CN117552546B - Anti-seismic tent made of multilayer aluminum alloy and manufacturing method thereof - Google Patents

Abstract

The application relates to the field of tent houses, in particular to an anti-seismic tent house manufactured by adopting a plurality of layers of aluminum alloy and a manufacturing method thereof, wherein the anti-seismic tent house manufactured by adopting the plurality of layers of aluminum alloy comprises: the bottom awning frame comprises a plurality of cross bars and a plurality of vertical bars, wherein the vertical bars are fixedly connected with the ground, the cross bars are connected end to form a plurality of tips, and the tips are in one-to-one correspondence with the upper ends of the vertical bars and are fixedly connected; the roof frame comprises two bent diagonal bracing pieces, wherein the two diagonal bracing pieces are in one-to-one correspondence with the cross bars on two opposite sides and are hinged, and each diagonal bracing piece and the corresponding cross bar enclose a triangle; a top awning cloth covered on the canopy frame and supported by the diagonal bracing piece; the adjusting component is arranged between the diagonal bracing piece and the cross rod and is used for adjusting the inclination angle of the diagonal bracing piece. According to the tent, different weather conditions can be effectively treated by adjusting the inclination angle of the diagonal bracing piece, and the safety of the tent is improved.

Description

Anti-seismic tent made of multilayer aluminum alloy and manufacturing method thereof

Technical Field

The application relates to the technical field of tent houses, in particular to an anti-seismic tent house manufactured by adopting multilayer aluminum alloy and a manufacturing method thereof.

Background

A tent is a movable building and generally comprises a tent support made of an aluminum alloy material and a tent cloth erected on the tent support. The tent mainly provides various temporary movable tents for outdoor activities, tourism, leisure, celebration activities, earthquake relief and the like. The tent is movable and convenient to set up on site, so that the tent is widely used.

The tent is usually built outdoors, and the weather outdoors can change to a certain extent. In windy weather, the tent may topple over due to the large side wind load. In snowy weather, more snow may exist on the tarpaulin at the top of the tent so that the tent is overwhelmed by bearing a larger snow load. In heavy rain, as the roof of the tent is covered with the tent cloth, the tent cloth is sunk inwards to accumulate water, so that the tent is collapsed. Therefore, different weather conditions put different requirements on the carrying capacity of the tent, and the existing tent cannot effectively adapt to different external weather conditions.

Disclosure of Invention

In order to solve the problem that the middle tent cannot adapt to different weather conditions, the application provides an anti-seismic tent manufactured by adopting multi-layer aluminum alloy and a manufacturing method thereof.

In a first aspect, the application provides an antidetonation formula covering or awning on a car, boat, etc. room of adoption multilayer aluminum alloy preparation, include:

the bottom awning frame comprises a plurality of cross bars and a plurality of vertical bars, wherein the vertical bars are fixedly connected with the ground, the cross bars are connected end to form a plurality of tips, and the tips are in one-to-one correspondence with the upper ends of the vertical bars and are fixedly connected;

the roof frame comprises two bent diagonal bracing pieces, wherein the two diagonal bracing pieces are in one-to-one correspondence with the cross bars on two opposite sides and are hinged, and each diagonal bracing piece and the corresponding cross bar enclose a triangle;

a top awning cloth covered on the canopy frame and supported by the diagonal bracing piece;

the adjusting component is arranged between the diagonal bracing piece and the cross rod and is used for adjusting the inclination angle of the diagonal bracing piece.

Through adopting above-mentioned technical scheme, firstly, during sunny day or cloudy day, through the inclination of adjusting component adjustment bracing piece, make the roof frame middle high both ends low to the convenience of customers normal use covering or awning on a car, boat, etc. room. Second, in heavy rain or heavy snow weather, the inclination angle of the diagonal bracing piece is adjusted through the adjusting component to be continuously changed, so that two side edges of the triangle are continuously changed in an inclined mode, rainwater or snow attached to the top awning cloth can slide down, and the pressure of the rainwater and the snow to the top awning cloth is reduced. Thirdly, when in windy weather, the inclination angle of the inclined stay bar is adjusted to reduce the contact area between wind and top tarpaulin in the direction of incoming wind, further reduce the wind load born by the tent, and further reduce the risk that the tent may collapse. When the wind power is large, the flat top tarpaulin can be completely laid, so that the wind load born by the tent is reduced. According to the awning, the inclined angle of the inclined strut member can be effectively adjusted through the adjusting component, so that the safety of the awning can be improved.

