CN214333498U - High-efficiency heat exchanger based on foam metal enhanced heat exchange - Google Patents

Abstract

The utility model is suitable for a heat exchanger technical field provides a high-efficient heat exchanger based on heat transfer is reinforceed to foamed metal, the on-line screen storage device comprises a base, a plurality of pulleys are installed to the bottom of base, and the top of base is connected with the heat exchanger body, the air conditioning import is installed on the top of heat exchanger body, and the bottom of heat exchanger body installs the air conditioning export, the heat source import is installed on the top of heat exchanger body, and the heat source export is installed to the bottom of heat exchanger body. The utility model discloses in, through the downward extrusion T type pole, can make the peak type board and the ground contact that T type pole bottom is connected, the peak type board is convenient for increase and the frictional force on ground, can be with the heat exchanger body restriction that the base is connected with and top at appointed position, through butt joint piece and the connection to the groove, be convenient for fix T type pole and peak type board, through reset spring's effect, be convenient for with T type pole and peak type board rebound, the base of being convenient for removes through the pulley.

Description

High-efficiency heat exchanger based on foam metal enhanced heat exchange

Technical Field

The utility model belongs to the technical field of the heat exchanger, especially, relate to a high-efficient heat exchanger based on heat transfer is reinforceed to foam metal.

Background

The heat exchanger is equipment for transferring partial heat of hot fluid to cold fluid, also called heat exchanger, the heat exchanger plays an important role in chemical industry, petroleum industry, power industry, food industry and other industrial production, the heat exchanger can be used as a heater, a cooler, a condenser, an evaporator, a reboiler and the like in chemical production, and the application is wide.

The high-efficient heat exchanger of heat transfer is reinforceed to current foam metal is at the in-process that uses, because its volume is great, difficult transport, and when needs outwards discharge its inside hot water, butt joint between its unable fine and the loading apparatus, leads to the waste of water source easily, and also just is difficult for dismantling the heat exchanger body get off, and the staff of being inconvenient for overhauls it.

SUMMERY OF THE UTILITY MODEL

The utility model provides a high-efficient heat exchanger based on heat transfer is reinforceed to foam metal aims at solving current foam metal and reinforces its in-process of using of high-efficient heat exchanger of heat transfer, because its volume is great, is difficult for the transport, and when needs outwards discharge its inside hot water, it can't be fine and the loading equipment between carry out the butt joint, leads to the waste at water source easily, and also just not just dismantle the heat exchanger body get off, the staff of being not convenient for carries out the problem of overhauing it.

The utility model is realized in such a way, a high-efficient heat exchanger based on foam metal enhanced heat exchange, which comprises a base, a plurality of pulleys are arranged at the bottom end of the base, a heat exchanger body is connected above the base, an air-conditioning inlet is arranged at the top end of the heat exchanger body, an air-conditioning outlet is arranged at the bottom end of the heat exchanger body, a heat source inlet is arranged at the top end of the heat exchanger body, a heat source outlet is arranged at the bottom end of the heat exchanger body, a limiting mechanism is arranged at the top end of the base, a sleeve is arranged in the limiting mechanism, a reset spring is fixedly connected at the bottom end in the sleeve, butt-joint grooves are connected at the top ends of two sides of the sleeve, a T-shaped rod is movably connected in the sleeve, butt-joint blocks are fixedly connected at the bottom ends of two sides of the T-shaped rod, the butt-joint blocks are connected with the butt-joint grooves in a clamping manner, and the T-shaped rod passes through a peak-shaped plate fixedly connected with the base, and be connected for relatively between the bottom of peak type board and base, the fixed surface of T type pole is connected with the baffle, and is swing joint between baffle and reset spring's the top, the surface mounting of heat exchanger body has disassembly body, adjustment mechanism is installed on the top of base.

Preferably, the T-shaped rod forms a clamping structure with the butt joint groove through the butt joint block, and the baffle forms an elastic telescopic structure with the sleeve through the return spring.

