DE202013105296U1 - Steam generator for realizing a continuous injection of high-pressure steam - Google Patents

Abstract

A steam generator for realizing the continuous injection of high-pressure steam, comprising an evaporation pot (1), wherein a water inlet opening (12) and a steam outlet opening (14) are provided at the top of the evaporation pot (1), and wherein the water inlet opening (12) is connected to a water pump, and wherein on the inner bottom surface of the evaporation pot (1) a heating element (10) is arranged, and wherein the inner bottom surface of the evaporation pot (1) is inclined, and wherein the heating element (10) is separated and has at least two heat generating units, and wherein on the inner bottom surface of the evaporation pot (10), the highest point of the at least two heat-generating units has different heights, and wherein a constant-off thermostat is located at the highest point of the heat-generating unit.

Description

Technical area

The invention relates to a steam generator, in particular a steam generator, which can inject the high pressure steam continuously, it is used in industrial steam irons, steam cleaners, overhead ironing machines, sterilizers of high-pressure steam and in other areas.

State of the art

At present, steam products on the market such as industrial steam irons, steam cleaners, overhead ironing machines and high pressure steam sterilizers all have a pressure below 3.5 bar. The reason that the pressure can not be made higher is that the water supply system of the steam products will have problems at too high pressure.

Currently, in most automatic water supply systems in areas of industrial steam irons, steam cleaners and overhead ironing machines, the water supply is realized either by the principle of connected tanks with balanced water level or by using the thermostat (constant open thermostat) or the thermistor, the water pump over the temperature is controlled within the steam generator. In the first water supply mode, the pressure in the boiler must be kept very small in order to keep the water supply smooth. With such products, the steam has a small speed and small amount, and the ironing does not have a good effect. In the second mode, the water supply to the water pump is controlled by the thermostat or thermistor constantly open, as the amount of water in the boiler decreases and the temperature of the hotplates increases, the thermostat is switched and the thermistor is switched, then the water pump is opened after the water has entered If the temperature of the heating plates drops, the thermostat or thermistor is switched off, the water pump does not supply water, this cycle is repeated. In this way, if the vapor pressure is less than 3.5 bar, products can realize the continuous steam injection, but if the pressure exceeds 4.5 bar, since the steam already has a high temperature, the thermostat recognizes it after the water supply of the water pump, that the temperature can not be lowered, it causes the water pump continues to supply water.

Brief description of the invention

The technical problem to be solved by the present invention is to provide a steam generator so that the steam generator continuously injects the high-pressure steam.

In order to solve the above technical problem, the present invention employs the following technical solutions: a steam generator for realizing the continuous injection of high-pressure steam, comprising an evaporation pot, wherein at the top of the evaporation pot a water inlet opening and a steam outlet opening are provided, and wherein the water inlet opening with Water pump is connected, and wherein on the inner bottom surface of the evaporation pot, a heating element is arranged, and wherein the inner bottom surface of the evaporation pot is tilted, and wherein the heating element is separated and has at least two heat generating units, and wherein on the inner bottom surface of the evaporation pot the highest Point of at least two heat generating units has different height, and wherein a constant-connected thermostat is located at the highest point of the heat generating unit.

Preferably, the inner bottom surface of the evaporation pot is an integral pitch.

Preferably, the inner bottom surface of the evaporation pot is a step-shaped surface.

Preferably, the heat generating units are arranged along the inner bottom surface of the evaporation pot in the squadron.

Preferably, the number of the heat generating unit is two, wherein two heat generating units are respectively the annular outer heating plate and the inner heating plate, and wherein the outer heating plate is disposed on the outer periphery side of the inner heating plate.

Preferably, the two constant-connected thermostats on the outer heating plate and the inner heating plate have the same value for temperature control.

Preferably, the power of the inner heating plate is smaller than the power of the outer heating plate.

Preferably, the inner heating plate and the outer heating plate are connected in series with a pressure switch in series, the pressure switch being connected in parallel with a pressure indication light.

Preferably, a screw is welded to the bottom of the evaporation pot, wherein on the inner heating plate and the outer heating plate corresponding through holes are provided, wherein they are mounted through the through holes in the screw and secured by nuts.

Preferably, the water pump is connected in series with a water level switch, wherein the water level switch is connected in parallel with a lack of water indicator light, and wherein a solenoid valve is disposed at the steam outlet, and wherein the solenoid valve is connected in series with the steam switch.

