CN219781049U - Coordination connection structure of temperature controller for greenhouse - Google Patents

Abstract

The utility model discloses a matched connection structure of a temperature controller for a greenhouse, which comprises the greenhouse, a support frame and the temperature controller. According to the utility model, structural components such as a greenhouse, a support frame, a temperature controller, a fixed block, a connecting block and a cavity are arranged, and through the use of a positioning assembly in the cavity, two positioning blocks can move to the inside of the connecting block, so that the connecting block is fixed with the fixed block, the temperature controller is fixed with the support frame, through the cooperation of a transmission assembly and the positioning assembly, the two positioning blocks can be moved out of the inside of the connecting block, the temperature controller and the support frame can be separated, and the temperature controller and the support frame can be manually quickly disassembled and assembled.

Description

Coordination connection structure of temperature controller for greenhouse

Technical Field

The utility model belongs to the technical field of greenhouses, and particularly relates to a matching connection structure of a temperature controller for a greenhouse.

Background

The greenhouse is used for cultivating seeds and planting vegetables in winter, plant crops are planted through the greenhouse, environmental factors such as temperature, humidity and illumination in the greenhouse need be mastered, in order to monitor the temperature inside the greenhouse in real time and change the temperature, a temperature control instrument is needed, through the use of the temperature control instrument, the occurrence of plant diseases and insect pests can be reduced through reasonable temperature control, the investment of pesticides is reduced, thereby saving production cost, the temperature control instrument needs to be installed, the temperature control instrument is installed on a supporting frame, the installation mode of the existing temperature control instrument and the supporting frame is often assembled and fixed through a plurality of bolts, a plurality of bolts need to be screwed through special tools, and the temperature control instrument is troublesome and not rapid, and has the problems that: the temperature controller and the support frame cannot be fast fixed, and a special tool is needed for disassembly and assembly, so that the temperature controller for the greenhouse is troublesome, and the temperature controller for the greenhouse is matched and connected to the support frame to solve the problems.

Disclosure of Invention

Aiming at the problems in the prior art, the utility model provides a matched connection structure of a temperature controller for a greenhouse, which has the advantage of being capable of manually enabling the temperature controller to be quickly assembled and disassembled with a support frame, and solves the problems that the temperature controller cannot be quickly fixed with the support frame, and a special tool is needed for assembling and disassembling, so that the assembly and disassembly are troublesome.

The utility model discloses a cooperation connection structure of a temperature controller for a greenhouse, which comprises a greenhouse, a support frame and the temperature controller, wherein the support frame and the temperature controller are both positioned in the greenhouse, one side of the temperature controller, which is close to the support frame, is in close contact with the support frame, the left side and the right side of the support frame are fixedly connected with fixed blocks, the interiors of the two fixed blocks are respectively connected with a connecting block in an inserting way, the front sides of the two connecting blocks are fixedly connected with the rear side of the temperature controller, a cavity is formed in the connecting block on the left side, and a positioning component and a transmission component are respectively arranged in the cavity.

As the preferable mode of the utility model, the positioning component comprises two positioning blocks, the surfaces of the two positioning blocks are movably connected with the inside of the cavity, the left sides of the front sides of the two positioning blocks are respectively and rotatably connected with a movable rod, the rear sides of the two movable rods are respectively and rotatably connected with a convex block, the rear sides of the two convex blocks are respectively and fixedly connected with the rear sides of the inner walls of the cavity, and the two positioning blocks can move to the inside of the connecting block through the cavity by arranging the positioning component, so that the connecting block is fixed with the fixed block, and the temperature controller is fixed with the support frame.

As the preferable transmission assembly of the utility model, the transmission assembly comprises two transmission rods, the surfaces of the two transmission rods are movably connected with the inside of the cavity, the opposite ends of the two transmission rods are fixedly connected with reset springs, the front sides of the two transmission rods are rotatably connected with short rods, the opposite ends of the two short rods are movably connected with the left sides of the two movable rods, the two positioning blocks can be moved out of the inside of the connecting block through the transmission assembly, and the two transmission rods and the short rods can automatically rebound to the original position after moving through the reset springs.

