CN210772795U - Heat conduction oil furnace bypass system - Google Patents

Abstract

The utility model discloses a heat conduction oil furnace bypass system, its structure includes the heat conduction oil furnace, and a support, a burner, gas piping, a supporting plate, the solenoid valve, the manometer on the spot, the relief pressure valve, T type filter, gate valve and congeal the jar, through having set up congeal jar and T type filter, congeal the jar with moisture filtering in the air supply, reduce moisture in the air supply, naphthalene in with the air supply in order to avoid moisture and air supply, reaction such as ammonia corrodes the T type filter to the cushion in the relief pressure valve naphthalene in with the air supply, the magazine such as ammonia carries out the filtering, the clean and the efficiency of protection relief pressure valve and solenoid valve that have guaranteed the air supply have been reached, solved when using to the heat conduction oil furnace, because the water content is too big and the air supply in the air supply naphthalene, easy appearance of overlooking the thing such as ammonia, the relief pressure valve has been leaded to lose the effect, the problem.

Description

Heat conduction oil furnace bypass system

Technical Field

The utility model relates to a heat conduction oil furnace technical field, concretely relates to heat conduction oil furnace bypass system.

Background

The heat conduction oil furnace is a boiler which is heated by heat conduction oil, the heat conduction oil, also called organic heat carrier or heat medium oil, has more than fifty years of history as the application of an intermediate heat transfer medium in the industrial heat exchange process, a direct current boiler which is developed based on the forced circulation design idea generally takes coal, oil and gas as fuel, takes the heat conduction oil as a medium, utilizes a hot oil circulation oil pump to force the medium to carry out liquid phase circulation, transmits heat energy to heat utilization equipment and then returns to a heating furnace for reheating, has the advantages of obtaining high working temperature under low pressure, being capable of carrying out high-precision control work on the medium operation, and the heat conduction oil furnace needs to be copied through a bypass system.

When the heat-conducting oil furnace is used, the pressure reducing valve loses effect due to the excessive water content in the air source and the presence of objects such as naphthalene, ammonia and the like which are easy to overlook in the air source, and the electromagnetic valve breaks down due to the overhigh pressure of the air source.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

In order to overcome the defects of the prior art, the bypass system of the heat-conducting oil furnace is provided, and the problems that when the heat-conducting oil furnace is used, a pressure reducing valve loses effect and the pressure of an air source is too high to cause the failure of an electromagnetic valve due to the fact that the water content in the air source is too large and naphthalene, ammonia and other objects which are easy to look down exist in the air source are solved.

(II) technical scheme

The utility model discloses a following technical scheme realizes: the utility model provides a heat conduction oil furnace bypass system, including heat conduction oil furnace, support, combustor, gas piping, backup pad, solenoid valve, spot manometer, relief pressure valve, T type filter, gate valve and congeal the jar, heat conduction oil furnace bottom fixed mounting has the support, heat conduction oil furnace left surface fixed mounting has the combustor, the gas piping right-hand member is with combustor feed inlet fixed connection, backup pad and gas piping bottom left end looks welding, the solenoid valve bottom is linked up with the gas piping, spot manometer embedding gas piping top, the relief pressure valve bottom is linked up with the gas piping, T type filter upper end is linked up with the gas piping, the gate valve bottom is linked up with the gas piping, congeal jar upper end and gas piping fixed connection through the flange, the gate valve comprises valve body, supporting shoe, valve rod and rotor, the left end and the right end of the valve body are in threaded connection with a gas pipeline, the supporting block is fixedly connected with the top of the valve body, the lower end of the valve rod is rotatably connected with the supporting block, the lower end of the valve rod penetrates through the valve body, and the rotating body is fixedly connected with the top end of the valve rod.

Further, two supporting plates are arranged, and the structure of the supporting plates is a trapezoidal structure.