Preferably, the inside of disassembly body is including two connecting blocks, and is connected between the bottom of connecting block and heat exchanger body, the recess has been seted up respectively to the top both sides of connecting block, and the inside fixedly connected with connecting rod of recess, the surface swing joint of connecting rod has first arc, and is connected between one side of first arc and heat exchanger body to one side gomphosis of first arc is connected with the spacing groove, one side swing joint of connecting rod has the second arc, and is connected between one side of second arc and heat exchanger body, one side of second arc is connected with the stopper, and is connected for the block between the inside of stopper and spacing groove.

Preferably, the first arc-shaped plate forms a turnover structure through the connecting rod and the connecting block, and the first arc-shaped plate forms a clamping structure through the limiting groove and the limiting block.

Preferably, adjustment mechanism's inside is including two sleeves, and is fixed connection between the top of sleeve pipe and base to sheathed tube inner wall one side fixedly connected with axis of rotation, top one side fixedly connected with cushion of base, and the top of cushion installs servo motor, be fixed connection between servo motor and the sheathed tube one side, and servo motor passes and be connected for the gomphosis between the inside of sleeve pipe and axis of rotation, one side of axis of rotation is rotated and is connected with first threaded rod, and the surperficial threaded connection of first threaded rod has the second threaded rod, be threaded connection between the bottom of second threaded rod and connecting block, and be swing joint between second threaded rod and the sheathed tube inside, sheathed tube one side swing joint has the inserted pin, and the inserted pin passes and be swing joint between the one side of sleeve pipe and second threaded rod.

Preferably, the first threaded rod forms a rotating structure through the rotating shaft and the sleeve, and the inserted pin forms a detachable structure through the sleeve and the second threaded rod.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses in, under stop gear's effect, through pushing down T type pole, can make peak type board and the ground contact that T type pole bottom is connected, the peak type board is convenient for increase and the frictional force on ground, can be with the base and the heat exchanger body restriction that the top is connected at appointed position, through butt joint piece and the connection to the groove, be convenient for fix T type pole and peak type board, through reset spring's effect, be convenient for with T type pole and peak type board rebound, the base of being convenient for removes through the pulley.

2. The utility model discloses in, under the effect of disassembly body, through overturning first arc and second arc on the surface of connecting rod, can make the spacing groove on the first arc be connected with the stopper on the second arc, be convenient for fix the heat exchanger body through first arc and second arc, be convenient for install and dismantle the facilitates use the heat exchanger body.

3. The utility model discloses in, under adjustment mechanism's effect, through servo motor's work, can make first threaded rod rotate to driving the second threaded rod and reciprocating, the heat exchanger body that the connecting block that can make second threaded rod top connect is connected reciprocates, is convenient for unload when needs, can make heat exchanger body and loading equipment dock in real time.

Drawings

Fig. 1 is a schematic structural view of a high-efficiency heat exchanger based on foam metal enhanced heat exchange of the present invention;

fig. 2 is a schematic structural view of the limiting mechanism of the present invention;

FIG. 3 is a schematic side view of the detaching mechanism of the present invention;

FIG. 4 is a schematic structural view of a top view portion of the detaching mechanism of the present invention;

fig. 5 is a schematic structural diagram of the adjusting mechanism of the present invention.

