Medical splicing antibacterial medical plate construction method
The construction method of medical splicing antibacterial medical panels solves the problems of flammability and stability of phenolic resin boards during construction. The use of snap-fit and glue groove tooth structure achieves efficient and safe construction results, which is suitable for high-cleanliness environments such as hospitals.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- CHINA CONSTR FIRST BUILDING (GRP) CORP LTD
- Filing Date
- 2024-09-29
- Publication Date
- 2026-06-26
Smart Images

Figure CN119145589B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of building decoration technology, specifically to a construction method for medical splicing antibacterial medical panels. Background Technology
[0002] With the advancement of urbanization, the construction of supporting hospitals has gradually increased. As a place with a large flow of people, hospitals usually have high requirements for building quality, and there are various forms of interior decoration and construction. A common construction method is to fix the keel on the wall, fix the fasteners on the panels, and then hang the panels on the keel through the fasteners to achieve the installation of the panels.
[0003] However, during actual construction, the inventors discovered that the current construction method still has shortcomings, specifically:
[0004] First, the wall panels currently used for decoration are usually phenolic resin boards. However, phenolic resin boards are flammable, posing a fire risk during construction. Secondly, phenolic resin boards have poor dimensional stability and are prone to deformation, increasing the difficulty of construction, potentially leading to material waste, reduced construction efficiency, and increased construction costs. Thirdly, fasteners are usually fixed to the boards using bolts; however, bolt fixing easily causes cracks in the phenolic resin boards, further resulting in material waste, reduced construction efficiency, and increased construction costs.
[0005] Therefore, based on the above shortcomings, there is an urgent need to design a construction method for medical splicing antibacterial medical panels to address the deficiencies in the construction process of phenolic resin panels and improve construction efficiency. Summary of the Invention
[0006] The purpose of this invention is to address the aforementioned shortcomings in the current construction process of phenolic resin boards by providing a construction method for medical splicing antibacterial medical boards, thereby solving the deficiencies in the construction process of phenolic resin boards and improving construction efficiency.
[0007] To achieve the above-mentioned objectives, the present invention provides the following technical solution:
[0008] A method for constructing a medical splicing antibacterial medical panel includes the following steps:
[0009] Step A, Wall Quality Inspection: The flatness error of the wall surface used to install the antibacterial medical panel shall not exceed 5mm, and the smaller the error, the better;
[0010] Step B, Marking: According to the design drawings, mark the positions of the horizontal keel on the wall and mark the fixing points of the horizontal keel.
[0011] Step C, Drilling and Inserting Screw Sleeves: Drill holes in sequence according to the drilling marks, and then insert screw sleeves;
[0012] Step D: Install horizontal keel: Place the horizontal keel horizontally in the installation position, so that the position of the pre-made through hole on the horizontal keel corresponds to the position of the hole on the wall, and then fix the horizontal keel to the wall with screws.
[0013] Step E, Install the fasteners: Slide the fasteners to the horizontal keel so that the fasteners can slide freely along the length of the horizontal keel;
[0014] Step F, Install the antibacterial medical panel: Use fasteners to splice and fix the antibacterial medical panel onto the horizontal keel in sequence;
[0015] Step G: Apply sealant: Apply sealant to the gap between adjacent antibacterial medical panels, making the surface of the sealant flush with the surface of the antibacterial medical panels.
[0016] As the preferred technical solution of this application, in step B, the marking includes marking horizontal lines on the wall and marking vertical lines on the wall. First, according to the requirements of the decoration design drawings, before installation, select measurement control points. First, use a theodolite to mark the vertical control lines on the two sides of the corner. Fix the angle steel for hanging the lines at the upper and lower ends of the corner. Hang the vertical control lines with steel wire and mark the upper and lower ends of the control lines. Second, mark horizontal lines on the wall with a spacing of 400mm. If the horizontal line is longer than 5 meters, use a level to check the level. Finally, mark vertical lines on the wall with a spacing of 400mm. Mark the intersection of the horizontal and vertical lines. The intersection point is the fixing point of the horizontal keel.
[0017] As the preferred technical solution of this application, in step C, holes are drilled sequentially according to the intersection points in step B. The required drilling depth is 10cm and the drilling diameter is 6cm. Drilling can be done with an impact drill, or a pointed chisel can be used to carve a recess on the pre-marked intersection point before drilling with an electric drill. If steel bars are encountered in the structure during drilling, the hole position can be adjusted appropriately. After drilling, the hole is cleaned, and then the screw sleeve is inserted and rotated a few times to install it in place.