As the preferable one of the utility model, the opposite ends of the two positioning blocks are fixedly connected with the square plate, the left side of the square plate is fixedly connected with the limiting block, the surface of the limiting block is slidably connected with the control block, the surface of the limiting block is sleeved with the extrusion spring, the right side of the extrusion spring is fixedly connected with the left side of the square plate, the left side of the extrusion spring is fixedly connected with the right side of the control block, and the two positioning blocks can move leftwards or rightwards in the cavity and can rebound to the original position automatically after moving through arranging the square plate, the limiting block, the control block and the extrusion spring.

As the preferable mode of the utility model, the rear sides of the two transmission rods are in sliding connection with the trapezoid groove, the trapezoid groove is arranged at the rear side of the inner wall of the cavity, and the two transmission rods can only move upwards or downwards in the cavity through the trapezoid groove by arranging the trapezoid groove.

As the utility model is preferable, the right sides of the two positioning blocks sequentially penetrate through the fixed block and the connecting block through the cavity and extend to the inside of the connecting block, and the two positioning blocks are arranged to move from the inside of the cavity to the inside of the connecting block, so that the temperature controller and the support frame are fixed.

As the utility model is preferable, one side of the two positioning blocks, which is close to the fixed block and the connecting block, is in close contact with the fixed block and the connecting block, and the two positioning blocks are arranged, so that the temperature controller is prevented from loosening after being fixed with the support frame, and the fixing effect is firmer.

Compared with the prior art, the utility model has the following beneficial effects:

1. according to the utility model, structural components such as the greenhouse, the support frame, the temperature control instrument, the fixed block, the connecting block and the cavity are arranged, and through the use of the positioning component in the cavity, the two positioning blocks can move into the connecting block, so that the connecting block and the fixed block are fixed, the temperature control instrument and the support frame are fixed, the two positioning blocks can be moved out of the connecting block through the cooperation of the transmission component and the positioning component, the temperature control instrument and the support frame can be separated, and the temperature control instrument and the support frame can be quickly disassembled by hand.

2. According to the utility model, structural components such as a greenhouse, a support frame, a temperature controller, a fixed block, a connecting block and a cavity are arranged, when the temperature controller is required to be separated from the support frame, the two transmission rods are pushed to move towards opposite ends by manpower and move to enable the two short rods to move, the two short rods can rotate in the moving process, the two movable rods move towards opposite ends through the two convex blocks, the two positioning blocks move leftwards and move out of the inside of the connecting block, the temperature controller is further enabled to move forwards, the separation contact of the temperature controller and the support frame is realized, the reset spring can generate a deformation force in the moving process of the two transmission rods, the reset spring can give the same force to the two transmission rods after the two transmission rods are loosened, the two transmission rods drive the two short rods and the two movable rods to rebound to the original position, the square plate can be driven to move leftwards and enable the extrusion spring to generate a deformation force when the square positioning blocks are loosened, the square positioning blocks can give the same force to enable the plate to drive the two square plate to rebound to the inside of the connecting block, and the temperature controller is fixed to the connecting block.

Drawings

FIG. 1 is a schematic diagram of a structure provided by an embodiment of the present utility model;

FIG. 2 is a schematic cross-sectional view of a greenhouse provided by an embodiment of the present utility model;

FIG. 3 is a perspective view of a support stand separated from a temperature controller according to an embodiment of the present utility model;

FIG. 4 is a front cross-sectional view of a securing block provided in accordance with an embodiment of the present utility model;

fig. 5 is a detailed view of a partial structure provided by an embodiment of the present utility model.

In the figure: 1. a greenhouse; 2. a support frame; 3. a temperature controller; 4. a fixed block; 5. a connecting block; 6. a cavity; 7. a positioning assembly; 701. a positioning block; 702. a movable rod; 703. a bump; 8. a transmission assembly; 801. a transmission rod; 802. a return spring; 803. a short bar; 9. a square plate; 10. a limiting block; 11. a control block; 12. extruding a spring; 13. a trapezoid groove.

Detailed Description

For a further understanding of the utility model, its features and advantages, reference is now made to the following examples, which are illustrated in the accompanying drawings.

The structure of the present utility model will be described in detail with reference to the accompanying drawings.