In the present invention, the inner bottom surface of the evaporation pot is inclined, and the inner bottom surface of the evaporation pot may be an integral slope or may be steppedly inclined. And, at least two heat generating units are arranged on the inner bottom surface of the evaporation pot, and the two heat generating units operate in parallel. On the inner bottom surface of the evaporation pot, the highest point of a plurality of heat generating units has different heights, and a constant connected thermostat is disposed at the highest point of the heat generating unit to control the operation of the corresponding heat generating unit, respectively. Thus, after the partial evaporation of the water in the evaporation pot the water level in the evaporation pot drops, the temperature of the constant connected thermostat at the relatively high position of the inner bottom surface of the evaporation pot increases rapidly, when the shutdown temperature is reached, the thermostat is turned off, now sucks Water pump to the water and the heat-generating unit of high position corresponding to the constant-connected thermostat stops with heating. After the cold water enters the evaporation pot, the temperature of the high-position heat generating unit drops, and the constant-connected thermostat thereon is switched, the water pump stops water suction, and the high-position heat generation unit restores the heating. During this process, since the highest point of the other low-level heat generating units is always below the water level, and at the same time the constant-switched thermostat of the low-level heat generating units are always switched, the low-position heat generating units constantly heat. Because the low-level heat generating units are constantly heating, it is ensured that the steam is constantly generated in the evaporation pot and thus the water pump sucks the water. If the high position heat generating unit is not in operation, enough steam is also injected by pressing the steam splash switch so that it can be ensured that the steam generator continuously injects the high pressure steam.

Brief description of the drawings

In connection with the figures and detailed embodiments, the present invention will be explained in more detail.

1 is a schematic structural diagram of the evaporation pot;

2 Fig. 12 is a schematic structural diagram of the inner heating plate and the outer heating plate;

3 Fig. 12 is a schematic structural diagram of the assembly of the inner heating plate, the outer heating plate and the bottom part of the evaporation pot;

4 Fig. 12 is a schematic diagram of the present invention;

5 is a schematic representation of the time when the water level in the evaporation pot is higher than the constant high-position thermostat;

6 is a schematic representation at the time when the water level in the evaporation pot is lower than the constant high-position thermostat (and at the same time higher than the constant low-position thermostat;

7 Fig. 12 is a schematic sectional view of the bottom of the evaporation pot in the second embodiment;

8th FIG. 12 is a schematic plan view of the bottom of the evaporation pot in the second embodiment; FIG.

9 Fig. 11 is a schematic sectional view of the bottom of the evaporation pot in the third embodiment;

10 Fig. 11 is a schematic plan view of the bottom of the evaporation pot in the third embodiment;

11 Fig. 15 is a schematic sectional view of the bottom of the evaporation pot in the third embodiment after deformation;

Detailed embodiments

Hereinafter, the first embodiment of the present invention will be described in connection with FIG 1 to 6 explained in more detail.

1 shows a steam generator for realizing the continuous injection of high-pressure steam, comprising an evaporation pot 1 , wherein at the top of the evaporation pot 1 a water inlet opening 12 , a steam outlet 14 and a pressure switch 13 are provided, and wherein the water inlet opening 12 connected to water pump, and being at the bottom of the evaporation pot 1 a sewage opening 11 is provided, and wherein on the inner bottom surface of the evaporation pot 1 a heating element 10 is arranged, and wherein the inner bottom surface of the evaporation pot is inclined, and wherein the heating element 10 is separated and has at least two heat generating units, and wherein on the inner bottom surface of the evaporation pot, the highest point of the at least two heat generating units has different height, and wherein a constant-connected thermostat is located at the highest point of the heat generating unit. In particular, in this embodiment, the bottom of the evaporation pot is 1 tilted so that the inner bottom surface of the evaporation pot 1 has a form of integral slope. Thus, despite relatively large change in the water level 16 inside the evaporation pot 1 is a relatively large part of the inner bottom surface of the evaporation pot below the water level 16 because of the integral slope 105 , Since the constant switched thermostat is still in the switched state, the heat generating unit can be below the water level 16 continue to heat to produce the steam.

