JP2022022943A - Removable step-on floor heating - Google Patents

Abstract

To provide a removable step-on floor heating in which a heat insulation effect is improved.SOLUTION: A removable step-on floor heating is configured as follows: a foot board 23 is pushed downward, when a person walks on the present invention; the foot board moves a projection block 25 downward by a support block 24 in a U-shaped groove 26; a rack 33 is made to come down in a process where a second compression spring 27 is compressed and the foot board moves downward; a gear engages with the rack and the gear rotates, and thereby a rope is wound up; the rope pulls and moves a slider 28, and the slider is made to slide in a sliding way 29; a first compression spring 32 is compressed and force is stored in the sliding process of the slider, and at the same time, the slider causes friction between the support block and the lower end face of the foot board; a surface temperatures is increased by the frictional force; a second compression spring returns after a foot is separated from the foot board, and the second compression spring pushes and moves a projection block to thereby move the support block to the upper part; the first compression spring returns at the same time when the foot board returns to an initial position; and thereby the slider is made to slide in the anti-direction in the sliding way and returns to an initial state.SELECTED DRAWING: Figure 3

Description

The present invention relates to the field of residential heat supply, specifically to removable stepped floor heating.

In the cold winter, the problem of housing heat supply is a problem related to people's daily life, and most of the conventional housing heat supply has water pipes laid under the floor tiles, and the number of water pipes laid is limited depending on the material of the water pipes. The position of the water pipe is fixed after laying, the heat reception of the floor is uneven, the heat dissipation of the water pipe is fast after the heat supply is stopped, and the holding time of the floor tile temperature is short.

Chinese Patent Application Publication No. 102748801

An object of the present invention is to provide a removable stepped floor heating that improves the heat retention effect, and to solve a problem in the prior art.

In order to realize the above object, it is a removable stepping floor heating, and the housing, the water pipe provided in the housing, the stepping mechanism provided at the upper end of the housing, and the water pipe. The treading mechanism includes two sliding components, a support component provided on the sliding component, and the support component, including an adjusting mechanism provided and a control mechanism provided between the water pipes. A fixed tread plate, a water pipe provided on the lower inner wall of the housing, a water inlet fixedly provided at one end of the water pipe, and a water outlet fixedly provided at the other end of the water pipe. The sliding components include a sliding path fixedly provided in the housing, a slider provided so as to be reciprocally slidable in the sliding path, and a rack fixedly provided at the lower end of the tread plate. A gear shaft rotatably provided on the side wall of the rack, a gear fixed to the gear shaft, a reel fixed to the gear shaft, and two second gears provided on the sliding path. The two pulleys include one pulley, a rope wound around the reel and the first pulley, and a first compression spring fixedly provided between the slider and the side wall of the sliding path. The dynamic components are symmetrical with respect to the housing, the two support components are symmetrical with respect to the housing, the treads can slide back and forth on the housing, and the rope is at one end. Is fixedly connected to the reel, and the other end is fixedly connected to the slider.

The support component includes a U-shaped groove fixed to the slider, a protrusion block, a support block, and a second compression spring, and the protrusion block reciprocates in the U-shaped groove. The support block is slidably provided, the support block is fixedly provided at the upper end of the protrusion block, and the second compression spring is provided between the lower end of the protrusion block and the lower inner wall of the U-shaped groove. It is fixedly installed.

The adjusting mechanism includes a support fixedly provided at the lower end of the slider, a connecting rod, a moving rod, a first torsion spring, a rotating shaft, a turntable, and five adjusting components. The connecting rod is fixedly provided at the lower end of the support, the moving rod is rotatably provided at the lower end of the connecting rod, and the first torsion spring is provided with the connecting rod and the moving rod. The rotary shaft is rotatably provided on the support, the rotary plate is fixedly provided on the rotary shaft, and the five adjustment components are the rotary plate. The five adjustment components are circumferentially symmetric with respect to the turntable, and the first torsion spring is connected by fixing one end to the connecting rod and the other end of the moving rod. It is fixedly connected with.