Optionally, the diagonal members are all provided as ropes, and two ends of each rope are hinged with the cross rod; the adjusting assembly comprises an adjusting rod, an adjusting ring and a locking piece, the adjusting rod is in sliding connection with the cross rod, the sliding direction is parallel to the axis direction of the cross rod, the adjusting ring is fixedly installed at the upper end of the adjusting rod, the rope penetrates through the adjusting ring, and the locking piece is used for locking the adjusting rod on the cross rod after the adjusting rod slides.

Through adopting above-mentioned technical scheme, through the removal regulation pole, can drive the adjusting ring and remove, and then change the butt position of adjusting ring and rope to realize the regulation to roof frame inclination. Firstly, the rope can be used as a supporting frame to support the top tarpaulin; and the rope can effectively resist wind load, snow load and the like as a flexible support. Secondly, the ropes are made of light materials, so that on one hand, a user can conveniently carry all parts of the tent, and the carrying load of the user is reduced; on the other hand, if the canopy collapses under extreme weather conditions, the lightweight rope falls down and does not injure people in the tent, so that the safety of the tent is further improved. Thirdly, set up the bracing piece as the rope, improved the convenience of adjusting the bracing piece.

Optionally, the hole that slides has been seted up to the horizontal pole, slide the extending direction in hole with the axis direction of horizontal pole is parallel, adjust the pole and wear to locate in the hole that slides, the locking piece include with adjust pole threaded connection's butt piece and latch segment, the butt piece with the horizontal pole is close to the one side butt of bracing piece, the latch segment with the horizontal pole is kept away from one side butt of butt piece.

Through adopting above-mentioned technical scheme, the hole of sliding can effectively restrict the direction of movement of adjusting the pole to the inclination of diagonal brace is conveniently adjusted. When the adjustable rod is adjusted, the position of the adjustable rod on the height is moved firstly, and then the adjustable rod is initially abutted and fixed through the abutting block, so that the adjustable rod is more labor-saving, and finally the adjustable rod is locked through the locking block, so that the aim of locking is fulfilled. First, adjust the inclination that pole can effectively adjust diagonal brace in order to adapt to different weather conditions. Secondly, the fixed adjusting rod can play a role in vertical support, and the bearing capacity of the tent is further improved.

Optionally, the montant includes sleeve and loop bar, the sleeve is used for with ground fixed connection, the loop bar is inserted and is located in the sleeve, the loop bar keep away from telescopic one end with the horizontal pole can dismantle and be connected, many still be connected with connection structure between the loop bar, connection structure is used for with ground parallel arrangement, be provided with lifting unit in the canopy frame, lifting unit is used for the drive connection structure goes up and down.

Through adopting above-mentioned technical scheme, lifting unit can drive connection structure and go up and down, and then can drive the loop bar and keep away from the sleeve to can adjust the height of whole covering or awning on a car, boat, etc. room. First, the height of the tent is adjustable to enhance the comfort of the user using the tent. Second, the height of the tent is adjustable, so that the convenience of tent assembly is improved. When the awning is assembled, the height of the awning room is reduced, so that the awning frame and the awning cloth can be installed, and after the awning frame is installed, the awning frame is lifted up again, and other tools are not needed, so that the awning is more convenient and quicker. Third, the setting of connection structure can once adjust a plurality of loop bars and keep away from the sleeve, has improved the convenience of covering or awning on a car, boat, etc. room altitude mixture control. Fourth, when encountering heavy wind, heavy rain and heavy snow weather, the height of the tent can be reduced, and the bearing capacity of the whole vertical rod is improved.

Optionally, the lifting assembly includes lift sleeve, lift loop bar and lock pin, the lift sleeve is used for with ground fixed connection, the lift loop bar wears to locate in the lift sleeve, just the lift loop bar is located the lift sleeve is kept away from one side on ground, the first cotter hole of multiunit has been seted up in the extending direction of lift loop bar, the second cotter hole has been seted up on the lift sleeve, the lock pin wears to locate in the first cotter hole with the second cotter hole.

Through adopting above-mentioned technical scheme, first, can effectively adjust the height of covering or awning on a car, boat, etc. room through lift sleeve, lift loop bar and locking pin, only need adjust the position in first cotter hole and second cotter hole, utilize the locking pin can lock. Secondly, the fixed lifting sleeve and the lifting sleeve rod can serve as middle support columns of the tent, and play a certain supporting role, so that the bearing capacity of the tent under different weather conditions is improved.