[0018] As the preferred technical solution of this application, in step D, firstly, the flatness of the wall surface must be tested before installing the horizontal keel, especially for walls with large areas, such as corridors and shared space walls. During the test, horizontal and vertical lines are stretched, and a level is used to find the deviation. Then, the horizontal keel is leveled according to the deviation. The leveling method is to put wood chips or fire-retardant strips behind the horizontal keel. The spacing between the layers behind the horizontal keel should not be greater than 150mm to prevent the horizontal keel from deforming. After the horizontal keel is installed, it needs to be inspected. The inspection method is to use a 2-meter straightedge. The horizontal and vertical deviations should not be greater than 2mm. Three rooms are randomly selected from each standard floor as an inspection batch, or three rooms are randomly selected from every 1000㎡ as an inspection batch. Each inspection batch is inspected once within 5m. Only after the inspection is qualified can the next process be carried out. Finally, the full-length horizontal keel is fixed. Holes are pre-drilled on the horizontal keel, and the positions of the horizontal keel are temporarily fixed and adjusted at both ends to make the connecting holes of the horizontal keel aligned. The horizontal keel is fixed to the wall with screws.
[0019] As the preferred technical solution of this application, the fasteners in step E include L-shaped fasteners and T-shaped fasteners. The L-shaped fasteners are used to connect the two ends of the transverse keel to the antibacterial medical board, and the T-shaped fasteners are used to connect adjacent antibacterial medical boards.
[0020] As the preferred technical solution of this application, in step F, before installing the antibacterial medical panel, structural adhesive needs to be applied in dots at intervals on the horizontal keel, and the applied structural adhesive should be full and without sagging. Then, the antibacterial medical panels are spliced and installed on the horizontal keel in sequence using fasteners. At the same time, a leveler is installed between two adjacent antibacterial medical panels. After all the antibacterial medical panels are installed in place, the leveler is used to level them so that all the antibacterial medical panels are kept on the same plane, while maintaining the gap between adjacent antibacterial medical panels at 5mm. The antibacterial medical panels are kept in place and the structural adhesive is allowed to cure. In particular, the bottom of the antibacterial medical panel is required to be 100mm away from the ground to allow for construction conditions for skirting and flooring. The top of the antibacterial medical panel is required to extend 30mm into the ceiling. Therefore, the installation of the antibacterial medical panel must be carried out before the ceiling construction.
[0021] As the preferred technical solution of this application, in step G, after the structural adhesive has cured, the leveler is removed, masking tape is applied to the edge of the antibacterial medical board, and then sealant is applied to the gap between adjacent antibacterial medical boards. After the sealant has cured, the masking tape is removed, the surface of the antibacterial medical board is cleaned, and the construction is completed.
[0022] As the preferred technical solution of this application, the antibacterial medical board is a new type of wall material made by using virgin wood pulp fiber, silicate cement and fine quartz as raw materials, processing them into core material through high temperature and high pressure steam curing technology, and then laminating flame-retardant decorative paper onto its surface. This significantly improves the fire resistance, wear resistance, moisture resistance, stain resistance and scratch resistance of the antibacterial medical board.
[0023] As the preferred technical solution of this application, the fastener is provided with a locking part; when the antibacterial medical plate is engaged with the fastener, the locking part locks the antibacterial medical plate and the fastener together; the locking part is a support foot symmetrically inclined on both sides of the fastener along the direction in which the antibacterial medical plate is inserted into the fastener; along the direction in which the antibacterial medical plate is inserted into the fastener, the distance between the support feet on both sides of the fastener increases.
[0024] As the preferred technical solution of this application, the transverse keel is provided with a glue groove for accommodating structural adhesive, the fastener is provided with a row of teeth, and a locking tooth is provided in the corresponding groove of the transverse keel, the locking tooth allowing the fastener to slide only in one direction within the groove of the transverse keel.
[0025] When the antibacterial medical panel is assembled, as the slot on the antibacterial medical panel begins to insert into the fastener, the locking teeth begin to slide into the row of teeth; when the antibacterial medical panel abuts against the fastener, the locking teeth remain abutting against the row of teeth.
[0026] As the preferred technical solution of this application, the glue groove is located at the top of the transverse keel, and the bottom of the glue groove is inclined downward.
[0027] Compared with the prior art, the beneficial effects of the present invention are as follows:
[0028] 1. The medical splicing antibacterial medical panel construction method provided by this invention has the advantages of simple construction process, fewer construction procedures, and high quality reliability. Furthermore, after the building wall is formed, the required number of antibacterial medical panels and horizontal keels can be calculated in advance based on the wall area, and then the antibacterial medical panels and horizontal keels can be prefabricated in advance. In this way, the construction speed can be greatly improved and the construction cycle can be shortened after the formal construction begins. Compared with the construction using phenolic resin boards, the fire resistance, wear resistance, moisture resistance, stain resistance, scratch resistance and other properties are significantly improved, making the construction process more environmentally friendly and safer. Furthermore, the fasteners and antibacterial medical panels are connected by a plug-in method, which increases the contact area between the fasteners and antibacterial medical panels. At the same time, the prefabricated grooves on the antibacterial medical panels ensure the stability of the groove structure. Compared with the method of directly fixing the fasteners to the panels with bolts, the plug-in method does not damage the structure of the antibacterial medical panels, reduces the occurrence of cracking of the antibacterial medical panels, reduces material loss, and helps to improve construction efficiency and reduce construction costs.