The adjustment component includes a fixing plate fixed to the rotary plate, a rotary plate, a second torsion spring, a position control plate, an arrangement space, a sliding rail, and a sliding rod. A third compression spring, a control rod, two second pulleys, a first position regulation groove, a position regulation block, a fourth compression spring, an elastic rope, and a second position regulation groove are included. The rotary plate is rotatably provided on the fixed plate, the second torsion spring is fixedly provided between the rotary plate and the fixed plate, and the position restricting plate is provided on the upper end of the rotary plate. The arrangement space is provided in the position control plate, the sliding rail is provided in the arrangement space, and the sliding rod is provided so as to be reciprocally slidable in the sliding rail. The two third compression springs are fixedly provided between the sliding rod and the sliding rail, and the control rod is fixedly provided at the lower end of the sliding rod, and the two third compression springs are provided. The two slides are rotatably provided on the control rod, the first position regulating groove is fixedly provided at the lower end of the control rod, and the position regulating block is reciprocated in the first position regulating groove. The fourth compression spring is movably provided, and the fourth compression spring is fixedly provided between the position regulation block and the first position regulation groove, and the elastic rope is wound around the second pulley and the first position is restricted. The two-position regulating groove is fixedly provided to the rotating plate, and the second torsion spring has one end fixed and connected to the rotating plate and the other end fixedly connected to the fixed plate. The third compression spring is vertically symmetrical with respect to the control rod, and one end of the elastic rope is fixedly connected to the control rod and the other end is fixedly connected to the position restricting block.

The control mechanism includes three fixed components and three adjustable components, which are a rotor provided slidably back and forth in the water pipe, a rotor rod, and two tension springs. The rotor rod is fixedly provided between the two rotors, and the two tension springs are fixedly provided to the rotor rod and include the arcuate plate and the positioning rod. The plate is fixedly provided to the tension spring, the positioning plate is fixedly provided between the arcuate plate at one end and the inner wall of the housing, and the two tension springs are fixed to the rotor rod. On the other hand, it is vertically symmetrical.

The adjustable component includes the rotor provided reciprocally slidable in the water pipe, the sliding groove rod, the sliding groove, the fifth compression spring, the two tension springs, and the arcuate shape. The sliding groove rod includes the plate and the positioning rod, and the sliding groove rod is fixedly provided to the rotor, and the sliding groove is provided between the two sliding groove rods, and the fifth compression is performed. The spring is fixedly provided between the sliding groove rod and the inner wall of the sliding groove, the two second tension springs are fixedly provided in the sliding groove, and the arcuate plate is provided. The positioning rod is fixedly provided between the arc-shaped plate at one end and the inner wall of the housing, and the two rotors are reciprocally slid on the sliding groove. The two tension springs can be vertically symmetrical with respect to the sliding groove.

Principle of operation: After laying a plurality of the removable stepped floor heaters and communicating the water inlet in the present invention with the water outlet in the other invention, the removable stepped floor heating is installed in a house. It communicates with the water supply port of the water supply port and forms a closed water circuit.

When hot water is supplied, hot water enters the water pipe, and when there is no water, the water pipe suddenly enters the water pipe, which is soft, and the water pipe is expanded by the action of the water flow, the diameter is increased, and the water pipe is adjustable. The rotor of the component is pushed and moved, the rotor slides the sliding groove rod in the sliding groove, the fifth compression spring is compressed and stores force, the compressed fifth compression spring is restored, and the fifth compression spring. The sliding groove rod slides to the outside of the sliding groove due to the repulsive force of, the rotor swings the water pipe left and right, the water pipe swings uniformly within a certain range, and the location range of the water pipe uniformly receives heat. At the same time, the rotor slides relative to the water pipe, and in the sliding process of the rotor, the sliding groove compresses the tension spring at one end and pulls the tension spring at the other end, and the tension spring that is pulled and the tension spring that is compressed. The sliding groove is slid up and down within a certain range formed between the water pipes to stabilize the left and right swing of the water pipes, and at the same time, the tension spring interlocks the arcuate plate to support the corners of the water pipes. In addition to avoiding breakage of the corners of the water pipe and causing clogging, the fixed component provides rigid support to the water pipe with a rotor rod, ensuring the rocking stability of the water pipe, and the fixed component is a fixed component. In the sliding process of the rotor, the tension spring at one end is compressed by the rotor rod to pull the tension spring at the other end, and the tension spring to be pulled and the tension spring to be compressed form the sliding groove between the water pipes. Slide up and down within a certain range.

