 42 includes a connection plate 422 connected to the body 41, and the two single hooks 421 are arranged to be axisymmetrical with respect to a central axis of the connection plate 422.

The body 41 may be designed differently to accommodate different forms of partition wall construction. In this embodiment, a straight partition wall plate is constructed, wherein, as shown in fig. 10, the body 41 comprises two parallel straight plates, and the end of one straight plate is connected with the end of the other straight plate through a connecting plate 422. In order to ensure flatness, the connection plate 422 and the straight plate are generally vertically connected. As shown in fig. 8 and 9, the single hooks 421 on the left connecting plate 422 are respectively engaged with the hook grooves 133 of the first keels 1 of the left ladder frame, and the single hooks 421 on the right connecting plate 422 are respectively engaged with the hook grooves 133 of the right ladder frame, so that the two ladder frames can be connected together to form a partition plate structure with a large area. Meanwhile, in order to ensure the flatness, the outer surface of the straight plate is required to be flush with the partition plate 3.

In addition, in order to seal the upper end and the lower end of the partition plate structure, the through hole 10 can be divided into an upper half hole and a lower half hole which are mirror images of each other, and the two ends of the first keel 1 are respectively provided with the upper half hole and the lower half hole. As shown in fig. 5, the size of the upper half hole and the lower half hole is half of the through hole 10, and the two inner sides of the upper half hole and the lower half hole are respectively provided with an insertion block 101, and the size, shape and position of the insertion block 101 are consistent with those of the insertion hole 101 of the original through hole 10. On this basis, as shown in fig. 10, both ends of the portion of the connection plate 422 located between the two single hooks 421 are also provided with an upper half hole and a lower half hole, respectively. Meanwhile, in order to seal the left end and the right end of the partition board structure, the combined hook body 42 without the upper half hole and the lower half hole as shown in fig. 20 may be directly adopted, and the single hook body 421 may be engaged with the hook grooves 133 at the left end and the right end of the partition board structure.

Example 2

This embodiment is substantially the same as embodiment 1, except that: in this embodiment, an L-shaped partition wall structure is constructed, which is commonly used in the external corner or the internal corner.

As shown in fig. 13, the body 41 includes a first straight plate and a second straight plate connected in non-parallel, and ends of the first straight plate and the second straight plate are respectively connected to the connection plates 422. If the shape of the external corner or the internal corner is regular, the first straight plate and the second straight plate are generally vertically connected, and the two connecting plates are vertically connected. As shown in fig. 11 and 12, the two single hooks 421 of the upper connecting plate 422 are engaged with the hook grooves 133 of the upper ladder frame, and the two single hooks 421 of the left connecting plate 422 are engaged with the hook grooves 133 of the left ladder frame, so that the two ladder frames can be connected together to form a partition wall structure of an external corner or an internal corner.

Example 3

This embodiment is substantially the same as embodiment 1, except that: in this embodiment, a T-shaped partition plate structure is constructed.

As shown in fig. 16, the body 41 includes a third straight plate, two ends of the third straight plate are respectively provided with a connecting plate 422, the two connecting plates 422 are both connected to the third straight plate perpendicularly, and then the two connecting plates 422 are connected through another connecting plate 422, so that the connecting member 4 forms a T-shaped connecting member. As shown in fig. 14 and 15, the single hooks 421 of the three connecting plates 422 are respectively engaged with the ladders to connect the three ladders together to form a T-shaped partition plate structure.

Example 4

This embodiment is substantially the same as embodiment 1, except that: in this embodiment, a cross-shaped partition wall structure is constructed.

As shown in fig. 19, the body 41 includes two connection plates 422, one connection plate 422 is vertically connected to the other connection plate 422 such that ends of the four connection plates 422 are connected in sequence. As shown in fig. 17 and 18, the single hooks 421 of the four connecting plates 422 are respectively engaged with the ladder frames to connect the four ladder frames together to form a cross-shaped partition plate structure.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Claims (10)