Furthermore, six gas pipelines are arranged, and the electromagnetic valves, the pressure reducing valves, the T-shaped filters, the gate valves and the water condensing cylinder are integrally communicated with one another through the gas pipelines.

Furthermore, a ball body is arranged in the valve body, and the middle end of the ball body is penetrated through by a ventilation hole.

Furthermore, the surface of the rotating body is provided with an anti-slip layer, and the thickness of the anti-slip layer is 0.5 CM.

Further, the bottom of the supporting block is of a circular structure, and the upper end connecting structure of the supporting block is of a cam-shaped structure.

Further, the bottom of the valve rod is connected with the ball body in the valve body, and a sealing ring is arranged at the joint of the valve rod and the valve body.

Furthermore, the material of the gas pipeline is austenite thin-wall stainless steel.

Furthermore, the rotator is made of aluminum alloy.

(III) advantageous effects

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

in order to solve the problems that when the heat-conducting oil furnace is used, the pressure reducing valve loses effect due to the fact that water content in an air source is too large and naphthalene, ammonia and other objects which are prone to overlook exist in the air source, and therefore the electromagnetic valve breaks down, the water condensing cylinder and the T-type filter are arranged, the water condensing cylinder filters water in the air source, the water in the air source is reduced, the T-type filter is prevented from being corroded by the water and the naphthalene, ammonia and other objects in the air source to filter magazines in the air source, the cleanliness of the air source is guaranteed, the effects of protecting the pressure reducing valve and the electromagnetic valve are achieved, and the problems that when the heat-conducting oil furnace is used, due to the fact that the water content in the air source is too large and the naphthalene, ammonia and other objects which are prone to overlook exist in the air source, the pressure reducing valve loses effect is caused by the fact that the air source pressure is.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is an enlarged schematic structural diagram of a position a of the present invention.

In the figure: the device comprises a heat-conducting oil furnace-1, a support-2, a burner-3, a gas pipeline-4, a support plate-5, an electromagnetic valve-6, an on-site pressure gauge-7, a pressure reducing valve-8, a T-shaped filter-9, a gate valve-10, a water condensing cylinder-11, a valve body-101, a support block-102, a valve rod-103 and a rotator-104.

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 and 2, the present invention provides a bypass system of a heat transfer oil furnace: the heat-conducting oil furnace comprises a heat-conducting oil furnace 1, a support 2, a burner 3, a gas pipeline 4, a support plate 5, an electromagnetic valve 6, an on-site pressure gauge 7, a pressure reducing valve 8, a T-shaped filter 9, a gate valve 10 and a water condensing cylinder 11, wherein the support 2 is fixedly arranged at the bottom of the heat-conducting oil furnace 1, the burner 3 is fixedly arranged on the left side surface of the heat-conducting oil furnace 1, the right end of the gas pipeline 4 is fixedly connected with a feed inlet of the burner 3, the support plate 5 is welded with the left end of the bottom of the gas pipeline 4, the bottom of the electromagnetic valve 6 is communicated with the gas pipeline 4, the on-site pressure gauge 7 is embedded into the top of the gas pipeline 4, the bottom of the pressure reducing valve 8 is communicated with the gas pipeline 4, the upper end of the T-shaped filter 9 is communicated with the gas pipeline 4, the bottom of the gate valve 10 is, the left end and the right end of the valve body 101 are in threaded connection with the gas pipeline 4, the supporting block 102 is fixedly connected with the top of the valve body 101, the lower end of the valve rod 103 is rotatably connected with the supporting block 102, the lower end of the valve rod 103 penetrates through the valve body 101, and the rotating body 104 is fixedly connected with the top end of the valve rod 103.

The number of the support plates 5 is two, the structure of the support plates is a trapezoidal structure, and the support plates can support the gas pipeline 4.