The water flow flows into the water pipe and collides with the adjustment mechanism, and the action of the water flow causes the turntable to rotate relative to the axis of rotation, the turntable rotates the adjustment component, and the sliding rod acts as the third compression spring in the initial state. It extends to the outside of the sliding rail, the first position regulation groove and the second position regulation groove come into contact, and the position regulation block moves from the first position regulation groove to the inside of the second position regulation groove by the action of the fourth compression spring. When the adjustment component rotates to the lowermost end of the water pipe, the adjustment component forming a recessed groove stores water inside, and the water flow through the water pipe is obstructed. When the flow velocity decreases, the time for water to accumulate in the adjustment mechanism becomes longer, the heat dissipation effect improves, the surface temperature of the present invention rises, and the adjustment component rotates to the uppermost end, the moving rod becomes a sliding rod. The sliding rod is compressed and slid into the sliding rail in contact with, the third compression spring is compressed to store force, and the sliding rod moves downward to move the control rod downward to control. The rod pulls the elastic rope and slides the position regulation block out of the second position regulation groove, the fourth compression spring is compressed, the position of the rotating plate is not regulated, and the rotating plate is fixed by the gravity of water. It rotates on the plate, and the water flows quickly through the adjusting component without affecting the subsequent work of the adjusting component and the subsequent temperature control, and after the moving rod comes into contact with the sliding rod, it rotates relative to the connecting rod. After the one-twisting spring stores the force and the moving rod does not come into contact with the sliding rod, the first torsion spring repositions and returns the moving rod to the initial state, and at the same time, the sliding rod is not compressed and the third compression. The action of the spring slides out of the sliding rail, the sliding rod pulls the control rod to its initial position, the first position regulating groove and the second position regulating spring come into contact again, and the position regulating block becomes the fourth compression spring. Slides into the second position regulation groove by the action of, and regulates the position of the turntable again.

When a person walks on the present invention, the tread plate is pushed downward in the walking process, the tread plate moves the protruding block downward in the U-shaped groove by the support block, the second compression spring is compressed, and the tread plate moves downward. In the process of moving, the rack is lowered, the rack and the gear mesh with each other, the gear interlocks the reel with the gear shaft, the reel rotates and the rope is wound by the first pulley, and the rope pulls the slider and slides on the slider. The first compression spring is compressed and stores force in the sliding process of the slider, and at the same time, the slider causes friction between the support block and the lower end surface of the tread plate, and the frictional force causes the temperature of the surface of the present invention. After the heat retention time is extended and the foot is separated from the tread plate, the second compression spring is repositioned, the second compression spring pushes the protrusion block and moves the support block upward, and the tread plate returns to the initial position. At the same time, when the first compression spring is restored, the slider slides in the opposite direction in the sliding path and returns to the initial state.

The present invention has the following advantages over the prior art:

The present invention has a simple structure, moves a water pipe within a certain range of the inner wall of the present invention, receives heat uniformly, and adjusts and treats the water flowing inside the present invention to extend the heating time. At the same time, the stepping when a person walks on the floor is converted into heat energy, and the heat retention and heat dissipation effect is improved.

Each direction described in the present application is a direction when the device is viewed in the same direction as in FIG.

It is a structural example figure of this invention. It is an enlarged view of the part A in FIG. It is a structural drawing which follows the HH line of FIG. It is an enlarged view of the part B in FIG. It is an enlarged view of the part C in FIG. It is an enlarged view of the part D in FIG. It is an enlarged view of the part E in FIG. It is an enlarged view of the part F in FIG. 7. It is a left side structural view of FIG. It is a left side structural view of the connection rod 54 in FIG. FIG. 4 is a left-side structural view of the gear 34 in FIG.

As shown in FIGS. 1 to 10, the removable stepping floor heating includes a housing 10, a water pipe 12 provided in the housing 10, and a stepping mechanism provided at the upper end of the housing 10. The treading mechanism includes two sliding components and a support component provided in the sliding component, including an adjusting mechanism provided in the water pipe 12 and a control mechanism provided between the water pipe 12. A tread plate 23 fixed to the support component, a water pipe 12 provided on the lower inner wall of the housing 10, a water inlet 13 fixed to one end of the water pipe 12, and the water pipe 12. The sliding component includes a water outlet 14 fixedly provided at the other end of the housing 10, and a sliding path 29 fixedly provided in the housing 10 and a reciprocating sliding in the sliding path 29. A slider 28 movably provided, a rack 33 fixed to the lower end of the tread plate 23, a gear shaft 57 rotatably provided on the side wall of the rack 33, and a gear shaft 57 fixed to the gear shaft 57. A gear 34, a reel 58 fixed to the gear shaft 57, two first pulleys 35 provided on the sliding path 29, and a rope 31 wound around the reel 58 and the first pulley 35. And a first compression spring 32 fixedly provided between the slider 28 and the side wall of the sliding path 29, the two sliding components are bilaterally symmetrical with respect to the housing 10. The two support components are symmetrical with respect to the housing 10, the tread plate 23 can slide back and forth on the housing 10, and the rope 31 is connected with one end fixed to the reel 58. The other end is fixedly connected to the slider 28. When a person walks on the present invention, the tread plate 23 is pushed downward, the tread plate 23 is lowered in the U-shaped groove 26 by the support block 24 into the protrusion block 25, the second compression spring 27 is compressed, and the tread plate 23 is compressed. In the process of lowering, the rack 33 is lowered, the rack 33 meshes with the gear 34, the gear 34 interlocks the reel 58 with the gear shaft 57, the reel 58 rotates, the rope 31 is wound by the first pulley 35, and the rope 31. Pulls the slider 28 to slide it in the sliding path 29, and in the sliding process of the slider 28, the first compression spring 32 is compressed to store the force, and at the same time, the slider 28 under the support block 24 and the tread plate 23. Friction occurs between the end face and the surface of the present invention due to the frictional force, the heat retention time is extended, the second compression spring 27 is repositioned after the human foot is separated from the tread plate 23, and the protrusion block 25 is formed. It is pushed to move the support block 24 upward, and at the same time the tread plate 23 returns to the initial position, the first compression spring 32 is restored and pushes the slider 28, and the slider 28 moves in the opposite direction in the sliding path 29. It slides and returns to the initial state.

