KR100946302B1 - Rapid Heating Steam Boiler - Google Patents

Abstract

The present invention relates to an instantaneous heating steam boiler having a shape in which the flow pipe is disposed on the same plane as the plane of the electric heater.

Description

Rapid Heating Steam Boiler

The present invention relates to an instantaneous heating steam boiler having a shape in which the flow pipe is disposed on the same plane as the plane of the electric heater.

Since the conventional steam heating steam cleaner is equipped with an electromagnetic pump and the steam heating steam boiler in a housing having a single mounting chamber, the heat generated by the steam boiler affects the electronic pump, which hinders the regular movement of the pump due to thermal deformation. . Therefore, the water discharge amount of the electronic pump is irregular, so that the durability and steam injection efficiency of the electronic pump are poor.

In order to solve this problem, the one disclosed in Japanese Patent Laid-Open No. 9-192147 is proposed as a conventional steam boiler. That is, as shown in FIG. 14, the sensor 6 which senses the temperature of the steam boiler 5 is controlled by the intermittent operation of the electronic pump 9 through the control circuit 8 (microcomputer) and at the same time U The current of the magnetic electric heater 5b is adjusted to control the heat generation thereof.

However, since the additional elements such as the temperature sensor 6 and the control circuit 8 must be provided, the cost is much higher than the mechanical electric steam boiler having only the bimetal for starting the electronic pump and the bimetal for maintaining a specific temperature range of the heater. There is a limit to this (especially the cost of the control circuit is relatively very high).

In addition, as shown in Fig. 14, the steam boiler 5 includes a block 5c, a spiral flow path 5a through which the washing water 3 is supplied, and a spiral flow path. It consists of the U-shaped electric heater 5b located close to the inside of 5a. The water supply pipe 4 and the steam pipe 7 are connected to the water inlet and the steam outlet of the flow path 5a.

However, since the flow path 5a is a spiral shape wound around the outside of the electric heater 5b, the volume of the block 5c is increased by the spiral outer diameter, which is an obstacle to the slim modularization of the steam generating unit, and thus does not contribute to the compactness of the device. can not do it.

The present invention has been made in view of the above-mentioned problem, and an object of the present invention is to provide an instantaneous heating steam boiler that can realize the compactness of the device through the slim of the steam boiler.

In order to achieve the above object, the instantaneous heating steam boiler of claim 1 of the present invention,

Including an electric heater, a water flow pipe consisting of a water injection pipe, a steam discharge pipe, a connection pipe connecting the water injection pipe and the steam discharge pipe, and the block of the electric heater terminal and the water injection pipe and the steam discharge pipe is exposed It's done,

The flow path tube is characterized in that the shape disposed on the same plane as the plane of the electric heater.

According to this configuration, the flow path tube is arranged in a flat shape in the form of a plate, which can significantly reduce the height and contribute to slimming of the block.

The instantaneous heating steam boiler according to claim 2 of the present invention,

The connecting tube is characterized in that the bending is formed in a waveform form.

According to this structure, it can contribute to complete steaming by lengthening a flow distance with a corrugated connection pipe and heating enough.

The instantaneous heating steam boiler according to claim 3 of the present invention,

The connection pipe of the flow pipe is characterized in that the pressed mark is formed.

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The instantaneous heating steam boiler according to claim 4 of the present invention,

The flow passage tube is characterized in that the spiral spring is inserted.

According to this configuration, the spring functions as a heating element to widen the surface area in contact with the flowing water, thereby greatly contributing to complete vaporization or steaming.

The instantaneous heating steam boiler according to claim 5 of the present invention,

The inner diameter of the water injection pipe is characterized in that larger than the inner diameter of the steam discharge pipe.

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The instantaneous heating steam boiler according to claim 6 of the present invention,

A first flow path comprising an electric heater, a first connection pipe contacting a lower surface of the electric heater and connecting a first water injection pipe, a first steam discharge pipe, and a first connection pipe connecting the first water injection pipe and the first steam discharge pipe; A second flow passage consisting of a second steam injection pipe which is in contact with the upper surface of the heater and connected to the first steam discharge pipe, a second steam discharge pipe, and a second connection pipe connecting the second steam injection pipe and the second steam discharge pipe; And, the terminal of the electric heater and the first water injection pipe and the first steam discharge pipe, the second steam injection pipe and the second steam discharge pipe made of a block including the exposed,

The first channel and the second channel is characterized in that the shape disposed on the same plane as the plane of the electric heater.