Optionally, connection structure includes two connecting rods, two the connecting rod middle part articulates in order to form the stull structure, lift loop bar is kept away from lift telescopic one end fixed connection is in two the connecting rod articulates the department, the connecting rod with the loop bar is kept away from telescopic one end can dismantle the connection.

Through adopting above-mentioned technical scheme, first, the connection structure of scissors support can play certain supporting role after connecting, improves the horizontal anti-load ability of covering or awning on a car, boat, etc. room. Secondly, the scissors support structure is convenient to contract, so that space can be effectively saved, and convenience in transporting parts to an installation site by a user is improved.

Optionally, the anti-seismic assembly is further included, the anti-seismic assembly is connected between the lifting sleeve and the ground, the anti-seismic assembly comprises a bottom plate, an elastic piece and a top plate, the bottom plate is fixedly connected with the ground, the elastic piece is fixedly connected between the bottom plate and the top plate, and one surface, far away from the bottom plate, of the top plate is fixedly connected with the lifting assembly.

By adopting the technical scheme, the anti-seismic assembly can further enhance the adaptability of the tent to different natural disasters, and further enhance the safety of the tent. The elastic piece can effectively absorb earthquake waves, so that the earthquake resistance of the tent is improved.

Optionally, still include a plurality of side tarpaulins, each side of bottom frame sets up one side tarpaulin, the top tarpaulin with side tarpaulin can dismantle the connection, top tarpaulin lower extreme extends to the cover side tarpaulin upper end, and is located the side tarpaulin outside.

Through adopting above-mentioned technical scheme, the installation mode of side tarpaulin and top tarpaulin can improve the gas tightness and the water proofness of tarpaulin, therefore can further improve user's comfort level of using.

Optionally, still include and wind the subassembly, it includes reel pole and knob to wind the subassembly, reel pole rotate connect in two between the montant, the both ends of reel pole stretch out outside the covering or awning on a car, boat, etc. room, just reel the pole and be located the montant is kept away from the one end of horizontal pole, side tarpaulin wind reel in reel pole periphery, knob fixed connection in reel pole stretch out the one end outside the covering or awning on a car, boat, etc.

Through adopting above-mentioned technical scheme, when the high change of covering or awning on a car, boat, etc. room, can wind or emit side tarpaulin through adjusting the rotation state of rolling up the pole this moment, therefore make side tarpaulin can make adaptive adjustment according to the high of covering or awning on a car, boat, etc. room. The winding rod is convenient for installing the contralateral tarpaulin.

In a second aspect, the application provides a method for manufacturing an anti-seismic tent made of multi-layer aluminum alloy, which comprises the following steps:

s1, fixedly connecting a plurality of vertical rods with the ground, and then installing a plurality of cross rods on one side of the vertical rods far away from the ground, wherein the vertical rods and the cross rods are connected to form a bottom awning frame;

s2, hinging a plurality of diagonal members with the cross rod, and connecting the diagonal members at two ends of the cross rod to form a triangular roof frame;

s3, installing a top tarpaulin on one surface of the diagonal bracing piece, which is far away from the cross rod, and fixedly connecting the side edge of the top tarpaulin with the cross rod;

s4, installing an adjusting component between the diagonal bracing piece and the cross rod.

Through adopting above-mentioned technical scheme, improved the convenience of covering or awning on a car, boat, etc. room installation, can adjust the inclination of bracing piece through adjusting part simultaneously after the installation is accomplished to make covering or awning on a car, boat, etc. room can adapt to different weather conditions.

In summary, the present application includes at least one of the following beneficial technical effects:

1. according to the tent, different weather conditions can be effectively treated by adjusting the inclination angle of the diagonal bracing piece through the adjusting component, so that the safety of the tent can be improved;

2. the rope improves the convenience of adjusting the diagonal bracing piece; the rope can be used as a supporting frame to support the top tarpaulin; the ropes are made of light materials, so that a user can conveniently carry all parts of the tent, and the carrying load of the user is reduced; if the canopy collapses under extreme weather conditions, the lightweight ropes can not smash people in the tent when falling down, so that the safety of the tent is further improved;

3. the height of the tent can be adjusted, so that the comfort level of a user in using the tent can be enhanced; the convenience of tent assembly is improved; the connecting structure can be used for adjusting the plurality of loop bars away from the sleeve at one time, so that the convenience of height adjustment of the tent is improved; when the weather is in heavy wind, heavy rain and heavy snow, the bearing capacity of the whole vertical rod can be improved by reducing the height of the tent;

4. when the height of the tent is changed, the winding assembly can wind or pay out the side tent cloth, so that the side tent cloth can be adaptively adjusted according to the height of the tent.