The support component includes a U-shaped groove 26 fixed to the slider 28, a protrusion block 25, a support block 24, and a second compression spring 27, and the protrusion block 25 is the U. The support block 24 is provided so as to be slidable back and forth in the character groove 26, the support block 24 is fixedly provided at the upper end of the protrusion block 25, and the second compression spring 27 is provided at the lower end of the protrusion block 25 and the U. It is fixedly provided between the character groove 26 and the lower inner wall. When a person walks on the present invention, the tread plate 23 is pushed downward in the walking process, the tread plate 23 moves the protrusion block 25 downward in the U-shaped groove 26 by the support block 24, and the second compression spring 27 compresses. In the process of moving the tread plate 23 downward, the rack 33 is lowered, the rack 33 and the gear 34 mesh with each other, the gear 34 interlocks the reel 58 with the gear shaft 57, the reel 58 rotates, and the rope is rotated by the first pulley 35. 31 is wound, the rope 31 pulls the slider 28 to slide in the sliding path 29, and in the sliding process of the slider 28, the first compression spring 32 is compressed to store force, and at the same time, the slider 28 is a support block. Friction is caused between the 24 and the lower end surface of the tread plate 23, the temperature of the surface of the present invention is increased by the frictional force, the heat retention time is extended, and after the foot is separated from the tread plate 23, the second compression spring 27 is restored. The protrusion block 25 is pushed and moved to move the support block 24 upward, and at the same time as the tread plate 23 returns to the initial position, the first compression spring 32 is restored so that the slider 28 slides in the sliding path 29 in the opposite direction. And return to the initial state.

The adjusting mechanism includes five supports 53 fixed to the lower end of the slider 28, a connecting rod 54, a moving rod 55, a first torsion spring 56, a rotating shaft 36, and a rotating disk 37. The connecting rod 54, including the adjusting component, is fixedly provided at the lower end of the support 53, and the moving rod 55 is rotatably provided at the lower end of the connecting rod 54, and the first twist. The spring 56 is fixedly provided between the connecting rod 54 and the moving rod 55, the rotating shaft 36 is rotatably provided on the support 53, and the rotating disk 37 is the rotating shaft 36. The five adjustment components are fixedly provided on the turntable 37, and the five adjustment components are circumferentially symmetrical with respect to the turntable 37, and the first torsion spring is provided. One end of the 56 is fixedly connected to the connecting rod 54, and the other end is fixedly connected to the moving rod 55. The water flow flows into the water pipe 12 and collides with the adjusting mechanism, the rotating disk 37 rotates relative to the rotating shaft 36 by the action of the water flow, the rotating disk 37 rotates the adjusting component, and the moving rod 55 becomes the sliding rod 43. After contacting, they rotate relative to each other on the connecting rod 54, the first torsion spring 56 stores a force, and after the moving rod 55 and the sliding rod 43 do not come into contact with each other, the first torsion spring 56 is repositioned and the moving rod 55. To return to the initial state.