As in 2 As shown, the number of the heat generating unit is two, with two heat generating units each being the annular outer heating plate 101 and the inner heating plate 102 are, and where the outer heating plate 101 on the side of the outer periphery of the inner heating plate 102 is arranged. If two hotplates on the inner bottom surface of the evaporation pot 1 are mounted, the highest point of two heating plates on the inner bottom surface of the evaporation pot has different height, the connecting line of Highest points passes through the middle of two heating plates, the constant high-position thermostat 1010 on the outer heating plate 101 is located just above the constant low temperature thermostat 1020 on the inner heating plate 102 , the two constant-connected thermostats on the outer heating plate 101 and the inner heating plate 102 have equal value for temperature control, and the performance of the inner heating plate 102 is less than the power of the outer heating plate 101 , At the inner heating plate 102 is an internal constant switched thermostat 1020 arranged, only when lack of water, the inner constant switched thermostat 1020 off. At the outer heating plate 101 is a constant switched thermostat 1010 mounted high position for controlling the water intake of the water pump. The constantly switched thermostat is used for water shortage 1010 high position also as a protective thermostat of the outer heating plate 101 , When the constant-connected thermostat 1010 high position of the outer heating plate 101 is switched, the branch line of the water pump is switched short, and the water pump does not work. When the constant-connected thermostat 1010 High position is switched off, the branch line of the water pump is connected, the water pump sucks the water, now is the distributed voltage for the outer heating plate 101 very small, and it does not heat up substantially. The constant switched thermostat 1010 high position of the outer heating plate 101 is located at the highest point of the outer heating plate 101 and reveals itself after attachment to the evaporation pot 1 above the water level and thus little of the internal steam temperature in the evaporation pot 1 affected. The inner heating plate 102 is constantly in the heating state, to ensure that the steam is constantly in the evaporation pot 1 is produced. Because the constant switched thermostat 1010 high position is turned off, stops the outer heating plate when water suction of the water pump with heating. Thus, after the entry of cold water, the constant-connected thermostat 1010 high position will be reset in a short time, and the water pump will not suck in too much cold water.

As in 3 pictured is a snail 103 at the bottom of the evaporation pot 1 welded, taking on the inner heating plate 102 and the outer heating plate 101 corresponding through-holes are provided, being mounted through the through-holes in the screw and by nuts 104 are attached.

As in 4 shown are the inner heating plate 102 and the outer heating plate 101 connected in series with a pressure switch, wherein the pressure switch is connected in parallel with an indicator light. The water pump is connected in series with a water level switch, wherein the water level switch is connected in parallel with a lack of water indicator light. Since the water level switch is connected to the circuit of the water pump, the water pump does not run empty even if the outer switched thermostat of the outer heating plate is turned off. A solenoid valve is disposed on the steam outlet port and the solenoid valve is connected in series with the steam switch.

As in 5 and 6 shown, have the two constant-connected thermostats on the outer heating plate 101 and the inner heating plate 102 same value for temperature control. But because the water level in the evaporation pot 1 is constantly changing and the two constant-connected thermostats on the inner bottom surface of the evaporation pot 1 have different heights, the detected temperatures are also different. After the partial evaporation of the water in the evaporation pot 1 the water level drops 16 in the evaporation pot 1 From, the temperature of the constant-connected thermostat at the relatively high position of the inner bottom surface of the evaporation pot 1 (namely the constant switched thermostat 1010 high position on the outer heating plate 1 ) increases rapidly, when the shutdown temperature is reached, the constant switched thermostat becomes high position 1010 switched off, now the water pump sucks the water and the heating is stopped. After entering the cold water in the evaporation pot 1 drops the temperature of the outer heating plate 101 off, and the constant high-position thermostat 1010 it is switched on, the water pump stops with the water suction, and the outer heating plate 101 Restores the heating. Because during this process the inner heating plate 102 always below the water level 16 is the constant switched thermostat is low position 1020 on the inner heating plate 102 also switched, after which heated the inner heating plate 102 constantly. Because the inner heating plate 102 Also, constantly heated, it ensures that the steam is constantly in the evaporation pot 1 is generated and thus the water pump sucks the water. If the outer heating plate 101 is not in the heating mode, enough steam is injected by pressing the steam splash switch.