Drawings

Fig. 1 is a schematic diagram of an earthquake-resistant housing (without top and side tarpaulins) made of a multi-layer aluminum alloy according to an embodiment of the present application.

Fig. 2 is a schematic cross-sectional view of an earthquake-resistant housing made of a multi-layered aluminum alloy in accordance with an embodiment of the present application.

Fig. 3 is an enlarged schematic view at a in fig. 2.

FIG. 4 is a schematic cross-sectional view of an embodiment of the present application where a side area of an earthquake-resistant housing is fabricated from multiple layers of aluminum alloy.

Fig. 5 is an enlarged schematic view at B in fig. 4.

Fig. 6 is a schematic diagram of a connection structure according to an embodiment of the present application.

Fig. 7 is an enlarged schematic view at C in fig. 2.

Reference numerals illustrate:

1. a bottom awning frame; 11. a cross bar; 111. a slip hole; 12. a vertical rod; 121. a sleeve; 122. a loop bar; 2. a canopy frame; 21. a diagonal bracing member; 3. a top awning cloth; 4. a side tarpaulin; 5. an adjustment assembly; 51. an adjusting rod; 52. an adjusting ring; 53. a locking member; 531. an abutment block; 532. a locking block; 6. a lifting assembly; 61. lifting the sleeve; 611. a second pin hole; 62. lifting the loop bar; 621. a first pin hole; 63. a locking pin; 7. an anti-seismic assembly; 71. a bottom plate; 72. an elastic member; 73. a top plate; 8. a winding assembly; 81. a winding rod; 82. a knob; 9. a connecting rod; 10. and (5) diagonal bracing.

Detailed Description

The present application is described in further detail below with reference to fig. 1-7.

It should be noted that, in the description of the present application, it should be understood that the terms "center," "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, merely for convenience in describing the present application and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present application.

The embodiment of the application discloses an anti-seismic tent made of multilayer aluminum alloy and a manufacturing method thereof.

In a first aspect, embodiments of the present application disclose an earthquake-resistant housing made of a multi-layered aluminum alloy.

Referring to fig. 1 and 2, an earthquake-resistant housing made of a multi-layered aluminum alloy includes a bottom canopy frame 1, a ceiling frame 2, a top canopy 3, side canopy 4, an adjusting unit 5, a lifting unit 6, an earthquake-resistant unit 7, and a winding unit 8. The tent referred to in this application is a small tent.

Referring to fig. 1, the canopy frame 1 includes a plurality of cross bars 11 and vertical bars 12, and the vertical bars 12 are fixedly connected to the ground, specifically, may be fixedly connected by anchor bolts. The cross bars 11 are connected end to form a plurality of tips, and the tips are in one-to-one correspondence with the upper ends of the vertical bars 12 and are fixedly connected. In this embodiment, the cross bar 11 and the vertical bar 12 are both made of aluminum alloy materials, and the bottom canopy frame 1 is fixedly connected to form a rectangular frame.

Referring to fig. 1 and 2, the roof rack 2 includes two bent diagonal members 21, the two diagonal members 21 are hinged to the two opposite side rails 11 in a one-to-one correspondence, and each diagonal member 21 encloses a triangle with the corresponding rail 11.

In this embodiment, the diagonal members 21 are each provided as ropes, and both ends of the ropes are hinged to the cross bar 11. In other embodiments, the diagonal strut 21 may also be provided as a rigid telescopic rod. In this embodiment, the flexible support of the rope is capable of withstanding wind loads, snow loads, etc. by being deformed to some extent. In addition, when carrying the parts of the tent, the weight of the rope is light, so the carrying load of the user can be reduced. Finally, if natural disasters such as earthquake are encountered, people in the tent can not be injured by rope collapse.

Referring to fig. 2, the canopy cloth 3 is covered on the roof frame 2 and supported by diagonal members 21. The top tarpaulin 3 completely covers the top area of the tent for sun protection or water protection. With reference to fig. 3, each side of the bottom awning frame 1 is provided with a side awning cloth 4, the lower end of the top awning cloth 3 extends to the upper end of the covering side awning cloth 4 and is located outside the side awning cloth 4, and the top awning cloth 3 and the side awning cloth 4 are detachably connected at the covering part.