In the figure: 1. a base; 2. a pulley; 3. a heat exchanger body; 4. a cold air inlet; 5. a cold air outlet; 6. a heat source inlet; 7. a heat source outlet; 8. a limiting mechanism; 801. a sleeve; 802. a return spring; 803. a butt joint groove; 804. a T-shaped rod; 805. a butt joint block; 806. a peak plate; 807. a baffle plate; 9. a disassembly mechanism; 901. connecting blocks; 902. a groove; 903. a connecting rod; 904. a first arc-shaped plate; 905. a limiting groove; 906. a second arc-shaped plate; 907. a limiting block; 10. an adjustment mechanism; 1001. a sleeve; 1002. a rotating shaft; 1003. cushion blocks; 1004. a servo motor; 1005. a first threaded rod; 1006. a second threaded rod; 1007. and (6) inserting a pin.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1-5, the present invention provides a high efficiency heat exchanger based on foam metal enhanced heat exchange, which comprises a base 1, a plurality of pulleys 2 mounted at the bottom end of the base 1, a heat exchanger body 3 connected above the base 1, a cool air inlet 4 mounted at the top end of the heat exchanger body 3, a cool air outlet 5 mounted at the bottom end of the heat exchanger body 3, a heat source inlet 6 mounted at the top end of the heat exchanger body 3, a heat source outlet 7 mounted at the bottom end of the heat exchanger body 3, a position-limiting mechanism 8 mounted at the top end of the base 1, a sleeve 801 included in the position-limiting mechanism 8, a return spring 802 fixedly connected to the bottom end of the sleeve 801, a butt-joint groove 803 connected to the top end of the sleeve 801, a T-shaped rod 804 movably connected to the inside of the sleeve 801, butt-joint blocks 805 fixedly connected to the bottom ends of the T-shaped rod 804, and a snap-joint block 805 connected to the inside of the butt-joint groove 803, the T-shaped rod 804 penetrates through the base 1 and is fixedly connected with the peak-shaped plate 806, the peak-shaped plate 806 is connected with the bottom end of the base 1 in a relative mode, the surface of the T-shaped rod 804 is fixedly connected with the baffle 807, the baffle 807 is movably connected with the top end of the reset spring 802, the surface of the heat exchanger body 3 is provided with the dismounting mechanism 9, and the top end of the base 1 is provided with the adjusting mechanism 10.

In this embodiment, the T-bar 804 is pressed downward to contact the peak plate 806 connected to the bottom end thereof with the ground, thereby increasing the frictional force with the ground.

Furthermore, the T-shaped rod 804 forms an engaging structure with the abutting groove 803 through the abutting block 805, and the baffle 807 forms an elastic telescopic structure with the sleeve 801 through the return spring 802.

In this embodiment, the connection between the docking block 805 and the docking groove 803 facilitates the fixing and limiting of the T-bar 804 and the peak plate 806, and the T-bar 804 and the peak plate 806 can be moved upward by the action of the return spring 802.

Further, the inside of detaching mechanism 9 is including two connecting blocks 901, and be connected between the bottom of connecting block 901 and heat exchanger body 3, recess 902 is seted up respectively to the top both sides of connecting block 901, and the inside fixedly connected with connecting rod 903 of recess 902, the surface swing joint of connecting rod 903 has first arc 904, and be connected between one side of first arc 904 and heat exchanger body 3, and one side gomphosis of first arc 904 is connected with spacing groove 905, one side swing joint of connecting rod 903 has second arc 906, and be connected between one side of second arc 906 and heat exchanger body 3, one side of second arc 906 is connected with stopper 907, and be the block connection between the inside of stopper 907 and spacing groove 905.

In this embodiment, two grooves 902 are formed at the top end of the connecting block 901, a first arc-shaped plate 904 is connected inside one groove 902, and a second arc-shaped plate 906 is connected inside the other groove 902.

Further, the first arc-shaped plate 904 forms an overturning structure through the connecting rod 903 and the connecting block 901, and the first arc-shaped plate 904 forms a clamping structure through the limiting groove 905 and the limiting block 907.

In this embodiment, the limiting groove 905 on the first arc-shaped plate 904 is connected with the limiting block 907 on the second arc-shaped plate 906, so that the heat exchanger body 3 can be conveniently mounted and dismounted through the first arc-shaped plate 904 and the second arc-shaped plate 906.