The instantaneous heating steam boiler according to claim 7 of the present invention,

Each of the first connector and the second connector is bent to form a waveform.

As apparent from the above description, the instantaneous heating steam boiler of the present invention has the following effects.

Since the flow path tube is disposed on the plane of the electric heater in a planar form in the form of a plate, the height can be significantly reduced for the same surface area, thereby contributing to the slimming of the block.

Since the connecting pipe of the flow pipe is bent in the form of a wave, the flow distance can be lengthened, thereby contributing to complete steaming through sufficient heating.

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Since the spiral spring is inserted into the flow path tube, the spring functions as a heating element to receive heat from the flow path tube, thereby greatly widening the contact area with the flowing water, thereby greatly contributing to complete vaporization or steaming.

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Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 and 2 are front and rear perspective views showing a steam cleaner according to a preferred embodiment of the present invention.

As shown in Figure 1 and 2, the steam cleaner of the present embodiment is composed of a base assembly 100, which is largely shaped, and a main assembly 300 pivotably connected to the base assembly 100. In addition, the main assembly 300 is preferably a push rod assembly 500 consisting of a handle bar 510 and a handle 530 that can be adjusted in length.

As shown in Figure 1, the base assembly 100 is composed of a main body 110 and a steam injection hole (not shown) forming an appearance.

The main body 110 is composed of an upper cover 120 and a bottom plate 130. The bottom plate 130 is formed with a steam injection hole (not shown).

On the peripheral bottom plate of the steam injection hole (not shown), a pad attachment part (also called Velcro) (not shown) to which the pad is attached is formed. The steam injection hole (not shown) is connected to the steam generating unit 340, in particular the steam discharge pipe 357c of the steam boiler 350 through the tube.

As shown in FIGS. 1 to 4, the main assembly 300 includes a housing 310 forming an external shape and a steam generating unit 340 mounted to the housing 310.

As shown in FIG. 5, the housing 310 includes a front housing 320 and a rear housing 330.

The front housing 320 functions as a cover of the rear housing 330. The front housing 320 is provided with a power button cover 381, the power button 382 of the PCB 385 operates together with the operation of the power button cover 381.

The rear housing 330 is equipped with a steam generating unit 340 as shown in Figs.

The steam generating unit 340 is constituted by an electric pump 360 which supplies the water tank 380, the steam boiler 350, and the water of the water tank 380 to the steam boiler 350.

The bucket 380 is detachably mounted to the outside of the rear housing 330 as shown in FIGS. 1 and 2.

The steam boiler 350 and the electronic pump 360 are mounted in the steam boiler mounting chamber 350A and the electronic pump mounting chamber 360A of the rear housing 330 as shown in FIG. The rear housing 330 is provided with a partition wall 390A for separating the steam boiler mounting chamber 350A and the electronic pump mounting chamber 360A. At this time, it is preferable that the steam boiler mounting chamber 350A is disposed below the partition wall 390A, and the electronic pump mounting chamber 360A is disposed above.

In addition, the partition wall 390A is preferably formed with the through grooves 391 and 393 through which the suction tube (not shown) and the discharge tube (not shown) of the electron pump 360 pass. .

Similarly, it is preferable that the steam boiler mounting cover chamber 350B and the electromagnetic pump mounting cover chamber 360B are formed in the front housing 320 to cover the rear housing 330. Of course, when the partition wall 390A does not protrude, it is preferable that the partition wall 390B corresponding to the partition wall 390A is formed in the front housing 320.

By the configuration of the barrier rib 390A or the barrier ribs 390A and 390B, heat generation of the steam boiler 350 is blocked, and thus the pump can be stably pumped without affecting the electron pump 360.