As shown in fig. 1 to 5, the matching connection structure of a temperature controller for greenhouse provided by the embodiment of the utility model comprises a greenhouse 1, a support frame 2, a temperature controller 3, a fixed block 4, a connecting block 5, a cavity 6, a positioning component 7, a positioning block 701, a movable rod 702, a bump 703, a transmission component 8, a transmission rod 801, a return spring 802, a short rod 803, a square plate 9, a limiting block 10, a control block 11, an extrusion spring 12 and a trapezoid groove 13, wherein the support frame 2 and the temperature controller 3 are both positioned in the greenhouse 1, one side of the temperature controller 3 close to the support frame 2 is tightly contacted with the support frame 2, the left side and the right side of the support frame 2 are both fixedly connected with the fixed blocks 4, the interiors of the two fixed blocks 4 are both connected with the connecting blocks 5 in a plug-in manner, the front sides of the two connecting blocks 5 are both fixedly connected with the rear side of the temperature controller 3, the cavity 6 is formed in the left connecting block 5, and the positioning component 7 and the transmission component 8 are respectively arranged in the cavity 6.

Referring to fig. 4, the positioning assembly 7 includes two positioning blocks 701, the surfaces of the two positioning blocks 701 are movably connected with the inside of the cavity 6, the left sides of the front sides of the two positioning blocks 701 are rotatably connected with movable rods 702, the rear sides of the two movable rods 702 are rotatably connected with protruding blocks 703, and the rear sides of the two protruding blocks 703 are fixedly connected with the rear sides of the inner walls of the cavity 6.

The scheme is adopted: through setting up locating component 7, two locating pieces 701 can be through the inside of cavity 6 removal to connecting block 5 to make connecting block 5 and fixed block 4 fixed, realize the fixed of temperature controller 3 and support frame 2.

Referring to fig. 4, the transmission assembly 8 includes two transmission rods 801, the surfaces of the two transmission rods 801 are movably connected with the inside of the cavity 6, the opposite ends of the two transmission rods 801 are fixedly connected with return springs 802, the front sides of the two transmission rods 801 are rotatably connected with short rods 803, and the opposite ends of the two short rods 803 are movably connected with the left sides of the two movable rods 702.

The scheme is adopted: by providing the drive assembly 8, two positioning blocks 701 can be moved out of the interior of the connection block 5, and the use of the return spring 802 can automatically rebound the two drive rods 801 and the short rod 803 to the original position after movement.

Referring to fig. 4, opposite ends of two positioning blocks 701 are fixedly connected with a square plate 9, a limiting block 10 is fixedly connected to the left side of the square plate 9, a control block 11 is slidably connected to the surface of the limiting block 10, an extrusion spring 12 is sleeved on the surface of the limiting block 10, the right side of the extrusion spring 12 is fixedly connected with the left side of the square plate 9, and the left side of the extrusion spring 12 is fixedly connected with the right side of the control block 11.

The scheme is adopted: through setting up square plate 9, stopper 10, control block 11 and extrusion spring 12, can play a spacing supporting role, make two locating pieces 701 can only left or right removal in the inside of cavity 6, can make two locating pieces 701 rebound to the normal position voluntarily after moving simultaneously.

Referring to fig. 5, the rear sides of the two transmission rods 801 are slidably connected with a trapezoidal groove 13, and the trapezoidal groove 13 is opened at the rear side of the inner wall of the cavity 6.

The scheme is adopted: by providing the trapezoidal groove 13, the two transmission rods 801 can only be moved in upward or downward direction inside the cavity 6 by the trapezoidal groove 13.

Referring to fig. 2, the right sides of the two positioning blocks 701 sequentially penetrate through the fixing block 4 and the connection block 5 through the cavity 6 and extend to the inside of the connection block 5.

The scheme is adopted: by arranging two positioning blocks 701, the temperature controller 3 and the support frame 2 are fixed by moving from the inside of the cavity 6 to the inside of the connecting block 5.

Referring to fig. 2, both sides of the two positioning blocks 701 near the fixing block 4 and the connection block 5 are in close contact with the fixing block 4 and the connection block 5.

The scheme is adopted: by arranging the two positioning blocks 701, looseness of the temperature controller 3 after being fixed with the support frame 2 is avoided, and the fixing effect is firmer.