[0029] 2. The construction method for medical splicing antibacterial medical panels provided by this invention is applicable to the hanging construction of parallel panels on the interior and exterior walls of industrial and civil buildings. It is particularly suitable for high-end interior and exterior decoration of hospitals, laboratories and office buildings with high cleanliness requirements, and is suitable for widespread application.
[0030] 3. To facilitate the splicing and installation of antibacterial medical panels, there is usually a gap between the antibacterial medical panel and the fastener. After splicing, there will be some wobbling between the antibacterial medical panel and the fastener, which is not conducive to the overall adjustment of the antibacterial medical panel. The setting of the clamping part allows the antibacterial medical panel to be locked in place after it is spliced and installed. This makes the spliced and installed antibacterial medical panel a whole, which is convenient for adjustment or movement and helps to improve construction efficiency. Furthermore, the clamping part has a pre-pressure on the antibacterial medical panel. Thus, the clamping part plays a role in inspecting the antibacterial medical panel. During the splicing and installation process, the antibacterial medical panel of poor quality may crack under the action of the clamping part. This allows the antibacterial medical panel to be replaced in time, avoiding the need to replace cracked antibacterial medical panels after the overall antibacterial medical panel splicing and installation is completed, which requires more work and reduces construction efficiency. Therefore, the setting of the clamping part helps to inspect the antibacterial medical panel during splicing and installation. If the antibacterial medical panel cracks, it can be replaced in time, which helps to improve construction efficiency.
[0031] 4. The locking part consists of symmetrically inclined feet on both sides of the fastener along the direction in which the antibacterial medical plate is inserted into the fastener; the distance between the feet on both sides of the fastener increases as the antibacterial medical plate is inserted into the fastener. With this structure, on the one hand, as the antibacterial medical plate is inserted deeper, the force exerted by the feet on the antibacterial medical plate increases, and the locking effect of the feet on the antibacterial medical plate also increases, ensuring the connection between the antibacterial medical plate and the fastener; on the other hand, the feet provide unidirectional insertion for the antibacterial medical plate. Thus, after the antibacterial medical plate is inserted into the fastener, if there is a tendency for the antibacterial medical plate to move outward and detach from the fastener, the feet prevent the antibacterial medical plate from falling out, making the connection between the antibacterial medical plate and the fastener more secure.
[0032] 5. When installing the antibacterial medical panel, first fix an L-shaped fastener to the end of the horizontal keel using a limiting screw. Then fill the adhesive groove with structural adhesive. Since the horizontal keel is fixed, the structural adhesive remains in the adhesive groove. Next, insert an antibacterial medical panel into the L-shaped fastener at the end of the horizontal keel, keeping the antibacterial medical panel in place. Slide the T-shaped fastener to the other side of the first antibacterial medical panel. When the antibacterial medical panel begins to insert into the fastener, the locking teeth on the fastener begin to slide into the teeth on the horizontal keel. The interaction between the locking teeth and the teeth... When the horizontal keel vibrates, the structural adhesive in the adhesive groove flows downwards, filling the gap between the horizontal keel and the antibacterial medical panel. At the same time, as the fasteners slide, they abut against the antibacterial medical panel. Since the locking teeth still abut against the toothed strip, the antibacterial medical panel is fixed to the horizontal keel under the action of the fasteners at both ends. This cycle is repeated, and the antibacterial medical panels are spliced and installed in sequence. After the structural adhesive cures, the connection between the antibacterial medical panel and the horizontal keel becomes more secure under the dual action of the structural adhesive and the fasteners. Attached Figure Description
[0033] Figure 1 This is a flowchart illustrating one embodiment of a construction method for a medical splicing antibacterial medical panel according to this application;
[0034] Figure 2 This is a schematic diagram of the assembly structure of one embodiment of the construction method for a medical splicing antibacterial medical panel according to this application;
[0035] Figure 3 This is a cross-sectional assembly structure schematic diagram of one embodiment of a construction method for a medical splicing antibacterial medical panel according to this application;
[0036] Figure 4 This is a cross-sectional assembly structure diagram of one embodiment of the L-shaped fastener in the construction method of a medical splicing antibacterial medical panel according to this application;
[0037] Figure 5This is a cross-sectional assembly structure diagram of one embodiment of the T-type fastener in the construction method of a medical splicing antibacterial medical panel according to this application;
[0038] Figure 6 This is a schematic diagram of another embodiment of the T-type fastener used in the construction method of a medical splicing antibacterial medical panel according to this application;
[0039] Figure 7 This is a cross-sectional assembly structure diagram of another embodiment of the T-type fastener in the construction method of a medical splicing antibacterial medical panel according to this application;
[0040] Figure 8 This is a structural schematic diagram of a third embodiment of the T-type fastener in a construction method for a medical splicing antibacterial medical panel according to this application;
[0041] Figure 9 This is a schematic diagram of another embodiment of the transverse keel in the construction method of a medical splicing antibacterial medical panel according to this application;
[0042] Figure 10 This is a cross-sectional structural schematic diagram of one embodiment of the clamping teeth and tooth arrangement in the construction method of a medical splicing antibacterial medical panel according to this application.