The adjustment component includes a fixing plate 39 fixed to the rotary plate 37, a rotary plate 38, a second torsion spring 40, a position regulation plate 41, an arrangement space 42, a sliding rail 44, and the like. A sliding rod 43, two third compression springs 46, a control rod 45, two second slides 52, a first position regulation groove 49, a position regulation block 48, a fourth compression spring 51, and elasticity. The rotating plate 38 includes the rope 50 and the second position regulating groove 47, and the rotating plate 38 is rotatably provided on the fixing plate 39, and the second torsion spring 40 includes the rotating plate 38 and the fixing plate 39. The position restricting plate 41 is provided at the upper end of the rotating plate 38, the arrangement space 42 is provided in the position restricting plate 41, and the sliding rail 44 is provided. The sliding rod 43 is provided in the arrangement space 42 so as to be reciprocally slidable in the sliding rail 44, and the two third compression springs 46 are the sliding rod 43 and the sliding rail. The control rod 45 is fixedly provided between the control rod 45 and the lower end of the sliding rod 43, and the two second slides 52 are rotatably provided on the control rod 45. The first position regulation groove 49 is fixedly provided at the lower end of the control rod 45, and the position regulation block 48 is provided so as to be reciprocally slidable in the first position regulation groove 49, and the fourth compression is performed. The spring 51 is fixedly provided between the position restricting block 48 and the first position restricting groove 49, and the elastic rope 50 is wound around the second pulley 52 and the second position restricting groove 47 is wound. Is fixedly provided to the rotary plate 38, one end of the second torsion spring 40 is fixedly connected to the rotary plate 38, and the other end is fixedly connected to the fixed plate 39. The third compression spring 46 is vertically symmetrical with respect to the control rod 45, and one end of the elastic rope 50 is fixedly connected to the control rod 45 and the other end is fixedly connected to the position regulation block 48. Will be done. The water flow flows into the water pipe 12 and collides with the adjusting mechanism, the rotating disk 37 rotates relative to the rotating shaft 36 by the action of the water flow, the rotating disk 37 rotates the adjusting component, and the sliding rod 43 is the first in the initial state. The third compression spring 46 extends to the outside of the sliding rail 44, the first position regulating groove 49 and the second position regulating groove 47 come into contact with each other, and the position regulating block 48 is moved by the action of the fourth compression spring 51. When the position of the control rod 45 is restricted by extending from the one-position regulating groove 49 to the inside of the second-position regulating groove 47 and the adjusting component rotates to the lowermost end of the water pipe 12, the adjusting component forming a concave groove shape is formed. The water is stored inside, the flow of water flowing through the water pipe 12 is obstructed, the flow velocity decreases, the time for the water to accumulate in the adjustment mechanism becomes longer, the heat dissipation effect improves, the temperature of the surface of the present invention rises, and the adjustment configuration When the component rotates to the uppermost end, the moving rod 55 comes into contact with the sliding rod 43, compresses the sliding rod 43 and slides it into the sliding rail 44, and the third compression spring 46 is compressed and exerts a force. The sliding rod 43 moves downward to move the control rod 45 downward, and the control rod 45 pulls the elastic rope 50 to slide the position restricting block 48 and exits from the inside of the second position restricting groove 47. The fourth compression spring 51 is compressed, the position of the rotating plate 38 is not regulated, the rotating plate 38 rotates on the fixed plate 39 due to the gravity of water, and the water flows quickly through the adjusting component to form the adjusting component. After the moving rod 55 comes into contact with the sliding rod 43, it rotates relative to the connecting rod 54 without affecting the subsequent work and the subsequent temperature control, the first torsion spring 56 stores the force, and the moving rod 55 is the sliding rod. After the contact with the 43 is lost, the first torsion spring 56 is restored and the moving rod 55 returns to the initial state, and at the same time, the sliding rod 43 is not compressed and the third compression spring 46 acts from the sliding rail 44. As it slides out, the sliding rod 43 pulls the control rod 45 to the initial position, the first position restricting groove 49 and the second position restricting spring 47 come into contact again, and the position restricting block 48 acts on the fourth compression spring 51. It slides into the second position regulating groove 47 and regulates the position of the turntable 37 again.

The control mechanism includes three fixed components, three adjustable components, and the fixed components include a rotor 19 and a rotor rod 18 provided so as to be reciprocally slidable to the water pipe 12. The rotor rod 18 includes one tension spring 17, an arcuate plate 16, and a positioning rod 15, and the rotor rod 18 is fixedly provided between the two rotors 19, and the two tension springs 17 are the rotor rods. The arcuate plate 16 is fixedly provided to the tension spring 17, and the positioning plate 15 is fixed between the arcuate plate 16 at one end and the inner wall of the housing 10. The two tension springs 17 are vertically symmetrical with respect to the rotor rod 18. When hot water is supplied, hot water enters the water pipe 12, and when there is no water, a water flow suddenly enters the water pipe 12, which is soft, so that the water pipe 12 is expanded by the action of the water flow, the diameter becomes large, and the water pipe 12 Pushes and moves the rotor 19 of the adjustable component, the rotor 19 slides the sliding groove rod 21 in the sliding groove 20, and the fifth compression spring 22 is compressed to store force and the compressed fifth compression. The spring 22 is restored, the sliding groove rod 21 slides to the outside of the sliding groove 20 due to the repulsive force of the fifth compression spring 22, the rotor 19 swings the water pipe 12 left and right, and the water pipe 12 stays within a certain range. It swings uniformly, the location range of the water pipe 12 receives heat uniformly, the rotor 19 slides relative to the water pipe 12, and in the sliding process of the rotor 19, the sliding groove 20 has a tension spring 17 at one end. The tension spring 17 at the other end is pulled, and the tension spring 17 to be pulled and the tension spring 17 to be compressed slide the sliding groove 20 up and down within a certain range formed between the water pipes 12. At the same time as stabilizing the left-right swing of the water pipe 12, the tension spring 17 interlocks the arcuate plate 16 to support the corner of the water pipe 12, and it is possible to prevent the corner portion of the water pipe 12 from breaking and causing clogging.