In the present embodiment, the steam boiler 350 and the electron pump 360 are mounted on the rear housing 330 having the steam boiler mounting chamber 350A, the electronic pump mounting chamber 360A, and the partition wall 390A. It may function as a main housing, and the front housing 320 may serve as a cover of the rear housing 330 to function as an auxiliary housing. If the power button 382 is at the rear of the rear housing 330, on the contrary, the front housing 320 functions as the main housing.

In addition, the heat dissipation hole 331 is preferably formed in the rear housing 330 having the steam boiler mounting chamber 350A, as shown in FIGS. 2 and 5. Since the heat dissipation hole 331 emits heat generated by the steam boiler 350 to the outside, heat transfer to the electron pump 360 may be further blocked.

As such, since the structure capable of maximally suppressing defects due to thermal deformation of the electronic pump 360 is adopted, an inexpensive mechanical steam boiler 350 can be adopted.

As shown in FIG. 8, the mechanical steam boiler 350 is a starting temperature bimetal 352 ′ of the electronic pump 360 and a temperature maintaining bimetal 352 of the steam boiler 350 without using a temperature sensor and a control circuit. It is an instant heated electric boiler (350).

On the other hand, in order to quickly release the heat generated from the electronic pump 360 itself, the heat sink 370 is preferably mounted. 6 and 7, the heat sink 370 includes a bottom base 371, a side wall base 373, and a side wall base 373 to form a space in which the casing 361 of the electronic pump 360 is seated. The heat dissipation fin 375 is formed on the outer wall.

The heat sink 370 on which the electron pump 360 is mounted is mounted in the electron pump mounting chamber 360A. That is, the discharge hole 365 of the electron pump 360 is supported by the support hole 334 of the fixing bracket 333 fixed to the rear housing 330, and the suction hole 363 of the electron pump 360 is the rear housing 330. By being supported by the fastening bracket 335 fastened to the), the electronic pump 360 is fixed in the form of pressing the heat sink 370 down.

As shown in FIG. 4, the fastening bracket 335 includes an inlet support piece 337 for supporting the inlet port 363 and a fastening piece 338 fastened to the fastener 339 formed in the rear housing 330. It is a 'b' shape.

On the other hand, the heat sink 370 is preferably formed with an arrangement groove 377 is disposed protruding fixing bracket 333. In addition, it is preferable that the engaging jaw 335 is applied to the front surface of the heat sink 370 in the electronic pump mounting chamber 360A.

The placement groove 377 and the locking jaw 335 have a function of determining a position when the heat sink 370 is seated, so that assembly efficiency is good.

In addition, as shown in FIG. 5, the housing 310 may be provided with handle rod mounting portions 510A and 510B on which the handle rod 510 is mounted.

Each of the handle bar mounting groove 510A and the handle bar mounting groove 510B has a concave arc-shaped locking jaw 511 to which the lower end of the handle bar 510 is formed. The concave arc-shaped latching jaw 511 serves as a passage through which heat in the electron pump mounting chamber 360A easily escapes upwards.

In addition, protruding ribs 513 are formed on the inner circumferential surface of the handle bar mounting groove 510A and the handle bar mounting groove 510B to discharge heat to the outside through the handle bar mounting parts 510A and 510B.

In addition, the handle bar 510 functions as a heat conductor that absorbs heat emitted from the heat sink 370 and releases it to the outside when an aluminum material having excellent heat conductivity is used.

In addition, the rear housing 330 is preferably formed with a drawing hole 410 for drawing the power cable 400. The outlet hole 410 may also function as a passage for extracting heat emitted from the heat sink 370 to the outside.

Electron pump 360 is a pump for pumping by reciprocating the plunger by the electromagnetic force, its operation principle and configuration refer to the publications of Korean Patent Laid-Open No. 2000-73549 and Korean Patent No. 10-747431, detailed description thereof will be omitted. .

The water suction port 363 of the electronic pump 360 is connected to the water tank 380 by a tube (not shown), and the water discharge port 365 of the electronic pump 360 is the water injection hole 355a of the steam boiler 350. Is connected by a tube (not shown).

FIG. 8 is a perspective view illustrating an instantaneous heated steam boiler according to the present invention, and FIGS. 9 and 10 are perspective views in which main parts of the instantaneous heated steam boiler of FIG. 8 are separated and combined.