[0043] Figure 11 This is a schematic diagram of the assembly structure of another embodiment of the construction method of a medical splicing antibacterial medical panel according to this application;
[0044] Figure 12 This is a side structural schematic diagram of another embodiment of the transverse keel in the construction method of a medical splicing antibacterial medical panel according to this application;
[0045] The diagram shows: 1-Antibacterial medical panel, 2-Horizontal keel, 21-Toothed teeth, 22-Glue groove, 3-Fastener, 31-L-type fastener, 32-T-type fastener, 33-Clamping part, 34-Feet, 35-Toothed teeth, 4-Screw, 5-Wall surface, 6-Structural adhesive, 7-Leveler, 8-Sealant. Detailed Implementation
[0046] To make the objectives, technical solutions, and advantages of the embodiments of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments.
[0047] Therefore, the following detailed description of embodiments of the present invention is not intended to limit the scope of the claimed invention, but merely illustrates some embodiments of the invention. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without inventive effort are within the scope of protection of the present invention.
[0048] It should be noted that, unless otherwise specified, the embodiments and features and technical solutions in the present invention can be combined with each other.
[0049] It should be noted that similar labels and letters in the following figures indicate similar items. Therefore, once an item is defined in one figure, it does not need to be further defined and explained in subsequent figures.
[0050] In the description of this invention, it should be noted that the terms "upper," "lower," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, or the orientation or positional relationship commonly used when the product of this invention is in use, or the orientation or positional relationship commonly understood by those skilled in the art. These terms are only for the convenience of describing this invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this invention. In addition, the terms "first," "second," etc., are only used to distinguish descriptions and should not be construed as indicating or implying relative importance.
[0051] Example 1: See Figures 1-5 As shown,
[0052] This embodiment provides a construction method for a medical splicing antibacterial medical panel, including the following steps:
[0053] Step A, Quality Inspection of Wall Surface 5: The flatness error of the wall surface 5 used to install the antibacterial medical panel 1 shall not exceed 5mm, and the smaller the error, the better;
[0054] Step B, Marking: According to the design drawings, mark the positions of the horizontal keel 2 on the wall 5, and mark the fixing points of the horizontal keel 2.
[0055] Step C, Drilling and Inserting Screw Sleeves: Drill holes in sequence according to the drilling marks, and then insert screw sleeves;
[0056] Step D, Install horizontal keel 2: Place horizontal keel 2 horizontally in the installation position, so that the position of the pre-made through hole on horizontal keel 2 corresponds to the position of the hole on wall 5, and then use screw 4 to fix horizontal keel 2 to wall 5.
[0057] Step E, Install fastener 3: Slide fastener 3 to the horizontal keel 2 so that fastener 3 can slide freely along the length of the horizontal keel 2;
[0058] Step F, Install antibacterial medical panel 1: Use fasteners 3 to sequentially splice and fix the antibacterial medical panel 1 onto the horizontal keel 2;
[0059] Step G: Apply sealant 8: Apply sealant 8 to the gap between adjacent antibacterial medical panels 1, so that the surface of sealant 8 is flush with the surface of antibacterial medical panel 1.
[0060] As a preferred embodiment, based on the above method, further, in step B, the marking includes horizontal lines marked on the wall surface 5 for the horizontal keel 2 and vertical lines marked on the wall surface 5. First, according to the requirements of the decoration design drawings, before installation, select measurement control points. First, use a theodolite to mark the vertical control lines on the two sides of the corner. Fix the angle steel for hanging the lines at the upper and lower ends of the corner. Hang the vertical control lines with steel wire and mark the upper and lower ends of the control lines. Second, mark the horizontal lines marked on the wall surface 5 for the horizontal keel 2, requiring a spacing of 400mm. If the length of the horizontal line exceeds 5 meters, a level must be used to measure the level. Finally, mark the vertical lines marked on the wall surface 5, requiring a spacing of 400mm. Mark the intersection of the horizontal and vertical lines. The intersection point is the fixing point of the horizontal keel 2.