Specifically, the top tarpaulin 3 and the side tarpaulin 4 can be bonded by using a magic tape, and can be detachably connected in a hole tying mode. Because the part of the top tarpaulin 3 extending out covers outside the side tarpaulin 4, rainwater can not enter the tarpaulin from the top tarpaulin 3, and the possible rain leakage or rain seepage in the tarpaulin is reduced.

Referring to fig. 1 and 4, an adjusting assembly 5 is installed between the diagonal member 21 and the cross bar 11, and the adjusting assembly 5 is used to adjust the inclination angle of the diagonal member 21.

Referring to fig. 4 and 5, the adjusting assembly 5 includes an adjusting lever 51, an adjusting ring 52, and a locking piece 53. The adjusting rod 51 is slidably connected with the cross rod 11, the sliding direction of the adjusting rod 51 is parallel to the axis direction of the cross rod 11, the locking piece 53 is used for locking the adjusting rod 51 on the cross rod 11 after the adjusting rod 51 slides to a designated position, the adjusting ring 52 is fixedly arranged at one end of the adjusting rod 51, and the rope is arranged in the adjusting ring 52 in a penetrating mode.

Specifically, the cross bar 11 is provided with a sliding hole 111, the extending direction of the sliding hole 111 is parallel to the axis direction of the cross bar 11, and the adjusting rod 51 is arranged in the sliding hole 111 in a penetrating manner. In this embodiment, the adjusting rod 51 is provided as a screw, and the locking piece 53 includes an abutment block 531 and a locking block 532 which are screwed to the adjusting rod 51, the abutment block 531 being in abutment with a surface of the cross bar 11 which is close to the diagonal member 21, and the locking block 532 being in abutment with a side of the cross bar 11 which is far from the abutment block 531.

In sunny days or cloudy days, the adjusting rod 51 is moved to the middle of the cross rod 11, the height of the adjusting rod 51 is adjusted up and down, so that ropes on two sides of the adjusting ring 52 are tightened, the abutting blocks 531 are rotated, the abutting blocks 531 abut against one surface of the cross rod 11, which is close to the ropes, and the adjusting rod 51 can be primarily limited to move downwards. The locking block 532 is then rotated to limit the upward movement of the adjustment lever 51. The abutment block 531 and the lock block 532 can effectively restrict the upward and downward movement of the adjustment lever 51, and thus the rope can be placed in a taut state to improve the supporting effect on the canopy 3. Meanwhile, after the adjusting rod 51 is fixed, the adjusting rod 51 can also serve as a vertical support, so that the bearing capacity of the tent is further improved.

During heavy rain or snowy weather, the abutting blocks 531 and the locking blocks 532 are unscrewed firstly, and then the adjusting rod 51 is moved back and forth along the extending direction of the sliding hole 111 to adjust the inclination angle of the diagonal bracing piece 21, so that the two side edges of the top triangle are continuously inclined and changed, rainwater or snow attached to the top awning cloth 3 can slide down, and the pressure of the rainwater and the snow on the top awning cloth 3 is reduced. For example, referring to fig. 4, the moving adjusting rod 51 may be moved to the left and then to the right, and the height of the adjusting rod 51 needs to be adjusted during the moving process of the adjusting rod 51, so that the rainwater or the snow on the top awning cloth 3 slides away from the top awning cloth 3 several times, so as to reduce the pressure of the rainwater or the snow on the top awning cloth 3, and further reduce the possibility of collapse of the canopy.

In windy weather, the adjusting rod 51 can be moved to the most edge of the cross rod 11, so that the inclination angle of the diagonal brace can be effectively reduced, the contact area between wind and the top tarpaulin 3 in the wind direction is reduced, the wind load born by the tent is further reduced, and the risk that the tent may collapse is further reduced. Of course, if the wind force is large, the adjusting lever 51 may be moved downward until the top cloth 3 is in a horizontal state, so that the contact area between the top cloth 3 and the wind can be reduced.

Referring to fig. 1 and 2, the vertical rod 12 includes a sleeve 121 and a stem 122, and the sleeve 121 is fixedly connected to the ground by anchor bolts. The loop bars 122 are inserted into the sleeves 121, one ends of the loop bars 122, which are far away from the sleeves 121, are detachably connected with the cross bars 11, and a connecting structure is further connected between the multiple groups of loop bars 122 and is used for being arranged in parallel with the ground. The lifting component 6 is used for driving the connecting structure to lift, and the lifting component 6 drives the connecting structure to lift, so that the loop bar 122 can be driven to move up and down, and the layer height of the tent can be adjusted. Wherein, other embodiments can also be provided as a multi-layer tent.