The adjustable component includes the rotor 19, the sliding groove rod 21, the sliding groove 20, the fifth compression spring 22, and the two tensions provided so as to be reciprocally slidable in the water pipe 12. A spring 17, an arcuate plate 16, and a positioning rod 15 are included, the sliding groove rod 21 is fixedly provided to the rotor 19, and the sliding groove 20 is provided with two sliding grooves. The fifth compression spring 22 is provided between the rods 21 and is fixedly provided between the sliding groove rod 21 and the inner wall of the sliding groove 20, and the two second tension springs 17 are provided. The arcuate plate 16 is fixedly provided in the sliding groove 20, the arcuate plate 16 is fixedly provided in the tension spring 17, and the positioning rod 15 is provided between the arcuate plate 16 at one end and the inner wall of the housing 10. The two rotors 19 are fixedly provided between them and can slide back and forth on the sliding groove 20, and the two tension springs 17 are vertically symmetrical with respect to the sliding groove 20 and are fixed components. Provides rigid support to the water pipe 12 by the rotor rod 18 to guarantee the rocking stability of the water pipe 12, and the fixed component is one end of the fixed component by the rotor rod 18 in the sliding process of the rotor 19. The tension spring 17 is compressed to pull the tension spring 17 at the other end, and the tension spring 17 to be pulled and the tension spring 17 to be compressed are within a certain range in which the sliding groove 20 is formed between the water pipes 12. Slide up and down and back and forth with.

Operating principle: After laying a plurality of the removable stepped floor heaters and communicating the water inlet 13 in the present invention with the water outlet 14 in the other invention, the removable stepped floor heating is performed. To form a closed water circuit by communicating with the water supply port of the house.

When hot water is supplied, hot water enters the water pipe 12, and when there is no water, a water flow suddenly enters the water pipe 12, which exhibits softness, so that the water pipe 12 is expanded by the action of the water flow, the diameter becomes large, and the water pipe 12 Pushes and moves the rotor 19 of the adjustable component, the rotor 19 slides the sliding groove rod 21 in the sliding groove 20, and the fifth compression spring 22 is compressed to store force and the compressed fifth compression. The spring 22 is restored, the sliding groove rod 21 slides to the outside of the sliding groove 20 due to the repulsive force of the fifth compression spring 22, the rotor 19 swings the water pipe 12 left and right, and the water pipe 12 stays within a certain range. It swings uniformly, the location range of the water pipe 12 receives heat uniformly, the rotor 19 slides relative to the water pipe 12, and in the sliding process of the rotor 19, the sliding groove 20 has a tension spring 17 at one end. The tension spring 17 at the other end is pulled, and the tension spring 17 to be pulled and the tension spring 17 to be compressed slide the sliding groove 20 up and down within a certain range formed between the water pipes 12. At the same time as stabilizing the left-right swing of the water pipe 12, the tension spring 17 interlocks the arcuate plate 16 to support the corner of the water pipe 12, and it is possible to prevent the corner portion of the water pipe 12 from breaking and causing clogging. The fixed component provides rigid support to the water pipe 12 by the rotor rod 18 to guarantee the rocking stability of the water pipe 12, and the fixed component is a tension spring at one end by the rotor rod 18 in the sliding process of the rotor 19. 17 is compressed to pull the tension spring 17 at the other end, and the tension spring 17 to be pulled and the tension spring 17 to be compressed slide up and down in a certain range formed between the water pipes 12 in the sliding groove 20. Move it.