[0061] As a preferred embodiment, based on the above method, further, in step C, holes are drilled sequentially according to the intersection points in step B, requiring a drilling depth of 10cm and a drilling diameter of 6cm. Drilling can be done with an impact drill, or a pointed chisel can be used to first carve a recess on the pre-marked intersection point, and then an electric drill can be used to drill the hole. If steel bars in the structure are encountered during drilling, the hole position can be adjusted appropriately. After the hole is formed, it should be cleaned, and then the screw sleeve should be inserted and rotated a few times to install it in place.
[0062] As a preferred embodiment, based on the above method, further, in step D, firstly, the flatness of the wall surface 5 must be checked before installing the horizontal keel 2, especially for large wall surfaces 5, such as corridor and shared space walls 5. During the check, horizontal and vertical lines are drawn, and a level is used to find the deviation. Then, the horizontal keel 2 is leveled according to the deviation. The leveling method is to place sawdust or fire-retardant strips behind the horizontal keel 2. The spacing between the layers behind the horizontal keel 2 should not exceed 150mm to prevent deformation of the horizontal keel 2. After the horizontal keel 2 is installed, it needs to be inspected. The inspection method is to use a 2-meter straightedge, and the horizontal and vertical deviations should not exceed 2mm. Three rooms are randomly selected from each standard floor as an inspection batch, or three rooms are randomly selected from every 1000㎡ as an inspection batch. Each inspection batch is inspected once within 5m. Only after the inspection is qualified can the next process be carried out. Finally, fix the full-length horizontal keel 2. Drill holes in the horizontal keel 2 in advance, and temporarily fix and adjust the position of the horizontal keel 2 at both ends so that the connecting holes of the horizontal keel 2 are aligned. Fix the horizontal keel 2 to the wall 5 with screws 4.
[0063] As a preferred embodiment, based on the above method, the fastener 3 in step E further includes an L-shaped fastener 31 and a T-shaped fastener 32. The L-shaped fastener 31 is used to connect the two ends of the transverse keel 2 to the antibacterial medical board 1, and the T-shaped fastener 32 is used to connect adjacent antibacterial medical boards 1.
[0064] As a preferred embodiment, based on the above method, further, in step F, before installing the antibacterial medical panel 1, structural adhesive 6 needs to be applied in dots at intervals on the horizontal keel 2, and the applied structural adhesive 6 should be full and without sagging. Then, the antibacterial medical panels 1 are spliced and installed on the horizontal keel 2 in sequence using fasteners 3. At the same time, a leveler 7 is installed between two adjacent antibacterial medical panels 1. After all the antibacterial medical panels 1 are installed in place, the leveler 7 is used to level them so that all the antibacterial medical panels 1 are kept on the same plane, while maintaining the gap between adjacent antibacterial medical panels 1 at 5mm, keeping the position of the antibacterial medical panels 1 still, and waiting for the structural adhesive 6 to cure. In particular, the bottom of the antibacterial medical panel 1 is required to be 100mm away from the ground to leave room for the construction of skirting boards and flooring, and the top of the antibacterial medical panel 1 is required to extend 30mm into the ceiling. Therefore, the installation of the antibacterial medical panel 1 must be carried out before the ceiling construction.
[0065] As a preferred embodiment, based on the above method, in step G, after the structural adhesive 6 has cured, the leveler 7 is removed, masking tape is applied to the edge of the antibacterial medical board 1, and then sealant 8 is applied to the gap between adjacent antibacterial medical boards 1. After the sealant 8 has cured, the masking tape is removed, the surface of the antibacterial medical board 1 is cleaned, and the construction is completed.
[0066] As a preferred embodiment, based on the above method, the antibacterial medical board 1 is a new type of wall material 5 made by using virgin wood pulp fiber, silicate cement, and fine quartz as raw materials, processing them into core material through high temperature and high pressure steam curing technology, and then laminating flame-retardant decorative paper onto its surface. This significantly improves the fire resistance, wear resistance, moisture resistance, stain resistance, scratch resistance, and other properties of the antibacterial medical board 1.