The working principle of the utility model is as follows:

when the temperature controller 3 is required to be separated from the supporting frame 2 in use, the two transmission rods 801 are pushed by manpower to move towards opposite ends and move the two short rods 803, the two short rods 803 rotate the two movable rods 702 in the moving process, the two movable rods 702 move towards opposite ends through the two convex blocks 703, the two positioning blocks 701 move leftwards and are removed from the inside of the connecting block 5, the temperature controller 3 moves forwards, the separation contact between the temperature controller 3 and the supporting frame 2 is realized, the two transmission rods 801 generate a deformation force by the reset spring 802 in the moving process, after the two transmission rods 801 are loosened, the reset spring 802 gives the two transmission rods 801 the same force, so that the two transmission rods 801 drive the two short rods 803 and the two movable rods 702 to rebound to the original position, the two positioning blocks 701 can drive the square plate 9 to move and the extrusion spring 12 to generate a deformation force when moving leftwards, the extrusion spring 12 gives the square plate 9 the same force when loosening the two transmission rods 801, the square plate 9 drives the two positioning blocks 701 to rebound to the inside of the connecting block 5, the connecting block 5 is fixed with the fixed block 4, and the fixation of the temperature controller 3 and the support frame 2 is realized.

To sum up: this temperature control appearance for big-arch shelter cooperation connection structure through setting up big-arch shelter 1, support frame 2, temperature control appearance 3, fixed block 4, connecting block 5, cavity 6, locating component 7, locating piece 701, movable rod 702, lug 703, drive assembly 8, drive rod 801, reset spring 802, quarter butt 803, square plate 9, stopper 10, control block 11, extrusion spring 12 and dovetail 13's cooperation use, has solved the present temperature control appearance that can not be quick and has fixed with the support frame, needs specialized tool to dismantle, comparatively troublesome problem.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a cooperation connection structure of temperature control appearance for big-arch shelter, includes big-arch shelter (1), support frame (2) and temperature control appearance (3) all are located the inside of big-arch shelter (1), one side that temperature control appearance (3) are close to support frame (2) and support frame (2) close contact, its characterized in that: the support frame is characterized in that fixed blocks (4) are fixedly connected to the left side and the right side of the support frame (2), connecting blocks (5) are connected to the inside of the two fixed blocks (4) in a plug-in mode, the front sides of the two connecting blocks (5) are fixedly connected with the rear side of the temperature control instrument (3), a cavity (6) is formed in the connecting blocks (5) in the left side, and a positioning assembly (7) and a transmission assembly (8) are arranged in the cavity (6) respectively.

2. The cooperative connection structure of a temperature controller for greenhouse as claimed in claim 1, wherein: the positioning assembly (7) comprises two positioning blocks (701), the surfaces of the two positioning blocks (701) are movably connected with the inside of the cavity (6), the left sides of the front sides of the two positioning blocks (701) are rotatably connected with movable rods (702), the rear sides of the two movable rods (702) are rotatably connected with lugs (703), and the rear sides of the two lugs (703) are fixedly connected with the rear sides of the inner walls of the cavity (6).

3. The cooperative connection structure of a temperature controller for greenhouse as claimed in claim 2, wherein: the transmission assembly (8) comprises two transmission rods (801), the surfaces of the two transmission rods (801) are movably connected with the inside of the cavity (6), the opposite ends of the two transmission rods (801) are fixedly connected with reset springs (802), the front sides of the two transmission rods (801) are rotatably connected with short rods (803), and the opposite ends of the two short rods (803) are movably connected with the left sides of the two movable rods (702).

4. The cooperative connection structure of a temperature controller for greenhouse as claimed in claim 2, wherein: opposite end fixedly connected with square board (9) of two locating pieces (701), the left side fixedly connected with stopper (10) of square board (9), the surface sliding connection of stopper (10) has control block (11), the surface cover of stopper (10) is equipped with extrusion spring (12), the right side of extrusion spring (12) and the left side fixed connection of square board (9), the left side of extrusion spring (12) and the right side fixed connection of control block (11).

5. A mating connection structure of a temperature controller for greenhouse as claimed in claim 3, wherein: the rear sides of the two transmission rods (801) are in sliding connection with trapezoid grooves (13), and the trapezoid grooves (13) are formed in the rear side of the inner wall of the cavity (6).

6. The cooperative connection structure of a temperature controller for greenhouse as claimed in claim 2, wherein: the right sides of the two positioning blocks (701) sequentially penetrate through the fixed block (4) and the connecting block (5) through the cavity (6) and extend to the inside of the connecting block (5).

7. The cooperative connection structure of a temperature controller for greenhouse as claimed in claim 2, wherein: one side of each positioning block (701) close to the fixed block (4) and one side of each connecting block (5) are in close contact with the fixed block (4) and the connecting blocks (5).