Hereinafter, the second embodiment of the present invention will be described in connection with FIGS 7 and 8th explained in more detail, as the first embodiment, the inner bottom surface of the evaporation pot 1 also the integral slope 105 , and the heat generating units on the slope 105 are arranged in steps. There are also two heat generating units, they are semi-circular. Here is the constant switched thermostat 1010 high position of lying at the high position of the slope heat generating unit disposed at the bow tip, and the constant-connected thermostat 1020 low position of the lying at the low position of the slope heat generating unit at the position in the vicinity of the center of the straight edge of the semicircular body.

The following will be related to the 9 and 10 the third embodiment of the present invention explained in more detail. Unlike the first embodiment, the inner bottom surface of the evaporation pot is 1 a stepped surface 106 and the step-shaped surface is a circular step-shaped surface so that a plurality of heat-generating units can be arranged circularly on the circular step-shaped surface. And because each step-shaped area is high, the constant-connected thermostat can be placed at any position of the heat-generating unit. The stepwise arranged heat generating units can ensure the water level change in the evaporation pot. During the water intake of the water pump still a part of the heat generating units can continue to heat to produce the steam. Of course as in 11 shown, the stepped surface 106 of the evaporation pot 1 Also arranged as a two-stage structure of two semi-circular stepped surfaces, two heat generating units are arranged accordingly, and they are both semi-circular, as well as the constant-connected thermostat can be mounted at any position of the heat generating unit.

Claims (10)

Steam generator for realizing the continuous injection of high-pressure steam, comprising an evaporation pot ( 1 ), wherein at the top of the evaporation pot ( 1 ) a water inlet opening ( 12 ) and a steam outlet ( 14 ) are provided, and wherein the water inlet opening ( 12 ) is connected to the water pump, and wherein on the inner bottom surface of the evaporation pot ( 1 ) a heating element ( 10 ), and wherein the inner bottom surface of the evaporation pot ( 1 ) is inclined, and wherein the heating element ( 10 ) and has at least two heat generating units, and wherein on the inner bottom surface of the evaporation pot ( 10 ) the highest point of the at least two heat generating units has different heights, and wherein a constant switched off thermostat is located at the highest point of the heat generating unit. Steam generator for realizing the continuous injection of high-pressure steam according to claim 1, characterized in that the inner bottom surface of the evaporation pot ( 1 ) an integral slope ( 105 ). Steam generator for the realization of the continuous injection of high-pressure steam according to claim 1, characterized in that the inner Bottom surface of the evaporation pot ( 1 ) a stepped surface ( 106 ). Steam generator for realizing the continuous injection of high-pressure steam according to claim 2 or 3, characterized in that the heat-generating units along the inner bottom surface of the evaporation pot ( 1 ) are arranged in the squadron. Steam generator for realizing the continuous injection of high-pressure steam according to claim 2 or 3, characterized in that the number of the heat-generating unit is two, wherein two heat-generating units each have the annular outer heating plate ( 101 ) and the inner heating plate ( 102 ), and wherein the outer heating plate ( 101 ) on the side of the outer periphery of the inner heating plate ( 102 ) is arranged. Steam generator for realizing the continuous injection of high-pressure steam according to claim 5, characterized in that the two constant thermostats switched off at the outer heating plate ( 101 ) and the inner heating plate ( 102 ) have the same value for temperature control. Steam generator for realizing the continuous injection of high-pressure steam according to claim 6, characterized in that the power of the inner heating plate ( 102 ) smaller than the power of the outer heating plate ( 101 ). Steam generator for realizing the continuous injection of high-pressure steam according to claim 7, characterized in that the inner heating plate ( 102 ) and the outer heating plate ( 101 ) are connected in series with a pressure switch, wherein the pressure switch is connected in parallel with a pressure-indicating light. Steam generator for realizing the continuous injection of high pressure steam according to claim 7, characterized in that a screw ( 103 ) at the bottom of the evaporation pot ( 1 ), wherein on the inner heating plate ( 102 ) and the outer heating plate ( 101 ) through holes are provided through the through holes in the screw and by nuts ( 104 ) are attached. Steam generator for realizing the continuous injection of high-pressure steam according to one of claims 1 to 3, characterized in that the water pump is connected in series with a water level switch, wherein the water level switch is connected in parallel with a water-lack indicator light, and wherein a solenoid valve at the steam outlet is arranged, and wherein the solenoid valve is connected in series with the steam switch.

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