[0067] The construction method for the medical splicing antibacterial medical panel 1 provided by this invention has the advantages of simple construction process, fewer construction procedures, and high quality reliability. Furthermore, after the building wall is formed, the required quantity of antibacterial medical panels 1 and horizontal keels 2 can be calculated in advance based on the wall area, and then the antibacterial medical panels 1 and horizontal keels 2 can be prefabricated. This greatly improves the construction speed and shortens the construction cycle after the formal construction begins. Compared with the construction using phenolic resin boards, the fire resistance, wear resistance, moisture resistance, stain resistance, and scratch resistance are significantly improved, making the construction process more environmentally friendly and safer. Furthermore, the fastener 3 and the antibacterial medical panel 1 are connected by an interlocking method, increasing the contact area between them. Simultaneously, the prefabricated slots on the antibacterial medical panel 1 ensure the stability of the slot structure. Compared to directly fixing the fastener 3 to the panel with bolts, the interlocking method does not damage the structure of the antibacterial medical panel 1, reducing the likelihood of cracking and material loss, thus improving construction efficiency and reducing construction costs.
[0068] Example 2: See Figure 6 and Figure 7 As shown,
[0069] As a preferred embodiment, based on Embodiment 1, the fastener 3 is further provided with a locking part 33; when the antibacterial medical plate 1 is engaged with the fastener 3, the locking part 33 locks the antibacterial medical plate 1 and the fastener 3 together.
[0070] To facilitate the splicing and installation of the antibacterial medical panel 1, there is usually a gap between the antibacterial medical panel 1 and the fastener 3. After splicing, there will be some wobbling between the antibacterial medical panel 1 and the fastener 3, which is not conducive to the overall adjustment of the antibacterial medical panel 1. The setting of the clamping part 33 makes the antibacterial medical panel 1 and the fastener 3 clamp together tightly. In this way, the spliced and installed antibacterial medical panel 1 becomes a whole, which facilitates the adjustment or movement of the antibacterial medical panel 1 and improves construction efficiency. Furthermore, the clamping part 33 has a pre-pressure on the antibacterial medical panel 1, so the clamping part serves as a test part for the antibacterial medical panel 1. The purpose of the clamping part 33 is to facilitate the inspection of the antibacterial medical panel 1 during the splicing and installation process. If cracks occur, the panel can be replaced promptly, avoiding the need for additional work and reduced efficiency if cracks appear after the entire antibacterial medical panel 1 has been assembled.
[0071] As a preferred embodiment, based on the above method, the locking part 33 is further provided as a support leg 34 symmetrically inclined on both sides of the fastener 3 along the direction in which the antibacterial medical plate 1 is inserted into the fastener 3; along the direction in which the antibacterial medical plate 1 is inserted into the fastener 3, the distance between the support legs 34 on both sides of the fastener 3 becomes larger and larger.
[0072] With the above structure, on the one hand, as the antibacterial medical plate 1 is inserted deeper, the force exerted by the support leg 34 on the antibacterial medical plate 1 increases, and the clamping effect of the support leg 34 on the antibacterial medical plate 1 also increases, ensuring the connection between the antibacterial medical plate 1 and the fastener 3; on the other hand, the support leg 34 plays a one-way insertion role in the insertion of the antibacterial medical plate 1. Thus, after the antibacterial medical plate 1 and the fastener 3 are inserted, when the antibacterial medical plate 1 has a tendency to move outward and detach from the fastener 3, the support leg 34 prevents the antibacterial medical plate 1 from detaching, making the connection between the antibacterial medical plate 1 and the fastener 3 more secure.
[0073] Example 3: See Figures 8 to 1 As shown in Figure 8,
[0074] As a preferred embodiment, based on Embodiment 1, the transverse keel 2 is further provided with a glue groove 22 for accommodating structural adhesive 6, the fastener 3 is provided with a toothed rack 21, and a locking tooth 35 is provided in the groove of the transverse keel 2, the locking tooth 35 making the fastener 3 slide only in one direction in the groove of the transverse keel 2.
[0075] When the antibacterial medical panel 1 is assembled, when the slot on the antibacterial medical panel 1 begins to insert into the fastener 3, the locking tooth 35 begins to slide into the toothed row 21; when the antibacterial medical panel 1 abuts against the fastener 3, the locking tooth 35 remains abutting against the toothed row 21.
[0076] Using the above structure, when installing the antibacterial medical panel 1, firstly, an L-shaped fastener 31 is fixed to the end of the transverse keel 2 using a limiting screw. Then, structural adhesive 6 is filled into the adhesive groove 22. Since the transverse keel 2 is fixed, the structural adhesive 6 remains in the adhesive groove 22. Then, an antibacterial medical panel 1 is inserted into the L-shaped fastener 31 at the end of the transverse keel 2. Keeping the position of the antibacterial medical panel 1 unchanged, the T-shaped fastener 32 is slid to the other side of the first antibacterial medical panel 1. When the antibacterial medical panel 1 begins to be inserted into the fastener 3, the locking teeth 35 on the fastener 3 begin to slide into the row of teeth 21 on the transverse keel 2. Under the interaction between 1, the transverse keel 2 will vibrate, causing the structural adhesive 6 in the adhesive groove 22 to flow downward and fill the gap between the transverse keel 2 and the antibacterial medical board 1. At the same time, as the fastener 3 slides, the fastener 3 abuts against the antibacterial medical board 1. Since the locking tooth 35 still abuts against the tooth 21 at this time, the antibacterial medical board 1 is fixed on the transverse keel 2 under the action of the fasteners 3 at both ends of the antibacterial medical board 1. This cycle is repeated to splice and install the antibacterial medical board 1 in sequence. After the structural adhesive 6 is cured, the connection between the antibacterial medical board 1 and the transverse keel 2 is more secure under the dual action of the structural adhesive 6 and the fastener 3.