The water flow flows into the water pipe 12 and collides with the adjusting mechanism, the rotating disk 37 rotates relative to the rotating shaft 36 by the action of the water flow, the rotating disk 37 rotates the adjusting component, and the sliding rod 43 is the first in the initial state. The third compression spring 46 extends to the outside of the sliding rail 44, the first position regulating groove 49 and the second position regulating groove 47 come into contact with each other, and the position regulating block 48 is moved by the action of the fourth compression spring 51. When the position of the control rod 45 is restricted by extending from the one-position regulating groove 49 to the inside of the second-position regulating groove 47 and the adjusting component rotates to the lowermost end of the water pipe 12, the adjusting component forming a concave groove shape is formed. The water is stored inside, the flow of water flowing through the water pipe 12 is obstructed, the flow velocity decreases, the time for the water to accumulate in the adjustment mechanism becomes longer, the heat dissipation effect improves, the temperature of the surface of the present invention rises, and the adjustment configuration When the component rotates to the uppermost end, the moving rod 55 comes into contact with the sliding rod 43, compresses the sliding rod 43 and slides it into the sliding rail 44, and the third compression spring 46 is compressed and exerts a force. The sliding rod 43 moves downward to move the control rod 45 downward, and the control rod 45 pulls the elastic rope 50 to slide the position restricting block 48 and exits from the inside of the second position restricting groove 47. The fourth compression spring 51 is compressed, the position of the rotating plate 38 is not regulated, the rotating plate 38 rotates on the fixed plate 39 due to the gravity of water, and the water flows quickly through the adjusting component to form the adjusting component. After the moving rod 55 comes into contact with the sliding rod 43, it rotates relative to the connecting rod 54 without affecting the subsequent work and the subsequent temperature control, the first torsion spring 56 stores the force, and the moving rod 55 is the sliding rod. After the first torsion spring 56 is repositioned and the rod 55 is returned to the initial state after it is no longer in contact with the 43, the sliding rod 43 is not compressed and the third compression spring 46 acts from the sliding rail 44. As it slides out, the sliding rod 43 pulls the control rod 45 to the initial position, the first position restricting groove 49 and the second position restricting spring 47 come into contact again, and the position restricting block 48 acts on the fourth compression spring 51. It slides into the second position regulating groove 47 and regulates the position of the turntable 37 again.

When a person walks on the present invention, the tread plate 23 is pushed downward in the walking process, the tread plate 23 moves the protrusion block 25 downward in the U-shaped groove 26 by the support block 24, and the second compression spring 27 compresses. In the process of moving the tread plate 23 downward, the rack 33 is lowered, the rack 33 and the gear 34 are engaged, the gear 34 interlocks the reel 58 with the gear shaft 57, the reel 58 is rotated, and the rope is provided by the first pulley 35. 31 is wound, the rope 31 pulls the slider 28 and slides in the sliding path 29 on the slider 28, and in the sliding process of the slider 28, the first compression spring 32 is compressed to store force, and at the same time, the slider 28 is stored. Causes friction between the support block 24 and the lower end surface of the tread 23, the frictional force increases the temperature of the surface of the present invention, the heat retention time is extended, and after the foot is separated from the tread 23, the second compression spring 27 The second compression spring 27 pushes and moves the protrusion block 25 to move the support block 24 upward, and the tread plate 23 returns to the initial position, and at the same time, the first compression spring 32 returns to slide the slider 28. It slides in the opposite direction in the road 29 and returns to the initial state.

Claims (6)