Six gas pipelines 4 are arranged, and the electromagnetic valve 6, the pressure reducing valve 8, the T-shaped filter 9, the gate valve 10 and the water condensing cylinder 11 are integrally communicated with one another by the gas pipelines 4, so that each part can play a role in the gas source in the gas pipelines 4, and the transmission of the gas source is not influenced.

Wherein, a ball body is arranged inside the valve body 101, and the middle end of the ball body is penetrated by a ventilation hole, so that the valve body 101 can block and unblock the air source in the gas pipeline 4.

The surface of the rotor 104 is provided with an anti-slip layer, and the thickness of the anti-slip layer is 0.5CM, so that slipping of a hand rotating the rotor 104 due to insufficient friction force is avoided.

The bottom of the supporting block 102 is a circular structure, and the upper end connecting structure is a cam-shaped structure, so that the valve rod 103 can be fixed.

Wherein, the bottom of the valve rod 103 is connected with the inner ball body of the valve body 101, and the joint of the valve rod 103 and the valve body 101 is provided with a sealing ring, so that the internal gas is prevented from being transmitted to the outside through a gap.

The gas pipeline 4 is made of austenite thin-wall stainless steel, has good comprehensive performance, can resist corrosion of various mediums and has good plasticity, toughness and weldability.

The rotating body 104 is made of aluminum alloy and has the advantages of light weight, good strength and good corrosion resistance.

According to the table above show, the utility model discloses rotor 104 adopts the aluminum alloy to make, when guaranteeing that density is light, has matter light, intensity is good and corrosion resisting property is good.

The T-shaped filter 9 is an indispensable device on a medium conveying pipeline, is usually arranged at a pressure reducing valve, a pressure release valve, a water level setting valve and inlet end equipment of other equipment of a squarer filter, and consists of a cylinder body, a stainless steel filter screen, a pollution discharge part, a transmission device and an electric control part, impurities of water to be treated are blocked after passing through a filter cartridge of the filter screen of the filter, when the water is required to be cleaned, the detachable filter cartridge is taken out and is re-filled after treatment, so that the T-shaped filter 9 is very convenient to use and maintain, and the T-shaped filter 9 of the equipment adopts a model specification of DN50PN 16; the water condensing cylinder 11 is a matched facility on a gas pipe network, is originally specially used for extracting accumulated water in artificial gas, gradually replaces gas with natural gas, has become a decoration because the natural gas does not contain moisture, generally considers the gradient not less than 0.3% in the pipeline design and construction process, sets the water condensing cylinder at the lowest point (the water condensing cylinder method has a standard diagram), considers the water drainage in the operation process, firstly considers the operation safety problem of a system rather than the water blockage problem if the pipeline is damaged, the gas leakage at the damaged part can cause the gas poisoning or explosion accident, and must be timely processed, and the water condensing cylinder 11 in the equipment adopts the model specification of DN50PN 16.

The working principle is as follows: when the device is used, firstly, the device is placed in a working area, then the device is connected with an external power supply, so that electric energy required by the work of the device can be provided, firstly, the gas pipeline 4 is connected with an external gas source and can provide a gas source for the gas pipeline 4, the gas source in the gas pipeline 4 enters the interior of the water condensing cylinder 11 through the left end of the water condensing cylinder 11, the water condensing cylinder 11 can filter and reduce water in the gas source by filtering the water in the gas source so as to prevent the water from reacting with naphthalene, ammonia and the like in the gas source to corrode a rubber mat in the pressure reducing valve 8, then, the gas source enters the interior of the gas pipeline 4 through the right end of the water condensing cylinder 11 to be transmitted, a gate valve 10 on the left end of the gas pipeline 4 can drive the valve rod 103 to rotate by rotating the rotor 104 and drive a ball in the interior of the valve body 101 to rotate, the gas pipeline 4 is adjusted in flow rate, the T-shaped filter 9 can filter the magazines such as naphthalene, ammonia and the like in the gas source, so that the cleanness of the gas source is guaranteed, then the gas source enters the combustor 3 through the pressure reducing valve 8 and the electromagnetic valve 6 to provide heat energy in the heat-conducting oil furnace 1, the ground pressure gauge 7 can detect the pressure in the gas pipeline 4, the pressure reducing valve 8 can adjust the pressure in the gas pipeline 4, the electromagnetic valve 6 can adjust the direction, the flow, the speed and other parameters of the gas source in the gas pipeline 4, and the effects of guaranteeing the cleanness of the gas source and protecting the pressure reducing valve and the electromagnetic valve are achieved.