As shown in FIGS. 8 to 10, the instantaneous heating steam boiler 350 includes a U-shaped electric heater 353, a first flow passage 355 and a second disposed on the bottom and top of the electric heater 353. The flow path tube 357 and the block 351 which embed | buried these are comprised.

The first flow pipe 355 is the first water injection pipe (355a), the first steam discharge pipe (355c), the first water injection pipe (355a) and the first connection pipe (355b) connecting the first steam discharge pipe (355c) is It is formed integrally.

Similarly to the first flow pipe 355, the second flow pipe 357 is connected to the first steam discharge pipe 355c by the connecting tube 356, and the second steam discharge pipe 357a and the second steam discharge pipe 357c. In addition, a second connection pipe 357b connecting the second steam injection pipe 357a and the second steam discharge pipe 357c is integrally formed.

The first flow path 355 and the second flow path 357 are arranged on the same plane as the plane (X-Y plane) of the electric heater 353.

Therefore, the two-dimensional flow path pipes 355 and 357 can be made thinner than the surface area of the block 351, compared to the conventional three-dimensional spiral flow pipe, making the steam boiler 350 slimmer. Can be implemented.

Meanwhile, the first connector 355b and the second connector 357b are preferably bent in a wave form. This is for realizing complete steaming (with little or no liquid) by lengthening the contact time of the electric heater 353 while reducing the volume.

In addition, the flow path tube formed integrally can be be divided into the first flow path pipe 355 and the second flow path pipe 357, but the first flow path pipe 355 and the second flow path pipe 357 into two After dividing and embedding in the block 351 and connecting with the connecting tube 356, the air filled with steam is very finely released from the connection between the connecting tube 356 and the pipes 355c and 357a. Very low noise during injection, regular injection volume and significant contribution to complete steaming.

On the other hand, instead of using two upper and lower flow channels, the single flow tubes shown in Figs. 11 to 13 may be used in various forms.

The flow path tube 355A or 357A of FIG. 11 has the shape bent by inserting the coil-shaped heating body 356A in the tube.

Since the heating element 356A functions as a heat conductor that receives heat from the flow path tube 355A or 357A, the heating body 356A expands the surface area in contact with the water flowing in the flow path tube 355A or 357A to vaporize or steam the water. Play a big role.

The heater 356A may have any shape in addition to the coil shape, as long as the surface area in contact with water is widened.

The flow path tube 355B or 357B in FIG. 12 may form a tread 356B pressed against the connecting tube.

In the flow path pipe 355C or 357C of FIG. 13, the inner diameter φ 1 of the water injection pipe may be larger than the inner diameter φ 2 of the steam discharge pipe.

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The difference in the inner diameter is preferably formed through expansion or shaft work.

The electrical circuit of the steam boiler 350, the electronic pump 360 and the power cable 400 will be described.

The terminal P1 of the specific temperature maintaining bimetal 352 of the steam boiler 350 is connected to the terminal P1 of the electric heater 353 by an electric wire (not shown), and the specific temperature maintaining bimetal of the steam boiler 350 is connected. Terminal P2 of 352 is connected to PCB 385 by an electric wire (not shown).

The terminal P1 of the electron pump 360 is connected to the PCB 385 by an electric wire (not shown), and the terminal P2 of the electron pump 360 is connected to the bimetal 352 'by an electric wire (not shown). It is connected to the terminal P2.

In addition, the power cable 400 is connected to the PCB (385).

Referring to the operation principle of the steam cleaner of the present embodiment constituting such an electric circuit as follows.

When the power button 381 is pressed after the cord of the power cable 400 is connected to an outlet, power is applied to the bimetal 352 and the bimetal 352 'through the circuit of the PCB 385.

The bimetal 352 'to which power is applied serves only as a switch for starting the electronic pump 360, and the started electronic pump 360 sucks water from the water tank 380 and continues to supply the steam boiler 350. .

The supplied water flows through the first flow passage 355 and the first steam comes out, and the first steam flows through the second flow passage 357 through the connection tube 356. Two steams are supplied to the steam sprayer (not shown).