Detachable stepping floor heating
The housing (10) and
A water pipe (12) provided in the housing (10) and
A stepping mechanism provided at the upper end of the housing (10),
The adjustment mechanism provided in the water pipe (12) and
Including a control mechanism provided between the water pipes (12).
The stepping mechanism is
Two sliding components and
Support components provided on the sliding parts and
A tread (23) fixed to the support component and
A water pipe (12) provided on the lower inner wall of the housing (10) and
A water inlet (13) fixed to one end of the water pipe (12) and
A water outlet (14) provided fixedly to the other end of the water pipe (12) is included.
The sliding component is
A sliding path (29) fixedly provided in the housing (10),
A slider (28) provided so as to be reciprocally slidable in the sliding path (29),
A rack (33) fixed to the lower end of the tread (23) and
A gear shaft (57) rotatably provided on the side wall of the rack (33) and
A gear (34) fixed to the gear shaft (57) and
A reel (58) fixed to the gear shaft (57) and
Two first pulleys (35) provided on the sliding path (29) and
The rope (31) wound around the reel (58) and the first pulley (35),
Includes a first compression spring (32) fixedly provided between the slider (28) and the side wall of the sliding path (29).
The two sliding components are symmetrical with respect to the housing (10).
The two support components are symmetrical with respect to the housing (10).
The tread (23) can slide back and forth on the housing (10), and can be slid back and forth.
One end of the rope (31) is fixedly connected to the reel (58), and the other end is fixedly connected to the slider (28).
Detachable stepping floor heating that features. The support component is
A U-shaped groove (26) fixed to the slider (28) and
The protrusion block (25), the support block (24),
Including the second compression spring (27),
The protrusion block (25) is provided so as to be reciprocally slidable in the U-shaped groove (26).
The support block (24) is fixedly provided at the upper end of the protrusion block (25).
The second compression spring (27) is fixedly provided between the lower end of the protrusion block (25) and the lower inner wall of the U-shaped groove (26).
The removable stepped floor heating according to claim 1. The adjustment mechanism is
A support (53) fixed to the lower end of the slider (28) and a support (53).
A connecting rod (54), a moving rod (55), and
The first torsion spring (56), the rotating shaft (36),
Includes turntable (37) and five adjustment components,
The connecting rod (54) is fixedly provided at the lower end of the support (53).
The moving rod (55) is rotatably provided at the lower end of the connecting rod (54).
The first torsion spring (56) is fixedly provided between the connecting rod (54) and the moving rod (55).
The rotation shaft (36) is rotatably provided on the support (53).
The rotating disk (37) is fixedly provided to the rotating shaft (36), and is provided.
The five adjustment components are fixedly provided to the turntable (37) and are provided.
The five adjustment components are circumferentially symmetric with respect to the turntable (37).
One end of the first torsion spring (56) is fixedly connected to the connecting rod (54), and the other end is fixedly connected to the moving rod (55).
The removable stepped floor heating according to claim 2. The adjustment component is
A fixing plate (39) fixed to the turntable (37) and
Rotating plate (38) and
The second torsion spring (40) and
Position control plate (41) and
Arrangement space (42) and
Sliding rail (44) and
With the sliding rod (43),
Two third compression springs (46) and
Control rod (45) and
Two second pulleys (52) and
First position regulation groove (49) and
Position control block (48) and
The fourth compression spring (51) and
Elastic rope (50) and
Including the second position regulating groove (47),
The rotary plate (38) is rotatably provided on the fixed plate (39).
The second torsion spring (40) is fixedly provided between the rotating plate (38) and the fixing plate (39).
The position restricting plate (41) is provided at the upper end of the rotating plate (38).
The arrangement space (42) is provided in the position regulation plate (41), and is provided.
The sliding rail (44) is provided in the arrangement space (42).
The sliding rod (43) is provided so as to be reciprocally slidable in the sliding rail (44).
The two third compression springs (46) are fixedly provided between the sliding rod (43) and the sliding rail (44).
The control rod (45) is fixedly provided at the lower end of the sliding rod (43).
The two second pulleys (52) are rotatably provided on the control rods (45).
The first position regulating groove (49) is fixedly provided at the lower end of the control rod (45).
The position restricting block (48) is provided so as to be reciprocally slidable in the first position restricting groove (49).
The fourth compression spring (51) is fixedly provided between the position restricting block (48) and the first position restricting groove (49).
The elastic rope (50) is wound around the second pulley (52), and the elastic rope (50) is wound around the second pulley (52).
The second position regulating groove (47) is fixedly provided to the rotating plate (38), and is provided.
One end of the second torsion spring (40) is fixedly connected to the rotating plate (38), and the other end is fixedly connected to the fixed plate (39).
The two third compression springs (46) are vertically symmetrical with respect to the control rods (45).
One end of the elastic rope (50) is fixedly connected to the control rod (45), and the other end is fixedly connected to the position regulation block (48).
The removable stepped floor heating according to claim 3. The control mechanism includes three fixed components and three adjustable components.
The fixing component includes a rotor (19) provided so as to be reciprocally slidable in the water pipe (12), a rotor rod (18), two tension springs (17), an arc-shaped plate (16), and a positioning rod. (15) and, including
The rotor rod (18) is fixedly provided between the two rotors (19).
The two tension springs (17) are fixedly provided to the rotor rod (18).
The arcuate plate (16) is fixedly provided to the tension spring (17), and is provided.
The positioning plate (15) is fixedly provided between the arc-shaped plate (16) at one end and the inner wall of the housing (10).
The two tension springs (17) are vertically symmetrical with respect to the rotor rod (18).
The removable stepped floor heating according to claim 4. The adjustable component includes the rotor (19) provided so as to be reciprocally slidable in the water pipe (12), the sliding groove rod (21), the sliding groove (20), and the fifth compression. The spring (22), the two tension springs (17), the arcuate plate (16), and the positioning rod (15) are included.
The sliding groove rod (21) is fixedly provided to the rotor (19), and is provided.
The sliding groove (20) is provided between the two sliding groove rods (21).
The fifth compression spring (22) is fixedly provided between the sliding groove rod (21) and the inner wall of the sliding groove (20).
The two second tension springs (17) are fixedly provided in the sliding groove (20).
The arcuate plate (16) is fixedly provided to the tension spring (17), and is provided.
The positioning rod (15) is fixedly provided between the arc-shaped plate (16) at one end and the inner wall of the housing (10).
The two rotors (19) can slide back and forth on the sliding groove (20).
The two tension springs (17) are vertically symmetrical with respect to the sliding groove (20).
The removable stepped floor heating according to claim 5.

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