[0077] In traditional construction processes, the installation of panels typically involves first adjusting the panel's position to a suitable location, and then applying adhesive to the joints for fixation. However, in panel hanging applications like the one described in this application, because the horizontal keel is installed on the back of the panel, the gap between the panel and the wall is narrow after installation. Directly applying adhesive between the panel and the wall at the joint between the horizontal keel and the panel is inconvenient, affecting construction efficiency. Furthermore, the quality of the adhesive application cannot be guaranteed, reducing the reliability of the connection between the panel and the horizontal keel. Using the above structure, structural adhesive 6 is applied to the horizontal keel 2 before installing the antibacterial medical panel 1. This facilitates operation and ensures sufficient adhesive usage. Then, by installing the fasteners 3, the horizontal keel 2 vibrates, causing the structural adhesive 6 to flow between the horizontal keel 2 and the antibacterial medical panel 1, thus improving construction efficiency and ensuring the stability of the antibacterial medical panel 1 after installation.
[0078] As a preferred embodiment, based on the above method, the glue groove 22 is further located at the top of the transverse keel 2, and the bottom of the glue groove 22 is inclined downward.
[0079] The adhesive groove 22 is set at the top of the transverse keel 2. The structural adhesive 6 flowing from the adhesive groove 22 can flow downward from the top of the transverse keel 2, increasing the area of the structural adhesive 6 coating and increasing the stability of the transverse keel 2 after it is bonded to the antibacterial medical board 1. Furthermore, the bottom of the adhesive groove 22 is set at an angle downward. When the transverse keel 2 vibrates, the structural adhesive 6 can flow downward from the adhesive groove 22 more easily. This is beneficial for the structural adhesive 6 to fill the gap between the transverse keel 2 and the antibacterial medical board 1, which further helps to improve the stability of the antibacterial medical board 1 after installation.
[0080] The above embodiments are only used to illustrate the present invention and are not intended to limit the technical solutions described herein. Although the present invention has been described in detail with reference to the above embodiments, the present invention is not limited to the specific embodiments described above. Therefore, any modifications or equivalent substitutions to the present invention, as well as all technical solutions and improvements that do not depart from the spirit and scope of the invention, are covered within the scope of the claims of the present invention.
Claims
1. A method for constructing a medical splicing antibacterial medical panel, characterized in that, Includes the following steps: Step A, Wall Quality Inspection: The flatness error of the wall surface used to install the antibacterial medical panel shall not exceed 5mm, and the smaller the error, the better; Step B, Marking: According to the design drawings, mark the positions of the horizontal keel on the wall and mark the fixing points of the horizontal keel. Step C, Drilling and Inserting Screw Sleeves: Drill holes in sequence according to the drilling marks, and then insert screw sleeves; Step D: Install horizontal keel: Place the horizontal keel horizontally in the installation position, so that the position of the pre-made through hole on the horizontal keel corresponds to the position of the hole on the wall, and then fix the horizontal keel to the wall with screws. Step E, Install the fasteners: Slide the fasteners to the horizontal keel so that the fasteners can slide freely along the length of the horizontal keel; Step F, Install the antibacterial medical panel: Use fasteners to splice and fix the antibacterial medical panel onto the horizontal keel in sequence; Step G: Apply sealant: Apply sealant to the gap between adjacent antibacterial medical panels, making the surface of the sealant flush with the surface of the antibacterial medical panels; In step F, before installing the antibacterial medical panels, structural adhesive needs to be applied in dots at intervals on the horizontal keel, ensuring the adhesive is fully applied without sagging. Then, the antibacterial medical panels are sequentially spliced and installed on the horizontal keel using fasteners. Simultaneously, a leveling device is installed between adjacent antibacterial medical panels. After all antibacterial medical panels are in place, they are leveled using the leveling device to ensure they are all on the same plane, maintaining a 5mm gap between adjacent panels. The panels remain in place while waiting for the structural adhesive to cure. The bottom of the antibacterial medical panel should be 100mm from the ground to allow for skirting and flooring installation. The top of the antibacterial medical panel should extend 30mm into the ceiling. Therefore, the installation of the antibacterial medical panels must be carried out before the ceiling construction. The transverse keel is provided with a glue groove for accommodating structural adhesive. The fastener is provided with a row of teeth, and a locking tooth is provided in the corresponding groove of the transverse keel, which allows the fastener to slide in only one direction within the groove of the transverse keel. When the antibacterial medical panel is being assembled, as the slot on the antibacterial medical panel begins to insert into the fastener, the locking teeth begin to slide into the row of teeth; when the antibacterial medical panel abuts against the fastener, the locking teeth remain abutting against the row of teeth. When the antibacterial medical panel is inserted into the fastener, the locking teeth on the fastener begin to slide into the row of teeth on the transverse keel. Under the interaction between the locking teeth and the row of teeth, the transverse keel will vibrate, causing the structural adhesive in the glue groove to flow downward and fill the gap between the transverse keel and the antibacterial medical panel.
