JPH03294766A - Fablication of regenerative compressor and regenerative heat exchanger - Google Patents

Abstract

PURPOSE:To fill a regenerant with ease and in a short time by inter-loading a heat exchanger between a regenerator vessel and the main body of a compressor after dipping a regenerative heat exchanger in the solvent of the regenerant and solidifying the regenerant between fins. CONSTITUTION:A regenerative heat exchanger 4 having a multitude of fins 3 circumferentially on a heat exchanger 6 is inter-loaded in between a vessel 1 and the main body of a compressor 2. In this case, the regenerative heat exchanger 4 is dipped in a tank 8 of solvent of the regenerant and is pulled up to leave as it is in order to solidifying the regenerant attaching in the fins 3. Thereafter the regenerative heat exchanger 4 together with the completed main body of the compressor 2 is inserted in the regenerative vessel 1 which is not yet put an upper lie. Then, after putting an upper lid 12, the regenerant is refilled in the vacancy around an accumulator 5 and others through the fixing holes for a safety valve 7 etc.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a method for manufacturing a heat storage compression device in which a compressor body and a heat storage heat exchanger are installed in a heat storage container that encloses a heat storage agent, and the heat storage heat exchanger. .

(Prior Art) Conventionally, a heat storage container (D
) is equipped with a compressor main body CC'), and these heat storage containers (D
) and the compressor body (C), a regenerative heat exchanger (E) having a large number of fins (F) is interposed between the compressor body (C).
) is stored in a heat storage agent, and can be taken out as a heat source for defrosting and the like via the heat storage heat exchanger (E).

Then, in filling the heat storage container (D) with the heat storage agent,
A compressor main body (C) and a regenerative heat exchanger (
After E) is assembled, the heat storage agent in powder form is continuously melted each time, and the melted heat storage agent is poured into the heat storage container through an injection port provided in the heat storage container.

(Problem to be solved by the invention) However, as described above, the compressor body (
C) and the manufacturing method of filling the heat storage agent after assembling the heat storage heat exchanger (E), it is best to fill the heat storage agent between the many fins (F) provided in the heat exchanger (E) without any gaps. There is a problem in that the filling operation is difficult and requires a lot of time and effort.

In other words, the heat storage agent includes paraffin, polyethylene glycol, etc., which is released from the compressor body at 60°C to 70°C.
A heat storage agent that melts with moderate heat and becomes solid at room temperature is used, but the molten heat storage agent has a high viscosity and will overflow if a large amount is filled from the injection port at once. It requires a long time. Furthermore, since the powdered heat storage agent is continuously melted each time, a large melting tank is required, which increases the equipment cost.

An object of the present invention is to provide a method for manufacturing a heat storage compression device and a heat storage heat exchanger that can easily and quickly fill a heat storage agent.

(Means for Solving the Problems) Therefore, in the present invention, in order to achieve the above object, a compressor main body (2) is installed inside a heat storage container (1) in which a heat storage agent is enclosed, and these heat storage containers (1) and In a method for manufacturing a heat storage compression device having a heat storage heat exchanger (4) interposed between a compressor body (2) and a heat storage heat exchanger (4) having a large number of fins (3), the heat storage heat exchanger (4) is heated by melting a heat storage agent. The fins (
After solidifying the heat storage agent during step 3), the heat exchanger (4) was interposed between the heat storage container (1) and the compressor body (2).

Further, there is provided a heat storage heat exchanger which is provided with a large number of fins (3) and is interposed between a heat storage container (1) enclosing a heat storage agent and a compressor main body (2) installed therein, Fin (3)
During this time, I decided to solidify and adhere the heat storage agent.

(Function) The heat storage agent is solidified between the fins (3) of the heat storage heat exchanger (4), and then the heat storage agent is solidified between the heat storage container (1) and the compressor body (2).
), it is possible to avoid the difficulty of filling the heat storage agent between the fins (3) as in the past, and the filling can be done easily, shortening the filling time and reducing the work effort. can be achieved.

Further, according to the heat storage heat exchanger in which the heat storage agent is solidified and adhered between the fins (3), filling the heat storage container (1) with the heat storage agent can be similarly easily performed.

(Example) Fig. 2 shows a completed heat storage compression device, which has a body (11), an upper cover (12), and a lower cover (13), and has a heat storage container (1) in which a heat storage agent is sealed. ), and the heat storage container (1) is equipped with a compressor body (
2) and an accumulator (5) installed in parallel thereto, and a large number of fins (3) are arranged in a circle on the heat exchange tube (6) between the container (1) and the compressor main body (2). A heat storage heat exchanger (4) arranged in a ring shape is interposed. Incidentally, (7) is a safety valve that is activated by an abnormal pressure rise within the container (1).

Regarding the manufacturing method of the heat storage compression device configured above, I decided to adopt the following process.

First, as shown in FIG. 1(a), the heat storage heat exchanger (
4) is immersed in a heat storage agent dissolving tank (8), pulled up, and left as is, thereby solidifying the heat storage agent adhering between the fins (3).

After that, as shown in the same figure (b), the fin (3
) A heat storage heat exchanger (
4), together with the completed compressor body (2), are inserted into the heat storage container (1) to which the top lid has not yet been attached.

Then, the upper cover (12) is attached to the completed state shown in FIG. 2, and the insufficient filling around the accumulator (5) is supplemented through the mounting hole of the safety valve (7).

In other words, if the above manufacturing method uses a heat exchanger (4) in which a heat storage agent is preliminarily coagulated between the fins (3), it will be difficult to fill the narrow gap between the fins (3) with the heat storage agent as in the conventional method. It is possible to avoid this, shorten the filling time and reduce the work effort, and also eliminate the need for equipment such as a large 8-inch dissolving tank.

(Effect of the invention) As described above, the fins (3) of the heat storage heat exchanger (4)
A method in which a heat storage agent is solidified between the fins (3) is later interposed between the heat storage container (1) and the compressor body (2), or a heat storage agent is solidified and attached between the fins (3). By using a thermal storage heat exchanger, it is possible to avoid the difficulty of filling the heat storage agent between the fins (3) as in the past, and the filling can be easily performed, shortening the filling time and reducing the work effort. Further, equipment such as a large dissolving tank can be made unnecessary.

[Brief explanation of the drawing]

1(a) and 1(b) are process diagrams showing the method for manufacturing the heat storage compression device of the present invention, FIG. 2 is a side view showing the completed state, and FIG. 3 is a sectional view of a conventional example. (1) Heat storage container (2) Compressor body (3) Fins (4) Heat storage heat exchanger 7-

Claims (2)

[Claims] (1) The compressor body (
2) inside, and these heat storage containers (1) and the compressor body (2)
) A regenerative heat exchanger (
4) In the method for manufacturing a heat storage compression device, the heat storage heat exchanger (4) is immersed in a solution of a heat storage agent,
A heat storage device characterized in that after the heat storage agent is solidified between the fins (3), the heat exchanger (4) is interposed between the heat storage container (1) and the compressor body (2). A method of manufacturing a compression device. (2) A regenerative heat exchanger that is provided with a large number of fins (3) and is interposed between a heat storage container (1) that encloses a heat storage agent and a compressor body (2) that is installed inside the heat storage container (1), The fin (3
) A heat storage heat exchanger characterized in that a heat storage agent is solidified and adhered between the layers.