In this embodiment, referring to fig. 1 and 2, the connection structure includes two connection rods 9, and the middle parts of the two connection rods 9 are hinged to form a scissors supporting structure (in combination with fig. 6). The lateral load resistance of the tent of the present application can be further improved by the arrangement of the two connecting rods 9 as a scissors stay, such as wind load, or load generated by transverse waves in the earthquake. Meanwhile, the connecting rod 9 can rotate, so that the subsequent folding of the connecting structure is facilitated, and the user can transport the connecting mechanism conveniently.

In other embodiments, the connection structure may be configured as a steel cable, where one end of the steel cable is fixedly connected to the vertical rod 12, and the other end of the steel cable is fixedly connected to the lifting assembly 6.

Referring to fig. 2 and 7, the lifting assembly 6 includes a lifting sleeve 61, a lifting sleeve rod 62, and a locking pin 63. The lifting sleeve 61 is used for being fixedly connected with the ground, and can be directly connected or indirectly connected. The lifting sleeve rod 62 is inserted into the lifting sleeve 61, the lifting sleeve rod 62 is positioned at one side of the lifting sleeve 61 far away from the ground, a plurality of groups of first pin holes 621 are formed in the extending direction of the lifting sleeve rod 62, a second pin hole 611 is formed in the lifting sleeve 61, and the locking pin 63 is arranged in the first pin holes 621 and the second pin holes 611 in a penetrating mode. Therefore, by aligning the second pin hole 611 with the different first pin hole 621 and plugging the locking pin 63 into the first pin hole 621 and the second pin hole 611, the floor height of the entire tent can be effectively adjusted and the lifting sleeve 61 and the lifting sleeve 62 can be fixed.

In order to facilitate the movement of the connection structure by the abutment of the lifting sleeve 62, in this embodiment, one end of the lifting sleeve 62 far from the lifting sleeve 61 is fixedly connected to the hinge point of the two connecting rods 9, and the connecting rods 9 and one end of the sleeve 122 far from the sleeve 121 are detachably connected. The convenience of adjusting the height of the tent is improved through the middle part of the abutting connection structure, and the vertical rods 12 at different positions do not need to be independently adjusted.

It will be appreciated that, in order to further increase the bearing capacity of the lifting sleeve 62, a plurality of diagonal braces 10 may be provided at the end of the lifting sleeve 62 remote from the lifting sleeve 61 (see fig. 2), the diagonal braces 10 connecting the lifting sleeve 62 with the connecting rod 9. Meanwhile, a pin may be provided between the sleeve 121 and the stem 122, and after the height adjustment is completed, the sleeve 121 and the stem 122 may be fixed by the pin.

Referring to fig. 2, when the tent is lifted and lowered, the side tent 4 located at the side of the tent needs to be adaptively elongated or shortened. The winding assembly 8 is able to accommodate different heights of the tent by winding the side tarpaulin 4.

Referring to fig. 1 and 2, the winding assembly 8 includes a winding rod 81 and a knob 82, the winding rod 81 is rotatably connected between the two vertical rods 12, two ends of the winding rod 81 extend out of the tent, the winding rod 81 is located at one end of the vertical rod 12 far away from the cross rod 11, the side tent 4 is wound around the periphery of the winding rod 81, and the knob 82 is fixedly connected to one end of the winding rod 81 extending out of the tent.

Thus, when the tent is lifted, the winding rod 81 can be further caused to release the side tent cloth 4 by rotating the knob 82, so that the height of the side tent cloth 4 is adapted to the height of the tent. Conversely, when the tent is lowered, the winding lever 81 can be made to wind up the side tent cloth 4 by rotating the knob 82 as well.

Referring to fig. 1 and 2, in order to further improve the safety of the tent of the present application, the earthquake-resistant assembly 7 is connected between the lifting sleeve 61 and the ground, the earthquake-resistant assembly 7 includes a bottom plate 71, an elastic member 72 and a top plate 73, the bottom plate 71 is fixedly connected with the ground, the elastic member 72 is fixedly connected between the bottom plate 71 and the top plate 73, and a surface of the top plate 73 far from the bottom plate 71 is fixedly connected with the lifting sleeve 61. Wherein, the elastic member 72 may be a spring. When an earthquake occurs, the earthquake resistant assembly 7 can resist the earthquake through the elastic deformation of the elastic piece 72, thereby reducing the risk of the tent being immediately collapsed.

Therefore, the tent can be adjusted by a user according to different weather conditions, and the safety of the tent is improved.