Furthermore, the interior of the adjusting mechanism 10 includes two sleeves 1001, and the sleeves 1001 are fixedly connected with the top end of the base 1, a rotating shaft 1002 is fixedly connected with one side of the inner wall of the sleeve 1001, a cushion block 1003 is fixedly connected with one side of the top end of the base 1, a servo motor 1004 is arranged at the top end of the cushion block 1003, the servo motor 1004 is fixedly connected with one side of the sleeve 1001, a servo motor 1004 is inserted into the sleeve 1001 and is engaged with the inside of the rotary shaft 1002, a first screw rod 1005 is rotatably connected to one side of the rotary shaft 1002, and a second threaded rod 1006 is connected to the surface of the first threaded rod 1005 in a threaded manner, the second threaded rod 1006 is connected to the bottom end of the connecting block 901 in a threaded manner, and the second threaded rod 1006 is movably connected with the interior of the sleeve 1001, one side of the sleeve 1001 is movably connected with a plug 1007, and the inserting tip 1007 passes through the sleeve 1001 and is movably connected with one side of the second threaded rod 1006.

In the present embodiment, the servo motor 1004 can control the speed and position accuracy very accurately, convert the voltage signal into torque and rotation speed to drive the controlled object, the rotation speed of the rotor of the servo motor 1004 is controlled by the input signal and can respond quickly, and the servo motor 1004 is used as an actuator in an automatic control system, has the characteristics of small electromechanical time constant, high linearity, starting voltage and the like, can convert the received electric signal into angular displacement or angular speed on the motor shaft and output the angular displacement or angular speed, and the servo motor 1004 is controlled by the control switch.

Further, the first threaded rod 1005 is in a rotating structure through the rotating shaft 1002 and the sleeve 1001, and the inserting tip 1007 is in a detachable structure through the sleeve 1001 and the second threaded rod 1006.

In the present embodiment, the second screw rod 1006 can be moved up and down by the rotation of the first screw rod 1005, and the heat exchanger main body 3 can be moved up and down.

The utility model discloses a theory of operation and use flow: firstly, the base 1 slides to a designated position through the pulley 2, the peak-shaped plate 806 connected with the bottom end of the T-shaped rod 804 is contacted with the ground by pressing the T-shaped rod 804 downwards, the peak-shaped plate 806 is convenient for increasing the friction force with the ground, the base 1 and the heat exchanger body 3 connected with the top end of the base 1 can be limited to the designated position, the T-shaped rod 804 and the peak-shaped plate 806 are convenient to be fixed through the connection of the butt joint block 805 and the butt joint groove 803, the T-shaped rod 804 and the peak-shaped plate 806 are convenient to move upwards through the action of the reset spring 802, the base 1 is convenient to move through the pulley 2, the limit groove 905 on the first arc-shaped plate 904 can be connected with the limit block 907 on the second arc-shaped plate 906 through overturning the first arc-shaped plate 904 and the second arc-shaped plate 906 on the surface of the connecting rod 903, the heat exchanger body 3 is convenient to be fixed through the first arc-shaped plate 904 and the second arc-shaped plate 906, be convenient for install and dismantle heat exchanger body 3, facilitate the use, through servo motor 1004's work, can make first threaded rod 1005 rotate to driving second threaded rod 1006 and reciprocating, can making heat exchanger body 3 that connecting block 901 that second threaded rod 1006 top is connected reciprocates, being convenient for when needs are unloaded, can making heat exchanger body 3 dock with loading equipment in real time, just so accomplished the utility model discloses a theory of operation.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (6)