The basic principle and the main characteristics of the utility model and the advantages of the utility model have been shown and described above, and the utility model discloses the standard part that uses all can purchase from the market, and dysmorphism piece all can be customized according to the record of the description with the drawing, and the concrete connection mode of each part all adopts conventional means such as ripe bolt rivet among the prior art, welding, and machinery, part and equipment all adopt prior art, conventional model, and conventional connection mode in the prior art is adopted in addition to circuit connection, and the details are not repeated here.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (7)

1. The utility model provides a heat conduction oil furnace bypass system which characterized in that: the heat-conducting oil furnace comprises a heat-conducting oil furnace (1), a support (2), a burner (3), a gas pipeline (4), a support plate (5), an electromagnetic valve (6), a local pressure gauge (7), a pressure reducing valve (8), a T-shaped filter (9), a gate valve (10) and a water condensing cylinder (11), wherein the support (2) is fixedly installed at the bottom of the heat-conducting oil furnace (1), the burner (3) is fixedly installed on the left side surface of the heat-conducting oil furnace (1), the right end of the gas pipeline (4) is fixedly connected with a feed inlet of the burner (3), the support plate (5) is welded with the left end of the bottom of the gas pipeline (4), the bottom of the electromagnetic valve (6) is communicated with the gas pipeline (4), the local pressure gauge (7) is embedded into the top of the gas pipeline (4), the bottom of the pressure reducing valve (8) is communicated with the gas pipeline (4), and the upper end of, the bottom of the gate valve (10) is communicated with a gas pipeline (4), the upper end of the water condensing cylinder (11) is fixedly connected with the gas pipeline (4) through a flange, the gate valve (10) is composed of a valve body (101), a supporting block (102), a valve rod (103) and a rotating body (104), the left end and the right end of the valve body (101) are in threaded connection with the gas pipeline (4), the supporting block (102) is fixedly connected with the top of the valve body (101), the lower end of the valve rod (103) is rotatably connected with the supporting block (102), the lower end of the valve rod (103) penetrates through the valve body (101), and the rotating body (104) is fixedly connected with the top end of the valve rod (103.

2. The heat transfer oil furnace bypass system of claim 1, wherein: the number of the supporting plates (5) is two, and the structure of the supporting plates is a trapezoidal structure.

3. The heat transfer oil furnace bypass system of claim 1, wherein: six gas pipelines (4) are arranged, and the solenoid valve (6), the pressure reducing valve (8), the T-shaped filter (9), the gate valve (10) and the water condensing cylinder (11) are integrally communicated with one another through the gas pipelines (4).

4. The heat transfer oil furnace bypass system of claim 1, wherein: a ball body is arranged in the valve body (101), and the middle end of the ball body is penetrated by a ventilation hole.

5. The heat transfer oil furnace bypass system of claim 1, wherein: the surface of the rotating body (104) is provided with an anti-slip layer, and the thickness of the anti-slip layer is 0.5 CM.

6. The heat transfer oil furnace bypass system of claim 1, wherein: the bottom of the supporting block (102) is of a circular structure, and the upper end connecting structure of the supporting block is of a cam-shaped structure.

7. The heat transfer oil furnace bypass system of claim 1, wherein: the bottom of the valve rod (103) is connected with the ball body inside the valve body (101), and a sealing ring is arranged at the joint of the valve rod (103) and the valve body (101).

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