1. The utility model provides a buckle formula partition wall structure which characterized in that: the ladder comprises a first keel (1) and a second keel (2) which are perpendicular to each other, wherein the first keel (1) is provided with a plurality of through holes (10), one end of the second keel (2) is inserted into the through hole (10) of one first keel (1), and the other end of the second keel is inserted into the through hole (10) of the other first keel (1) so as to form a ladder frame; the ladder comprises a ladder frame and partition boards (3) arranged on two opposite surfaces of the ladder frame; the first keel (1) comprises a first middle keel (12), first single-form bones (13) which are respectively arranged on two sides of the first middle keel (12) and are parallel to the first middle keel (12), and first connecting bones (11) which connect the first single-form bones (13) with the first middle keel (12); a groove (121) is formed among the end part of the first single bone (13) along the width direction, the first connecting bone (11) and the end part of the first single bone (12) along the width direction; the partition board (3) comprises a flat plate (31) and convex strips (32) which are arranged on the flat plate (31) and can be inserted into the grooves (121).

2. The buckle type partition wall structure according to claim 1, wherein: two ends of the first single rib (13) in the width direction are respectively provided with an external convex strip (131), the external convex strips (131) are connected with the first single rib (13) in a non-parallel manner, and the free ends of the external convex strips (131) protrude out of one surface, away from the first single rib (12), of the first single rib (13); the free end of the outer convex strip (131) is connected with a stop strip (132) in a non-parallel way; a hook groove (133) is formed between the outer convex strip (131) and the stop strip (132); still including connecting two connecting piece (4) of ladder frame, connecting piece (4) include body (41) and set up in two combination coupler body (42) of body (41), combination coupler body (42) including can with one two of first fossil fragments (1) hook groove (133) single coupler body (421) of connecting respectively.

3. The snap-in type partition wall structure according to claim 2, wherein: the combined hook body (42) comprises a connecting plate (422) connected with the body (41), and the two single hook bodies (421) are arranged in an axisymmetric manner by taking the central axis of the connecting plate (422) as an axis.

4. A snap-in type partition wall structure according to claim 3, wherein: the body (41) comprises two parallel straight plates, and the end part of one straight plate is connected with the end part of the other straight plate through the connecting plate (422).

5. A snap-in type partition wall structure according to claim 3, wherein: the body (41) comprises a first straight plate and a second straight plate which are connected in a non-parallel mode, and the ends of the first straight plate and the second straight plate are respectively connected with the connecting plate (422).

6. A snap-in type partition wall structure according to claim 3, wherein: the body (41) comprises a third straight plate, the two ends of the third straight plate are respectively provided with the connecting plates (422), and the free ends of the two connecting plates (422) are connected through the other connecting plate (422), so that the connecting piece (4) forms a T-shaped connecting piece.

7. A snap-in type partition wall structure according to claim 3, wherein: the body (41) comprises two connecting plates (422), and the ends of the four connecting plates (422) are sequentially connected to enable the connecting piece (4) to form a cross-shaped connecting piece.

8. A snap-in type partition wall structure according to claim 3, wherein: the second keel (2) comprises three parallel second single bones and a second connecting bone (21) for connecting the three second single bones, and the second connecting bone (21) is perpendicular to the second single bones; the second single rib comprises a second single rib (22) and a second single rib (23) which is arranged on two sides of the second single rib (22) and parallel to the first single rib (12), two ends of the second single rib (23) in the width direction are respectively provided with an inner convex strip (231), the inner convex strips (231) are connected with the second single rib (23) in a non-parallel mode, and the inner convex strips (231) protrude out of one surface, close to the second single rib (22), of the second single rib (23); the inner top and the inner bottom of the through hole (10) are respectively abutted with the second single rib (23), an L-shaped insert block (101) is arranged at the inner side of the through hole (10), the insert block (101) comprises a first insert part and a second insert part which are vertically connected, one end of the first insert part is abutted with the second single rib (22), and the other end of the first insert part is abutted with the free end face of the inner convex strip (231); one end of the second insertion part is abutted against the side surface of the second connecting rib (21), and the other end of the second insertion part is abutted against the side surface of the inner convex strip (231).

9. The snap-in type partition wall structure according to claim 8, wherein: the through hole (10) comprises an upper half hole and a lower half hole which are mirror images of each other, and the two ends of the first keel (1) are respectively provided with the upper half hole and the lower half hole.

10. The snap-in type partition wall structure according to claim 9, wherein: the two ends of the part of the connecting plate (422) between the two single hook bodies (421) are respectively provided with the upper half hole and the lower half hole.

Images