On the other hand, the bimetal 352 'to which power is applied serves as a switch so as to be within a specific temperature range while sensing the temperature of the electric heater 353.

Instantaneous heating steam boiler according to the present invention is not limited to the above-described embodiment can be carried out in a variety of modifications within the range allowed by the technical idea of the present invention.

The present invention can be applied to all of the instantaneous heating steam boiler in contact with the electric heater.

1 and 2 are a front and rear perspective view showing a steam cleaner according to a preferred embodiment of the present invention.

3 is a perspective view showing a steam generating unit in a state where the front housing is removed.

4 is a perspective view illustrating a steam generating unit in a state in which the PCB of FIG. 3 is removed.

5 is a perspective view showing the front housing and the rear housing separated in accordance with the present invention.

6 and 7 are perspective views showing the separation and coupling of the electronic pump and the heat sink according to the present invention.

Figure 8 is a perspective view of the instantaneous heating steam boiler according to the present invention.

9 and 10 are perspective views in which main parts of the instantaneous heated steam boiler of FIG. 8 are separated and combined.

11 to 13 are perspective views showing various embodiments of the flow pipe according to the present invention.

Figure 14 is an explanatory view showing the arrangement and configuration of each element of the dental pore cleaning device using a conventional steam boiler.

<Description of the symbols for the main parts of the drawings>

100: base assembly 110: main body

120: upper cover 130: bottom plate

300: main assembly 310: housing

320: front housing 330: rear housing

331: heat dissipation hole 333: fixing bracket

335: tightening bracket 340: steam generating unit

350: steam boiler 351: block

352,352 ': Bimetal 353: Electric Heater

355,357: Euro pipe 355a, 357a: Water injection pipe

355b, 357b: Steam discharge pipe 355c, 357c: Connector

356A: heating element 356B: pressed mark

350A: Steam boiler mounting room 360: Electronic pump

360A: Electronic pump mounting room 370: Heat sink

380: Bucket 385: PCB

390A: Bulkhead 391,393: Passing groove

400: power cable 410: (power cable) drawing hole

500: push rod assembly 510: handle bar

530: handle 510A, 510B: handle rod mounting portion

Claims (7)

Electric heater, A water flow pipe consisting of a water injection pipe, a steam discharge pipe, a connection pipe connecting the water injection pipe and the steam discharge pipe; Including a block that is embedded while the terminal and the water injection pipe and the steam discharge pipe of the electric heater is exposed, The flow path tube is disposed in a planar shape in the form of a plate in contact with the upper or lower surface of the electric heater, The flow path tube is instantaneous heating steam boiler disposed on the same plane as the plane of the electric heater. The method of claim 1, The connecting tube is instantaneous heating steam boiler, characterized in that formed in the form of a bend. The method of claim 2, Instantaneous heating steam boiler, characterized in that the press marks are formed in the connection pipe of the flow pipe. The method of claim 1, Instantaneous heating steam boiler, characterized in that the spiral tube is inserted into the flow pipe is installed. The method according to any one of claims 1 to 4, The inner diameter of the water injection pipe is instantaneous heating steam boiler, characterized in that larger than the inner diameter of the steam discharge pipe. Electric heater, A first flow passage configured to be in contact with a lower surface of the electric heater and to include a first water injection pipe, a first steam discharge pipe, and a first connection pipe connecting the first water injection pipe and the first steam discharge pipe; A second steam injection pipe contacting the upper surface of the electric heater and connected to the first steam discharge pipe, a second steam discharge pipe, and a second connection pipe connecting the second steam injection pipe to the second steam discharge pipe; Euro Pipe, Including a block of the electric heater and the first water injection pipe and the first steam discharge pipe, the second steam injection pipe and the second steam discharge pipe is exposed, The first channel and the second channel is arranged in a planar shape in the form of a plate in contact with the upper and lower surfaces of the electric heater, And the first flow passage and the second flow passage are disposed on the same plane as the plane of the electric heater. The method of claim 6, Instantaneous heating steam boiler, characterized in that each of the first connecting pipe and the second connecting pipe is bent in the form of a wave.

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