The implementation principle of the embodiment is as follows:

when suffering different weather, adjust inclination of diagonal brace 21 in order to adapt to different weather through adjusting component 5, therefore can effectively improve the security of this application covering or awning on a car, boat, etc. room.

When the awning is used in windy weather, the abutting blocks 531 and the locking blocks 532 are loosened firstly, then the adjusting rod 51 is moved, the adjusting rod 51 is moved to the end part of the cross rod 11, and then the abutting blocks 531 and the locking blocks 532 are screwed, so that the contact area between the awning cloth 3 and wind power can be effectively reduced. When the wind force is large, the adjusting rod 51 can be moved downwards without supporting the top tarpaulin 3, so that the contact area between the top tarpaulin 3 and the wind force is further reduced.

In heavy rain or snowy weather, the abutting blocks 531 and the locking blocks 532 are loosened first, and then the adjusting rod 51 is moved back and forth along the length direction of the cross rod 11, so that rainwater or snow on the top awning cloth 3 can slide from two sides of the top awning cloth 3, and vertical load borne by the top awning cloth 3 is reduced.

In a second aspect, the embodiment of the application also discloses a manufacturing method of the earthquake-resistant tent made of the multilayer aluminum alloy.

Referring to fig. 1 and 2, an earthquake-resistant housing made of a multi-layered aluminum alloy and a method for manufacturing the same, comprising the steps of:

s1, fixedly connecting a plurality of vertical rods 12 with the ground, and then installing a plurality of cross rods 11 on one side of the vertical rods 12 far away from the ground, wherein the vertical rods 12 and the cross rods 11 are connected to form a bottom awning frame 1;

s2, hinging a plurality of diagonal members 21 with the cross rod 11, and connecting the diagonal members 21 at two ends of the cross rod 11 with each other to form a triangular roof frame 2;

s3, installing the top tarpaulin 3 on one surface of the diagonal bracing piece 21 away from the cross rod 11, and fixedly connecting the side edge of the top tarpaulin 3 with the cross rod 11;

s4, installing the adjusting assembly 5 between the diagonal bracing piece 21 and the cross rod 11.

Through the steps, the convenience of tent installation is improved, and the inclined state of the diagonal bracing piece 21 can be adjusted through the adjusting component 5 after the tent is installed, so that the tent can adapt to different weather conditions.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. An anti-seismic tent made of multi-layer aluminum alloy, which is characterized by comprising:

the bottom awning frame (1) comprises a plurality of cross bars (11) and a plurality of vertical bars (12), wherein the vertical bars (12) are fixedly connected with the ground, the cross bars (11) are connected end to form a plurality of tips, and the tips are in one-to-one correspondence with the upper ends of the vertical bars (12) and are fixedly connected;

the roof frame (2) comprises two bent diagonal bracing pieces (21), the two diagonal bracing pieces (21) are in one-to-one correspondence with the two cross bars (11) on the two opposite sides and are hinged, and each diagonal bracing piece (21) and the corresponding cross bar (11) enclose a triangle;

a top awning cloth (3) which is covered on the canopy frame (2) and is supported by the diagonal bracing piece (21);

the adjusting assembly (5) is arranged between the diagonal member (21) and the cross rod (11), and the adjusting assembly (5) is used for adjusting the inclination angle of the diagonal member (21);

the diagonal bracing pieces (21) are all arranged as ropes, and two ends of each rope are hinged with the cross rod (11); the adjusting assembly (5) comprises an adjusting rod (51), an adjusting ring (52) and a locking piece (53), the adjusting rod (51) is in sliding connection with the cross rod (11), the sliding direction is parallel to the axis direction of the cross rod (11), the adjusting ring (52) is fixedly arranged at the upper end of the adjusting rod (51), the rope is arranged in the adjusting ring (52) in a penetrating mode, and the locking piece (53) is used for locking the adjusting rod (51) on the cross rod (11) after the adjusting rod (51) slides;

the transverse rod (11) is provided with a sliding hole (111), the extending direction of the sliding hole (111) is parallel to the axis direction of the transverse rod (11), the adjusting rod (51) is arranged in the sliding hole (111) in a penetrating mode, the locking piece (53) comprises an abutting block (531) and a locking block (532) which are in threaded connection with the adjusting rod (51), the abutting block (531) abuts against one surface, close to the diagonal bracing piece (21), of the transverse rod (11), and the locking block (532) abuts against one side, far away from the abutting block (531), of the transverse rod (11);

in the windy weather, the abutting block (531) and the locking block (532) are loosened, the adjusting rod (51) is moved to the end part of the cross rod (11), and then the abutting block (531) and the locking block (532) are screwed;

during heavy rain or heavy snow weather, the abutting block (531) and the locking block (532) are loosened first, and then the adjusting rod (51) is moved back and forth along the length direction of the cross rod (11).