2. The construction method of a medical splicing antibacterial medical panel as described in claim 1, characterized in that: In step B, the marking includes marking horizontal lines for the keel on the wall and marking vertical lines on the wall. First, according to the decoration design drawings, select measurement control points before installation. First, use a theodolite to mark the vertical control lines on the two sides of the corner. Fix angle steel for hanging the lines at the upper and lower ends of the corner. Hang the vertical control lines with steel wire and mark the upper and lower ends of the control lines. Second, mark horizontal lines for the keel on the wall, requiring a spacing of 400mm. If the horizontal line is longer than 5 meters, a level must be used to check the level. Finally, mark vertical lines on the wall, requiring a spacing of 400mm. Mark the intersection of the horizontal and vertical lines. The intersection point is the fixing point of the horizontal keel.
3. The construction method of a medical splicing antibacterial medical panel as described in claim 1, characterized in that: In step C, holes are drilled sequentially according to the intersection points in step B. The required drilling depth is 10cm and the drilling diameter is 6cm. If steel bars are encountered in the structure during drilling, the hole position is adjusted appropriately. After drilling, the hole is cleaned, and then the screw sleeve is inserted and rotated a few times to install it in place.
4. The construction method of a medical splicing antibacterial medical panel as described in claim 1, characterized in that: In step D, firstly, the flatness of the wall surface must be checked before installing the horizontal keel. During the check, a horizontal and vertical line is stretched, and a level is used to find the deviation. Then, the horizontal keel is leveled according to the deviation. The leveling method is to put wood chips or fire-retardant strips behind the horizontal keel. The spacing between the layers behind the horizontal keel should not be greater than 150mm to prevent the horizontal keel from deforming. After the horizontal keel is installed, it needs to be inspected. The inspection method is to use a 2-meter straightedge. The horizontal and vertical deviations should not be greater than 2mm. Three rooms are randomly selected from each standard floor as an inspection batch, or three rooms are randomly selected from every 1000㎡ as an inspection batch. Each inspection batch is inspected once within 5m. Only after the inspection is qualified can the next process be carried out. Finally, the full-length horizontal keel is fixed. Holes are pre-drilled on the horizontal keel, and the positions of the horizontal keel are temporarily fixed and adjusted at both ends to make the connecting holes of the horizontal keel aligned. The horizontal keel is fixed to the wall with screws.
5. The construction method of a medical splicing antibacterial medical panel as described in claim 1, characterized in that: The fasteners in step E include L-shaped fasteners and T-shaped fasteners. The L-shaped fasteners are used to connect the two ends of the horizontal keel to the antibacterial medical board, and the T-shaped fasteners are used to connect adjacent antibacterial medical boards.
6. The construction method of a medical splicing antibacterial medical panel as described in claim 1, characterized in that: In step G, after the structural adhesive has cured, remove the leveling tool, apply masking tape to the edge of the antibacterial medical panel, then apply sealant to the gap between adjacent antibacterial medical panels. After the sealant has cured, remove the masking tape, clean the surface of the antibacterial medical panel, and the construction is complete.
7. A method for constructing a medical splicing antibacterial medical panel as described in any one of claims 1-6, characterized in that: The antibacterial medical board is a new type of wall material made from virgin wood pulp fiber, silicate cement, and fine quartz as raw materials, which are processed into core material through high temperature and high pressure steam curing, and then flame-retardant decorative paper is laminated onto its surface.
8. The construction method of a medical splicing antibacterial medical panel as described in claim 7, characterized in that: The fastener is provided with a locking part; when the antibacterial medical plate is engaged with the fastener, the locking part locks the antibacterial medical plate and the fastener together; the locking part is a support foot symmetrically inclined on both sides of the fastener along the direction in which the antibacterial medical plate is inserted into the fastener; along the direction in which the antibacterial medical plate is inserted into the fastener, the distance between the support feet on both sides of the fastener increases.