1. The utility model provides a high-efficient heat exchanger based on heat transfer is reinforceed to foam metal, including base (1), its characterized in that: the heat exchanger is characterized in that a plurality of pulleys (2) are installed at the bottom end of the base (1), a heat exchanger body (3) is connected above the base (1), a cold air inlet (4) is installed at the top end of the heat exchanger body (3), a cold air outlet (5) is installed at the bottom end of the heat exchanger body (3), a heat source inlet (6) is installed at the top end of the heat exchanger body (3), a heat source outlet (7) is installed at the bottom end of the heat exchanger body (3), a limiting mechanism (8) is installed at the top end of the base (1), a sleeve (801) is included inside the limiting mechanism (8), a reset spring (802) is fixedly connected to the bottom end of the sleeve (801), butt joint grooves (803) are connected to the top ends of two sides of the sleeve (801), a T-shaped rod (804) is movably connected to the inside of the sleeve (801), and butt joint blocks (805) are fixedly connected to the bottom ends of two sides of the T-shaped rod (804), and butt joint piece (805) and butt joint groove (803) inside between be the block connection, T type pole (804) pass base (1) fixedly connected with peak type board (806), and be connected for relatively between peak type board (806) and the bottom of base (1), the fixed surface of T type pole (804) is connected with baffle (807), and is swing joint between baffle (807) and reset spring (802) the top, the surface mounting of heat exchanger body (3) has disassembly body (9), adjustment mechanism (10) are installed to the top of base (1).

2. The high-efficiency heat exchanger based on the foam metal enhanced heat exchange as set forth in claim 1, wherein: the T-shaped rod (804) forms a clamping structure with the butt joint groove (803) through the butt joint block (805), and the baffle (807) forms an elastic telescopic structure with the sleeve (801) through the return spring (802).

3. The high-efficiency heat exchanger based on the foam metal enhanced heat exchange as set forth in claim 1, wherein: the interior of the disassembling mechanism (9) comprises two connecting blocks (901), the connecting blocks (901) are connected with the bottom end of the heat exchanger body (3), two sides of the top end of each connecting block (901) are respectively provided with a groove (902), a connecting rod (903) is fixedly connected inside the groove (902), the surface of the connecting rod (903) is movably connected with a first arc-shaped plate (904), and the first arc-shaped plate (904) is connected with one side of the heat exchanger body (3), one side of the first arc-shaped plate (904) is embedded and connected with a limit groove (905), one side of the connecting rod (903) is movably connected with a second arc-shaped plate (906), and the second arc-shaped plate (906) is connected with one side of the heat exchanger body (3), one side of the second arc-shaped plate (906) is connected with a limit block (907), and the limiting block (907) is connected with the inside of the limiting groove (905) in a clamping manner.

4. A high efficiency heat exchanger based on foam metal enhanced heat exchange as claimed in claim 3, wherein: the first arc-shaped plate (904) forms a turnover structure through the connecting rod (903) and the connecting block (901), and the first arc-shaped plate (904) forms a clamping structure through the limiting groove (905) and the limiting block (907).

5. The high-efficiency heat exchanger based on the foam metal enhanced heat exchange as set forth in claim 1, wherein: the adjusting mechanism (10) comprises two sleeves (1001) inside, the sleeves (1001) are fixedly connected with the top end of the base (1), a rotating shaft (1002) is fixedly connected to one side of the inner wall of each sleeve (1001), a cushion block (1003) is fixedly connected to one side of the top end of the base (1), a servo motor (1004) is installed at the top end of each cushion block (1003), the servo motor (1004) is fixedly connected with one side of each sleeve (1001), the servo motor (1004) penetrates through the sleeves (1001) to be embedded and connected with the inside of the rotating shaft (1002), one side of the rotating shaft (1002) is rotatably connected with a first threaded rod (1005), the surface of the first threaded rod (1005) is in threaded connection with a second threaded rod (1006), the second threaded rod (1006) is in threaded connection with the bottom end of the connecting block (901), and the second threaded rod (1006) is movably connected with the inside of each sleeve (1001), one side of the sleeve (1001) is movably connected with a pin (1007), and the pin (1007) penetrates through one side of the sleeve (1001) and the second threaded rod (1006) to be movably connected.

6. The high-efficiency heat exchanger based on the foam metal enhanced heat exchange as set forth in claim 5, wherein: the first threaded rod (1005) forms a rotating structure through the rotating shaft (1002) and the sleeve (1001), and the inserting tip (1007) forms a detachable structure through the sleeve (1001) and the second threaded rod (1006).

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