2. The earthquake-resistant housing made of a plurality of layers of aluminum alloy according to claim 1, wherein: the vertical rod (12) comprises a sleeve (121) and a loop bar (122), the sleeve (121) is fixedly connected with the ground, the loop bar (122) is inserted in the sleeve (121), one end of the loop bar (122) away from the sleeve (121) is detachably connected with the cross rod (11), a plurality of loop bars (122) are connected with a connecting structure, the connecting structure is used for being arranged in parallel with the ground, a lifting assembly (6) is arranged in the bottom awning frame (1), and the lifting assembly (6) is used for driving the connecting structure to lift.

3. The earthquake-resistant housing made of a plurality of layers of aluminum alloy as claimed in claim 2, wherein: lifting assembly (6) are including lift sleeve (61), lift loop bar (62) and locking pin (63), lift sleeve (61) are used for with ground fixed connection, lift loop bar (62) are inserted and are located in lift sleeve (61), just lift loop bar (62) are located lift sleeve (61) keep away from one side on ground, multiunit first cotter hole (621) have been seted up in the extending direction of lift loop bar (62), second cotter hole (611) have been seted up on lift sleeve (61), locking pin (63) wear to locate first cotter hole (621) with in second cotter hole (611).

4. An earthquake-resistant housing made of a multi-layered aluminum alloy as recited in claim 3, wherein: the connecting structure comprises two connecting rods (9), the middle parts of the two connecting rods (9) are hinged to form a scissor supporting structure, one end of a lifting sleeve rod (62) away from the lifting sleeve (61) is fixedly connected to the hinged parts of the two connecting rods (9), and one end of the connecting rod (9) away from the sleeve rod (122) is detachably connected with one end of the sleeve (121).

5. An earthquake-resistant housing made of a multi-layered aluminum alloy as recited in claim 3, wherein: still include antidetonation subassembly (7), be connected between lift sleeve (61) and the ground antidetonation subassembly (7), antidetonation subassembly (7) include bottom plate (71), elastic component (72) and roof (73), bottom plate (71) are used for with ground fixed connection, elastic component (72) fixed connection in bottom plate (71) with between roof (73), roof (73) keep away from one side of bottom plate (71) with lift subassembly (6) fixed connection.

6. An earthquake-resistant housing made of a multi-layered aluminum alloy as recited in claim 3, wherein: still include a plurality of side tarpaulins (4), each side of bottom tarpaulin frame (1) sets up one side tarpaulin (4), top tarpaulin (3) with side tarpaulin (4) can dismantle and be connected, top tarpaulin (3) lower extreme extends to the cover side tarpaulin (4) upper end, and is located the side tarpaulin (4) outside.

7. The earthquake-resistant housing made of a plurality of layers of aluminum alloy according to claim 6, wherein: still including winding subassembly (8), winding subassembly (8) including rolling up pole (81) and knob (82), roll up pole (81) rotate connect in two between montant (12), roll up the both ends of pole (81) and stretch out outside the covering or awning on a car, boat, etc. room, just roll up pole (81) are located montant (12) are kept away from the one end of horizontal pole (11), side tarpaulin (4) roll up in roll up pole (81) periphery, knob (82) fixed connection in roll up pole (81) stretch out the one end outside the covering or awning on a car, boat, etc.

8. The manufacturing method of the anti-seismic tent made of the multi-layer aluminum alloy is based on the anti-seismic tent made of the multi-layer aluminum alloy as claimed in claim 1, and is characterized by comprising the following steps:

s1, fixedly connecting a plurality of vertical rods (12) with the ground, and then installing a plurality of cross rods (11) on one side of the vertical rods (12) far away from the ground, wherein the vertical rods (12) and the cross rods (11) are connected to form a bottom awning frame (1);

s2, hinging a plurality of diagonal members (21) with the cross rod (11), and connecting the diagonal members (21) at two ends of the cross rod (11) to form a triangular roof frame (2);

s3, installing a top awning cloth (3) on one surface of the diagonal bracing piece (21) far away from the cross rod (11), and fixedly connecting the side edge of the top awning cloth (3) with the cross rod (11);

s4, installing the adjusting component (5) between the diagonal bracing piece (21) and the cross rod (11).